linux/drivers/net/ethernet/marvell/mvpp2.c

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/*
* Driver for Marvell PPv2 network controller for Armada 375 SoC.
*
* Copyright (C) 2014 Marvell
*
* Marcin Wojtas <mw@semihalf.com>
*
* This file is licensed under the terms of the GNU General Public
* License version 2. This program is licensed "as is" without any
* warranty of any kind, whether express or implied.
*/
#include <linux/kernel.h>
#include <linux/netdevice.h>
#include <linux/etherdevice.h>
#include <linux/platform_device.h>
#include <linux/skbuff.h>
#include <linux/inetdevice.h>
#include <linux/mbus.h>
#include <linux/module.h>
#include <linux/mfd/syscon.h>
#include <linux/interrupt.h>
#include <linux/cpumask.h>
#include <linux/of.h>
#include <linux/of_irq.h>
#include <linux/of_mdio.h>
#include <linux/of_net.h>
#include <linux/of_address.h>
#include <linux/of_device.h>
#include <linux/phy.h>
#include <linux/phy/phy.h>
#include <linux/clk.h>
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
#include <linux/hrtimer.h>
#include <linux/ktime.h>
#include <linux/regmap.h>
#include <uapi/linux/ppp_defs.h>
#include <net/ip.h>
#include <net/ipv6.h>
#include <net/tso.h>
/* Fifo Registers */
#define MVPP2_RX_DATA_FIFO_SIZE_REG(port) (0x00 + 4 * (port))
#define MVPP2_RX_ATTR_FIFO_SIZE_REG(port) (0x20 + 4 * (port))
#define MVPP2_RX_MIN_PKT_SIZE_REG 0x60
#define MVPP2_RX_FIFO_INIT_REG 0x64
#define MVPP22_TX_FIFO_SIZE_REG(port) (0x8860 + 4 * (port))
/* RX DMA Top Registers */
#define MVPP2_RX_CTRL_REG(port) (0x140 + 4 * (port))
#define MVPP2_RX_LOW_LATENCY_PKT_SIZE(s) (((s) & 0xfff) << 16)
#define MVPP2_RX_USE_PSEUDO_FOR_CSUM_MASK BIT(31)
#define MVPP2_POOL_BUF_SIZE_REG(pool) (0x180 + 4 * (pool))
#define MVPP2_POOL_BUF_SIZE_OFFSET 5
#define MVPP2_RXQ_CONFIG_REG(rxq) (0x800 + 4 * (rxq))
#define MVPP2_SNOOP_PKT_SIZE_MASK 0x1ff
#define MVPP2_SNOOP_BUF_HDR_MASK BIT(9)
#define MVPP2_RXQ_POOL_SHORT_OFFS 20
#define MVPP21_RXQ_POOL_SHORT_MASK 0x700000
#define MVPP22_RXQ_POOL_SHORT_MASK 0xf00000
#define MVPP2_RXQ_POOL_LONG_OFFS 24
#define MVPP21_RXQ_POOL_LONG_MASK 0x7000000
#define MVPP22_RXQ_POOL_LONG_MASK 0xf000000
#define MVPP2_RXQ_PACKET_OFFSET_OFFS 28
#define MVPP2_RXQ_PACKET_OFFSET_MASK 0x70000000
#define MVPP2_RXQ_DISABLE_MASK BIT(31)
/* Parser Registers */
#define MVPP2_PRS_INIT_LOOKUP_REG 0x1000
#define MVPP2_PRS_PORT_LU_MAX 0xf
#define MVPP2_PRS_PORT_LU_MASK(port) (0xff << ((port) * 4))
#define MVPP2_PRS_PORT_LU_VAL(port, val) ((val) << ((port) * 4))
#define MVPP2_PRS_INIT_OFFS_REG(port) (0x1004 + ((port) & 4))
#define MVPP2_PRS_INIT_OFF_MASK(port) (0x3f << (((port) % 4) * 8))
#define MVPP2_PRS_INIT_OFF_VAL(port, val) ((val) << (((port) % 4) * 8))
#define MVPP2_PRS_MAX_LOOP_REG(port) (0x100c + ((port) & 4))
#define MVPP2_PRS_MAX_LOOP_MASK(port) (0xff << (((port) % 4) * 8))
#define MVPP2_PRS_MAX_LOOP_VAL(port, val) ((val) << (((port) % 4) * 8))
#define MVPP2_PRS_TCAM_IDX_REG 0x1100
#define MVPP2_PRS_TCAM_DATA_REG(idx) (0x1104 + (idx) * 4)
#define MVPP2_PRS_TCAM_INV_MASK BIT(31)
#define MVPP2_PRS_SRAM_IDX_REG 0x1200
#define MVPP2_PRS_SRAM_DATA_REG(idx) (0x1204 + (idx) * 4)
#define MVPP2_PRS_TCAM_CTRL_REG 0x1230
#define MVPP2_PRS_TCAM_EN_MASK BIT(0)
/* RSS Registers */
#define MVPP22_RSS_INDEX 0x1500
#define MVPP22_RSS_INDEX_TABLE_ENTRY(idx) ((idx) << 8)
#define MVPP22_RSS_INDEX_TABLE(idx) ((idx) << 8)
#define MVPP22_RSS_INDEX_QUEUE(idx) ((idx) << 16)
#define MVPP22_RSS_TABLE_ENTRY 0x1508
#define MVPP22_RSS_TABLE 0x1510
#define MVPP22_RSS_TABLE_POINTER(p) (p)
#define MVPP22_RSS_WIDTH 0x150c
/* Classifier Registers */
#define MVPP2_CLS_MODE_REG 0x1800
#define MVPP2_CLS_MODE_ACTIVE_MASK BIT(0)
#define MVPP2_CLS_PORT_WAY_REG 0x1810
#define MVPP2_CLS_PORT_WAY_MASK(port) (1 << (port))
#define MVPP2_CLS_LKP_INDEX_REG 0x1814
#define MVPP2_CLS_LKP_INDEX_WAY_OFFS 6
#define MVPP2_CLS_LKP_TBL_REG 0x1818
#define MVPP2_CLS_LKP_TBL_RXQ_MASK 0xff
#define MVPP2_CLS_LKP_TBL_LOOKUP_EN_MASK BIT(25)
#define MVPP2_CLS_FLOW_INDEX_REG 0x1820
#define MVPP2_CLS_FLOW_TBL0_REG 0x1824
#define MVPP2_CLS_FLOW_TBL1_REG 0x1828
#define MVPP2_CLS_FLOW_TBL2_REG 0x182c
#define MVPP2_CLS_OVERSIZE_RXQ_LOW_REG(port) (0x1980 + ((port) * 4))
#define MVPP2_CLS_OVERSIZE_RXQ_LOW_BITS 3
#define MVPP2_CLS_OVERSIZE_RXQ_LOW_MASK 0x7
#define MVPP2_CLS_SWFWD_P2HQ_REG(port) (0x19b0 + ((port) * 4))
#define MVPP2_CLS_SWFWD_PCTRL_REG 0x19d0
#define MVPP2_CLS_SWFWD_PCTRL_MASK(port) (1 << (port))
/* Descriptor Manager Top Registers */
#define MVPP2_RXQ_NUM_REG 0x2040
#define MVPP2_RXQ_DESC_ADDR_REG 0x2044
#define MVPP22_DESC_ADDR_OFFS 8
#define MVPP2_RXQ_DESC_SIZE_REG 0x2048
#define MVPP2_RXQ_DESC_SIZE_MASK 0x3ff0
#define MVPP2_RXQ_STATUS_UPDATE_REG(rxq) (0x3000 + 4 * (rxq))
#define MVPP2_RXQ_NUM_PROCESSED_OFFSET 0
#define MVPP2_RXQ_NUM_NEW_OFFSET 16
#define MVPP2_RXQ_STATUS_REG(rxq) (0x3400 + 4 * (rxq))
#define MVPP2_RXQ_OCCUPIED_MASK 0x3fff
#define MVPP2_RXQ_NON_OCCUPIED_OFFSET 16
#define MVPP2_RXQ_NON_OCCUPIED_MASK 0x3fff0000
#define MVPP2_RXQ_THRESH_REG 0x204c
#define MVPP2_OCCUPIED_THRESH_OFFSET 0
#define MVPP2_OCCUPIED_THRESH_MASK 0x3fff
#define MVPP2_RXQ_INDEX_REG 0x2050
#define MVPP2_TXQ_NUM_REG 0x2080
#define MVPP2_TXQ_DESC_ADDR_REG 0x2084
#define MVPP2_TXQ_DESC_SIZE_REG 0x2088
#define MVPP2_TXQ_DESC_SIZE_MASK 0x3ff0
#define MVPP2_TXQ_THRESH_REG 0x2094
#define MVPP2_TXQ_THRESH_OFFSET 16
#define MVPP2_TXQ_THRESH_MASK 0x3fff
#define MVPP2_AGGR_TXQ_UPDATE_REG 0x2090
#define MVPP2_TXQ_INDEX_REG 0x2098
#define MVPP2_TXQ_PREF_BUF_REG 0x209c
#define MVPP2_PREF_BUF_PTR(desc) ((desc) & 0xfff)
#define MVPP2_PREF_BUF_SIZE_4 (BIT(12) | BIT(13))
#define MVPP2_PREF_BUF_SIZE_16 (BIT(12) | BIT(14))
#define MVPP2_PREF_BUF_THRESH(val) ((val) << 17)
#define MVPP2_TXQ_DRAIN_EN_MASK BIT(31)
#define MVPP2_TXQ_PENDING_REG 0x20a0
#define MVPP2_TXQ_PENDING_MASK 0x3fff
#define MVPP2_TXQ_INT_STATUS_REG 0x20a4
#define MVPP2_TXQ_SENT_REG(txq) (0x3c00 + 4 * (txq))
#define MVPP2_TRANSMITTED_COUNT_OFFSET 16
#define MVPP2_TRANSMITTED_COUNT_MASK 0x3fff0000
#define MVPP2_TXQ_RSVD_REQ_REG 0x20b0
#define MVPP2_TXQ_RSVD_REQ_Q_OFFSET 16
#define MVPP2_TXQ_RSVD_RSLT_REG 0x20b4
#define MVPP2_TXQ_RSVD_RSLT_MASK 0x3fff
#define MVPP2_TXQ_RSVD_CLR_REG 0x20b8
#define MVPP2_TXQ_RSVD_CLR_OFFSET 16
#define MVPP2_AGGR_TXQ_DESC_ADDR_REG(cpu) (0x2100 + 4 * (cpu))
#define MVPP22_AGGR_TXQ_DESC_ADDR_OFFS 8
#define MVPP2_AGGR_TXQ_DESC_SIZE_REG(cpu) (0x2140 + 4 * (cpu))
#define MVPP2_AGGR_TXQ_DESC_SIZE_MASK 0x3ff0
#define MVPP2_AGGR_TXQ_STATUS_REG(cpu) (0x2180 + 4 * (cpu))
#define MVPP2_AGGR_TXQ_PENDING_MASK 0x3fff
#define MVPP2_AGGR_TXQ_INDEX_REG(cpu) (0x21c0 + 4 * (cpu))
/* MBUS bridge registers */
#define MVPP2_WIN_BASE(w) (0x4000 + ((w) << 2))
#define MVPP2_WIN_SIZE(w) (0x4020 + ((w) << 2))
#define MVPP2_WIN_REMAP(w) (0x4040 + ((w) << 2))
#define MVPP2_BASE_ADDR_ENABLE 0x4060
/* AXI Bridge Registers */
#define MVPP22_AXI_BM_WR_ATTR_REG 0x4100
#define MVPP22_AXI_BM_RD_ATTR_REG 0x4104
#define MVPP22_AXI_AGGRQ_DESCR_RD_ATTR_REG 0x4110
#define MVPP22_AXI_TXQ_DESCR_WR_ATTR_REG 0x4114
#define MVPP22_AXI_TXQ_DESCR_RD_ATTR_REG 0x4118
#define MVPP22_AXI_RXQ_DESCR_WR_ATTR_REG 0x411c
#define MVPP22_AXI_RX_DATA_WR_ATTR_REG 0x4120
#define MVPP22_AXI_TX_DATA_RD_ATTR_REG 0x4130
#define MVPP22_AXI_RD_NORMAL_CODE_REG 0x4150
#define MVPP22_AXI_RD_SNOOP_CODE_REG 0x4154
#define MVPP22_AXI_WR_NORMAL_CODE_REG 0x4160
#define MVPP22_AXI_WR_SNOOP_CODE_REG 0x4164
/* Values for AXI Bridge registers */
#define MVPP22_AXI_ATTR_CACHE_OFFS 0
#define MVPP22_AXI_ATTR_DOMAIN_OFFS 12
#define MVPP22_AXI_CODE_CACHE_OFFS 0
#define MVPP22_AXI_CODE_DOMAIN_OFFS 4
#define MVPP22_AXI_CODE_CACHE_NON_CACHE 0x3
#define MVPP22_AXI_CODE_CACHE_WR_CACHE 0x7
#define MVPP22_AXI_CODE_CACHE_RD_CACHE 0xb
#define MVPP22_AXI_CODE_DOMAIN_OUTER_DOM 2
#define MVPP22_AXI_CODE_DOMAIN_SYSTEM 3
/* Interrupt Cause and Mask registers */
#define MVPP2_ISR_TX_THRESHOLD_REG(port) (0x5140 + 4 * (port))
#define MVPP2_MAX_ISR_TX_THRESHOLD 0xfffff0
#define MVPP2_ISR_RX_THRESHOLD_REG(rxq) (0x5200 + 4 * (rxq))
#define MVPP2_MAX_ISR_RX_THRESHOLD 0xfffff0
#define MVPP21_ISR_RXQ_GROUP_REG(port) (0x5400 + 4 * (port))
#define MVPP22_ISR_RXQ_GROUP_INDEX_REG 0x5400
#define MVPP22_ISR_RXQ_GROUP_INDEX_SUBGROUP_MASK 0xf
#define MVPP22_ISR_RXQ_GROUP_INDEX_GROUP_MASK 0x380
#define MVPP22_ISR_RXQ_GROUP_INDEX_GROUP_OFFSET 7
#define MVPP22_ISR_RXQ_GROUP_INDEX_SUBGROUP_MASK 0xf
#define MVPP22_ISR_RXQ_GROUP_INDEX_GROUP_MASK 0x380
#define MVPP22_ISR_RXQ_SUB_GROUP_CONFIG_REG 0x5404
#define MVPP22_ISR_RXQ_SUB_GROUP_STARTQ_MASK 0x1f
#define MVPP22_ISR_RXQ_SUB_GROUP_SIZE_MASK 0xf00
#define MVPP22_ISR_RXQ_SUB_GROUP_SIZE_OFFSET 8
#define MVPP2_ISR_ENABLE_REG(port) (0x5420 + 4 * (port))
#define MVPP2_ISR_ENABLE_INTERRUPT(mask) ((mask) & 0xffff)
#define MVPP2_ISR_DISABLE_INTERRUPT(mask) (((mask) << 16) & 0xffff0000)
#define MVPP2_ISR_RX_TX_CAUSE_REG(port) (0x5480 + 4 * (port))
#define MVPP2_CAUSE_RXQ_OCCUP_DESC_ALL_MASK 0xffff
#define MVPP2_CAUSE_TXQ_OCCUP_DESC_ALL_MASK 0xff0000
#define MVPP2_CAUSE_TXQ_OCCUP_DESC_ALL_OFFSET 16
#define MVPP2_CAUSE_RX_FIFO_OVERRUN_MASK BIT(24)
#define MVPP2_CAUSE_FCS_ERR_MASK BIT(25)
#define MVPP2_CAUSE_TX_FIFO_UNDERRUN_MASK BIT(26)
#define MVPP2_CAUSE_TX_EXCEPTION_SUM_MASK BIT(29)
#define MVPP2_CAUSE_RX_EXCEPTION_SUM_MASK BIT(30)
#define MVPP2_CAUSE_MISC_SUM_MASK BIT(31)
#define MVPP2_ISR_RX_TX_MASK_REG(port) (0x54a0 + 4 * (port))
#define MVPP2_ISR_PON_RX_TX_MASK_REG 0x54bc
#define MVPP2_PON_CAUSE_RXQ_OCCUP_DESC_ALL_MASK 0xffff
#define MVPP2_PON_CAUSE_TXP_OCCUP_DESC_ALL_MASK 0x3fc00000
#define MVPP2_PON_CAUSE_MISC_SUM_MASK BIT(31)
#define MVPP2_ISR_MISC_CAUSE_REG 0x55b0
/* Buffer Manager registers */
#define MVPP2_BM_POOL_BASE_REG(pool) (0x6000 + ((pool) * 4))
#define MVPP2_BM_POOL_BASE_ADDR_MASK 0xfffff80
#define MVPP2_BM_POOL_SIZE_REG(pool) (0x6040 + ((pool) * 4))
#define MVPP2_BM_POOL_SIZE_MASK 0xfff0
#define MVPP2_BM_POOL_READ_PTR_REG(pool) (0x6080 + ((pool) * 4))
#define MVPP2_BM_POOL_GET_READ_PTR_MASK 0xfff0
#define MVPP2_BM_POOL_PTRS_NUM_REG(pool) (0x60c0 + ((pool) * 4))
#define MVPP2_BM_POOL_PTRS_NUM_MASK 0xfff0
#define MVPP2_BM_BPPI_READ_PTR_REG(pool) (0x6100 + ((pool) * 4))
#define MVPP2_BM_BPPI_PTRS_NUM_REG(pool) (0x6140 + ((pool) * 4))
#define MVPP2_BM_BPPI_PTR_NUM_MASK 0x7ff
#define MVPP2_BM_BPPI_PREFETCH_FULL_MASK BIT(16)
#define MVPP2_BM_POOL_CTRL_REG(pool) (0x6200 + ((pool) * 4))
#define MVPP2_BM_START_MASK BIT(0)
#define MVPP2_BM_STOP_MASK BIT(1)
#define MVPP2_BM_STATE_MASK BIT(4)
#define MVPP2_BM_LOW_THRESH_OFFS 8
#define MVPP2_BM_LOW_THRESH_MASK 0x7f00
#define MVPP2_BM_LOW_THRESH_VALUE(val) ((val) << \
MVPP2_BM_LOW_THRESH_OFFS)
#define MVPP2_BM_HIGH_THRESH_OFFS 16
#define MVPP2_BM_HIGH_THRESH_MASK 0x7f0000
#define MVPP2_BM_HIGH_THRESH_VALUE(val) ((val) << \
MVPP2_BM_HIGH_THRESH_OFFS)
#define MVPP2_BM_INTR_CAUSE_REG(pool) (0x6240 + ((pool) * 4))
#define MVPP2_BM_RELEASED_DELAY_MASK BIT(0)
#define MVPP2_BM_ALLOC_FAILED_MASK BIT(1)
#define MVPP2_BM_BPPE_EMPTY_MASK BIT(2)
#define MVPP2_BM_BPPE_FULL_MASK BIT(3)
#define MVPP2_BM_AVAILABLE_BP_LOW_MASK BIT(4)
#define MVPP2_BM_INTR_MASK_REG(pool) (0x6280 + ((pool) * 4))
#define MVPP2_BM_PHY_ALLOC_REG(pool) (0x6400 + ((pool) * 4))
#define MVPP2_BM_PHY_ALLOC_GRNTD_MASK BIT(0)
#define MVPP2_BM_VIRT_ALLOC_REG 0x6440
#define MVPP22_BM_ADDR_HIGH_ALLOC 0x6444
#define MVPP22_BM_ADDR_HIGH_PHYS_MASK 0xff
#define MVPP22_BM_ADDR_HIGH_VIRT_MASK 0xff00
#define MVPP22_BM_ADDR_HIGH_VIRT_SHIFT 8
#define MVPP2_BM_PHY_RLS_REG(pool) (0x6480 + ((pool) * 4))
#define MVPP2_BM_PHY_RLS_MC_BUFF_MASK BIT(0)
#define MVPP2_BM_PHY_RLS_PRIO_EN_MASK BIT(1)
#define MVPP2_BM_PHY_RLS_GRNTD_MASK BIT(2)
#define MVPP2_BM_VIRT_RLS_REG 0x64c0
#define MVPP22_BM_ADDR_HIGH_RLS_REG 0x64c4
#define MVPP22_BM_ADDR_HIGH_PHYS_RLS_MASK 0xff
#define MVPP22_BM_ADDR_HIGH_VIRT_RLS_MASK 0xff00
#define MVPP22_BM_ADDR_HIGH_VIRT_RLS_SHIFT 8
/* TX Scheduler registers */
#define MVPP2_TXP_SCHED_PORT_INDEX_REG 0x8000
#define MVPP2_TXP_SCHED_Q_CMD_REG 0x8004
#define MVPP2_TXP_SCHED_ENQ_MASK 0xff
#define MVPP2_TXP_SCHED_DISQ_OFFSET 8
#define MVPP2_TXP_SCHED_CMD_1_REG 0x8010
#define MVPP2_TXP_SCHED_PERIOD_REG 0x8018
#define MVPP2_TXP_SCHED_MTU_REG 0x801c
#define MVPP2_TXP_MTU_MAX 0x7FFFF
#define MVPP2_TXP_SCHED_REFILL_REG 0x8020
#define MVPP2_TXP_REFILL_TOKENS_ALL_MASK 0x7ffff
#define MVPP2_TXP_REFILL_PERIOD_ALL_MASK 0x3ff00000
#define MVPP2_TXP_REFILL_PERIOD_MASK(v) ((v) << 20)
#define MVPP2_TXP_SCHED_TOKEN_SIZE_REG 0x8024
#define MVPP2_TXP_TOKEN_SIZE_MAX 0xffffffff
#define MVPP2_TXQ_SCHED_REFILL_REG(q) (0x8040 + ((q) << 2))
#define MVPP2_TXQ_REFILL_TOKENS_ALL_MASK 0x7ffff
#define MVPP2_TXQ_REFILL_PERIOD_ALL_MASK 0x3ff00000
#define MVPP2_TXQ_REFILL_PERIOD_MASK(v) ((v) << 20)
#define MVPP2_TXQ_SCHED_TOKEN_SIZE_REG(q) (0x8060 + ((q) << 2))
#define MVPP2_TXQ_TOKEN_SIZE_MAX 0x7fffffff
#define MVPP2_TXQ_SCHED_TOKEN_CNTR_REG(q) (0x8080 + ((q) << 2))
#define MVPP2_TXQ_TOKEN_CNTR_MAX 0xffffffff
/* TX general registers */
#define MVPP2_TX_SNOOP_REG 0x8800
#define MVPP2_TX_PORT_FLUSH_REG 0x8810
#define MVPP2_TX_PORT_FLUSH_MASK(port) (1 << (port))
/* LMS registers */
#define MVPP2_SRC_ADDR_MIDDLE 0x24
#define MVPP2_SRC_ADDR_HIGH 0x28
#define MVPP2_PHY_AN_CFG0_REG 0x34
#define MVPP2_PHY_AN_STOP_SMI0_MASK BIT(7)
#define MVPP2_MNG_EXTENDED_GLOBAL_CTRL_REG 0x305c
#define MVPP2_EXT_GLOBAL_CTRL_DEFAULT 0x27
/* Per-port registers */
#define MVPP2_GMAC_CTRL_0_REG 0x0
#define MVPP2_GMAC_PORT_EN_MASK BIT(0)
#define MVPP2_GMAC_PORT_TYPE_MASK BIT(1)
#define MVPP2_GMAC_MAX_RX_SIZE_OFFS 2
#define MVPP2_GMAC_MAX_RX_SIZE_MASK 0x7ffc
#define MVPP2_GMAC_MIB_CNTR_EN_MASK BIT(15)
#define MVPP2_GMAC_CTRL_1_REG 0x4
#define MVPP2_GMAC_PERIODIC_XON_EN_MASK BIT(1)
#define MVPP2_GMAC_GMII_LB_EN_MASK BIT(5)
#define MVPP2_GMAC_PCS_LB_EN_BIT 6
#define MVPP2_GMAC_PCS_LB_EN_MASK BIT(6)
#define MVPP2_GMAC_SA_LOW_OFFS 7
#define MVPP2_GMAC_CTRL_2_REG 0x8
#define MVPP2_GMAC_INBAND_AN_MASK BIT(0)
#define MVPP2_GMAC_FLOW_CTRL_MASK GENMASK(2, 1)
#define MVPP2_GMAC_PCS_ENABLE_MASK BIT(3)
#define MVPP2_GMAC_INTERNAL_CLK_MASK BIT(4)
#define MVPP2_GMAC_DISABLE_PADDING BIT(5)
#define MVPP2_GMAC_PORT_RESET_MASK BIT(6)
#define MVPP2_GMAC_AUTONEG_CONFIG 0xc
#define MVPP2_GMAC_FORCE_LINK_DOWN BIT(0)
#define MVPP2_GMAC_FORCE_LINK_PASS BIT(1)
#define MVPP2_GMAC_IN_BAND_AUTONEG BIT(2)
#define MVPP2_GMAC_IN_BAND_AUTONEG_BYPASS BIT(3)
#define MVPP2_GMAC_CONFIG_MII_SPEED BIT(5)
#define MVPP2_GMAC_CONFIG_GMII_SPEED BIT(6)
#define MVPP2_GMAC_AN_SPEED_EN BIT(7)
#define MVPP2_GMAC_FC_ADV_EN BIT(9)
#define MVPP2_GMAC_FLOW_CTRL_AUTONEG BIT(11)
#define MVPP2_GMAC_CONFIG_FULL_DUPLEX BIT(12)
#define MVPP2_GMAC_AN_DUPLEX_EN BIT(13)
#define MVPP2_GMAC_STATUS0 0x10
#define MVPP2_GMAC_STATUS0_LINK_UP BIT(0)
#define MVPP2_GMAC_PORT_FIFO_CFG_1_REG 0x1c
#define MVPP2_GMAC_TX_FIFO_MIN_TH_OFFS 6
#define MVPP2_GMAC_TX_FIFO_MIN_TH_ALL_MASK 0x1fc0
#define MVPP2_GMAC_TX_FIFO_MIN_TH_MASK(v) (((v) << 6) & \
MVPP2_GMAC_TX_FIFO_MIN_TH_ALL_MASK)
#define MVPP22_GMAC_INT_STAT 0x20
#define MVPP22_GMAC_INT_STAT_LINK BIT(1)
#define MVPP22_GMAC_INT_MASK 0x24
#define MVPP22_GMAC_INT_MASK_LINK_STAT BIT(1)
#define MVPP22_GMAC_CTRL_4_REG 0x90
#define MVPP22_CTRL4_EXT_PIN_GMII_SEL BIT(0)
#define MVPP22_CTRL4_DP_CLK_SEL BIT(5)
#define MVPP22_CTRL4_SYNC_BYPASS_DIS BIT(6)
#define MVPP22_CTRL4_QSGMII_BYPASS_ACTIVE BIT(7)
#define MVPP22_GMAC_INT_SUM_MASK 0xa4
#define MVPP22_GMAC_INT_SUM_MASK_LINK_STAT BIT(1)
/* Per-port XGMAC registers. PPv2.2 only, only for GOP port 0,
* relative to port->base.
*/
#define MVPP22_XLG_CTRL0_REG 0x100
#define MVPP22_XLG_CTRL0_PORT_EN BIT(0)
#define MVPP22_XLG_CTRL0_MAC_RESET_DIS BIT(1)
#define MVPP22_XLG_CTRL0_RX_FLOW_CTRL_EN BIT(7)
#define MVPP22_XLG_CTRL0_MIB_CNT_DIS BIT(14)
#define MVPP22_XLG_CTRL1_REG 0x104
#define MVPP22_XLG_CTRL1_FRAMESIZELIMIT_OFFS 0
#define MVPP22_XLG_CTRL1_FRAMESIZELIMIT_MASK 0x1fff
#define MVPP22_XLG_STATUS 0x10c
#define MVPP22_XLG_STATUS_LINK_UP BIT(0)
#define MVPP22_XLG_INT_STAT 0x114
#define MVPP22_XLG_INT_STAT_LINK BIT(1)
#define MVPP22_XLG_INT_MASK 0x118
#define MVPP22_XLG_INT_MASK_LINK BIT(1)
#define MVPP22_XLG_CTRL3_REG 0x11c
#define MVPP22_XLG_CTRL3_MACMODESELECT_MASK (7 << 13)
#define MVPP22_XLG_CTRL3_MACMODESELECT_GMAC (0 << 13)
#define MVPP22_XLG_CTRL3_MACMODESELECT_10G (1 << 13)
#define MVPP22_XLG_EXT_INT_MASK 0x15c
#define MVPP22_XLG_EXT_INT_MASK_XLG BIT(1)
#define MVPP22_XLG_EXT_INT_MASK_GIG BIT(2)
#define MVPP22_XLG_CTRL4_REG 0x184
#define MVPP22_XLG_CTRL4_FWD_FC BIT(5)
#define MVPP22_XLG_CTRL4_FWD_PFC BIT(6)
#define MVPP22_XLG_CTRL4_MACMODSELECT_GMAC BIT(12)
/* SMI registers. PPv2.2 only, relative to priv->iface_base. */
#define MVPP22_SMI_MISC_CFG_REG 0x1204
#define MVPP22_SMI_POLLING_EN BIT(10)
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
#define MVPP22_GMAC_BASE(port) (0x7000 + (port) * 0x1000 + 0xe00)
#define MVPP2_CAUSE_TXQ_SENT_DESC_ALL_MASK 0xff
/* Descriptor ring Macros */
#define MVPP2_QUEUE_NEXT_DESC(q, index) \
(((index) < (q)->last_desc) ? ((index) + 1) : 0)
/* XPCS registers. PPv2.2 only */
#define MVPP22_MPCS_BASE(port) (0x7000 + (port) * 0x1000)
#define MVPP22_MPCS_CTRL 0x14
#define MVPP22_MPCS_CTRL_FWD_ERR_CONN BIT(10)
#define MVPP22_MPCS_CLK_RESET 0x14c
#define MAC_CLK_RESET_SD_TX BIT(0)
#define MAC_CLK_RESET_SD_RX BIT(1)
#define MAC_CLK_RESET_MAC BIT(2)
#define MVPP22_MPCS_CLK_RESET_DIV_RATIO(n) ((n) << 4)
#define MVPP22_MPCS_CLK_RESET_DIV_SET BIT(11)
/* XPCS registers. PPv2.2 only */
#define MVPP22_XPCS_BASE(port) (0x7400 + (port) * 0x1000)
#define MVPP22_XPCS_CFG0 0x0
#define MVPP22_XPCS_CFG0_PCS_MODE(n) ((n) << 3)
#define MVPP22_XPCS_CFG0_ACTIVE_LANE(n) ((n) << 5)
/* System controller registers. Accessed through a regmap. */
#define GENCONF_SOFT_RESET1 0x1108
#define GENCONF_SOFT_RESET1_GOP BIT(6)
#define GENCONF_PORT_CTRL0 0x1110
#define GENCONF_PORT_CTRL0_BUS_WIDTH_SELECT BIT(1)
#define GENCONF_PORT_CTRL0_RX_DATA_SAMPLE BIT(29)
#define GENCONF_PORT_CTRL0_CLK_DIV_PHASE_CLR BIT(31)
#define GENCONF_PORT_CTRL1 0x1114
#define GENCONF_PORT_CTRL1_EN(p) BIT(p)
#define GENCONF_PORT_CTRL1_RESET(p) (BIT(p) << 28)
#define GENCONF_CTRL0 0x1120
#define GENCONF_CTRL0_PORT0_RGMII BIT(0)
#define GENCONF_CTRL0_PORT1_RGMII_MII BIT(1)
#define GENCONF_CTRL0_PORT1_RGMII BIT(2)
/* Various constants */
/* Coalescing */
#define MVPP2_TXDONE_COAL_PKTS_THRESH 15
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
#define MVPP2_TXDONE_HRTIMER_PERIOD_NS 1000000UL
#define MVPP2_TXDONE_COAL_USEC 1000
#define MVPP2_RX_COAL_PKTS 32
#define MVPP2_RX_COAL_USEC 100
/* The two bytes Marvell header. Either contains a special value used
* by Marvell switches when a specific hardware mode is enabled (not
* supported by this driver) or is filled automatically by zeroes on
* the RX side. Those two bytes being at the front of the Ethernet
* header, they allow to have the IP header aligned on a 4 bytes
* boundary automatically: the hardware skips those two bytes on its
* own.
*/
#define MVPP2_MH_SIZE 2
#define MVPP2_ETH_TYPE_LEN 2
#define MVPP2_PPPOE_HDR_SIZE 8
#define MVPP2_VLAN_TAG_LEN 4
/* Lbtd 802.3 type */
#define MVPP2_IP_LBDT_TYPE 0xfffa
#define MVPP2_TX_CSUM_MAX_SIZE 9800
/* Timeout constants */
#define MVPP2_TX_DISABLE_TIMEOUT_MSEC 1000
#define MVPP2_TX_PENDING_TIMEOUT_MSEC 1000
#define MVPP2_TX_MTU_MAX 0x7ffff
/* Maximum number of T-CONTs of PON port */
#define MVPP2_MAX_TCONT 16
/* Maximum number of supported ports */
#define MVPP2_MAX_PORTS 4
/* Maximum number of TXQs used by single port */
#define MVPP2_MAX_TXQ 8
/* MVPP2_MAX_TSO_SEGS is the maximum number of fragments to allow in the GSO
* skb. As we need a maxium of two descriptors per fragments (1 header, 1 data),
* multiply this value by two to count the maximum number of skb descs needed.
*/
#define MVPP2_MAX_TSO_SEGS 300
#define MVPP2_MAX_SKB_DESCS (MVPP2_MAX_TSO_SEGS * 2 + MAX_SKB_FRAGS)
/* Dfault number of RXQs in use */
#define MVPP2_DEFAULT_RXQ 4
/* Max number of Rx descriptors */
#define MVPP2_MAX_RXD 128
/* Max number of Tx descriptors */
#define MVPP2_MAX_TXD 1024
/* Amount of Tx descriptors that can be reserved at once by CPU */
#define MVPP2_CPU_DESC_CHUNK 64
/* Max number of Tx descriptors in each aggregated queue */
#define MVPP2_AGGR_TXQ_SIZE 256
/* Descriptor aligned size */
#define MVPP2_DESC_ALIGNED_SIZE 32
/* Descriptor alignment mask */
#define MVPP2_TX_DESC_ALIGN (MVPP2_DESC_ALIGNED_SIZE - 1)
/* RX FIFO constants */
#define MVPP2_RX_FIFO_PORT_DATA_SIZE_32KB 0x8000
#define MVPP2_RX_FIFO_PORT_DATA_SIZE_8KB 0x2000
#define MVPP2_RX_FIFO_PORT_DATA_SIZE_4KB 0x1000
#define MVPP2_RX_FIFO_PORT_ATTR_SIZE_32KB 0x200
#define MVPP2_RX_FIFO_PORT_ATTR_SIZE_8KB 0x80
#define MVPP2_RX_FIFO_PORT_ATTR_SIZE_4KB 0x40
#define MVPP2_RX_FIFO_PORT_MIN_PKT 0x80
/* TX FIFO constants */
#define MVPP22_TX_FIFO_DATA_SIZE_10KB 0xa
#define MVPP22_TX_FIFO_DATA_SIZE_3KB 0x3
/* RX buffer constants */
#define MVPP2_SKB_SHINFO_SIZE \
SKB_DATA_ALIGN(sizeof(struct skb_shared_info))
#define MVPP2_RX_PKT_SIZE(mtu) \
ALIGN((mtu) + MVPP2_MH_SIZE + MVPP2_VLAN_TAG_LEN + \
ETH_HLEN + ETH_FCS_LEN, cache_line_size())
#define MVPP2_RX_BUF_SIZE(pkt_size) ((pkt_size) + NET_SKB_PAD)
#define MVPP2_RX_TOTAL_SIZE(buf_size) ((buf_size) + MVPP2_SKB_SHINFO_SIZE)
#define MVPP2_RX_MAX_PKT_SIZE(total_size) \
((total_size) - NET_SKB_PAD - MVPP2_SKB_SHINFO_SIZE)
#define MVPP2_BIT_TO_BYTE(bit) ((bit) / 8)
/* IPv6 max L3 address size */
#define MVPP2_MAX_L3_ADDR_SIZE 16
/* Port flags */
#define MVPP2_F_LOOPBACK BIT(0)
/* Marvell tag types */
enum mvpp2_tag_type {
MVPP2_TAG_TYPE_NONE = 0,
MVPP2_TAG_TYPE_MH = 1,
MVPP2_TAG_TYPE_DSA = 2,
MVPP2_TAG_TYPE_EDSA = 3,
MVPP2_TAG_TYPE_VLAN = 4,
MVPP2_TAG_TYPE_LAST = 5
};
/* Parser constants */
#define MVPP2_PRS_TCAM_SRAM_SIZE 256
#define MVPP2_PRS_TCAM_WORDS 6
#define MVPP2_PRS_SRAM_WORDS 4
#define MVPP2_PRS_FLOW_ID_SIZE 64
#define MVPP2_PRS_FLOW_ID_MASK 0x3f
#define MVPP2_PRS_TCAM_ENTRY_INVALID 1
#define MVPP2_PRS_TCAM_DSA_TAGGED_BIT BIT(5)
#define MVPP2_PRS_IPV4_HEAD 0x40
#define MVPP2_PRS_IPV4_HEAD_MASK 0xf0
#define MVPP2_PRS_IPV4_MC 0xe0
#define MVPP2_PRS_IPV4_MC_MASK 0xf0
#define MVPP2_PRS_IPV4_BC_MASK 0xff
#define MVPP2_PRS_IPV4_IHL 0x5
#define MVPP2_PRS_IPV4_IHL_MASK 0xf
#define MVPP2_PRS_IPV6_MC 0xff
#define MVPP2_PRS_IPV6_MC_MASK 0xff
#define MVPP2_PRS_IPV6_HOP_MASK 0xff
#define MVPP2_PRS_TCAM_PROTO_MASK 0xff
#define MVPP2_PRS_TCAM_PROTO_MASK_L 0x3f
#define MVPP2_PRS_DBL_VLANS_MAX 100
/* Tcam structure:
* - lookup ID - 4 bits
* - port ID - 1 byte
* - additional information - 1 byte
* - header data - 8 bytes
* The fields are represented by MVPP2_PRS_TCAM_DATA_REG(5)->(0).
*/
#define MVPP2_PRS_AI_BITS 8
#define MVPP2_PRS_PORT_MASK 0xff
#define MVPP2_PRS_LU_MASK 0xf
#define MVPP2_PRS_TCAM_DATA_BYTE(offs) \
(((offs) - ((offs) % 2)) * 2 + ((offs) % 2))
#define MVPP2_PRS_TCAM_DATA_BYTE_EN(offs) \
(((offs) * 2) - ((offs) % 2) + 2)
#define MVPP2_PRS_TCAM_AI_BYTE 16
#define MVPP2_PRS_TCAM_PORT_BYTE 17
#define MVPP2_PRS_TCAM_LU_BYTE 20
#define MVPP2_PRS_TCAM_EN_OFFS(offs) ((offs) + 2)
#define MVPP2_PRS_TCAM_INV_WORD 5
/* Tcam entries ID */
#define MVPP2_PE_DROP_ALL 0
#define MVPP2_PE_FIRST_FREE_TID 1
#define MVPP2_PE_LAST_FREE_TID (MVPP2_PRS_TCAM_SRAM_SIZE - 31)
#define MVPP2_PE_IP6_EXT_PROTO_UN (MVPP2_PRS_TCAM_SRAM_SIZE - 30)
#define MVPP2_PE_MAC_MC_IP6 (MVPP2_PRS_TCAM_SRAM_SIZE - 29)
#define MVPP2_PE_IP6_ADDR_UN (MVPP2_PRS_TCAM_SRAM_SIZE - 28)
#define MVPP2_PE_IP4_ADDR_UN (MVPP2_PRS_TCAM_SRAM_SIZE - 27)
#define MVPP2_PE_LAST_DEFAULT_FLOW (MVPP2_PRS_TCAM_SRAM_SIZE - 26)
#define MVPP2_PE_FIRST_DEFAULT_FLOW (MVPP2_PRS_TCAM_SRAM_SIZE - 19)
#define MVPP2_PE_EDSA_TAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 18)
#define MVPP2_PE_EDSA_UNTAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 17)
#define MVPP2_PE_DSA_TAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 16)
#define MVPP2_PE_DSA_UNTAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 15)
#define MVPP2_PE_ETYPE_EDSA_TAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 14)
#define MVPP2_PE_ETYPE_EDSA_UNTAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 13)
#define MVPP2_PE_ETYPE_DSA_TAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 12)
#define MVPP2_PE_ETYPE_DSA_UNTAGGED (MVPP2_PRS_TCAM_SRAM_SIZE - 11)
#define MVPP2_PE_MH_DEFAULT (MVPP2_PRS_TCAM_SRAM_SIZE - 10)
#define MVPP2_PE_DSA_DEFAULT (MVPP2_PRS_TCAM_SRAM_SIZE - 9)
#define MVPP2_PE_IP6_PROTO_UN (MVPP2_PRS_TCAM_SRAM_SIZE - 8)
#define MVPP2_PE_IP4_PROTO_UN (MVPP2_PRS_TCAM_SRAM_SIZE - 7)
#define MVPP2_PE_ETH_TYPE_UN (MVPP2_PRS_TCAM_SRAM_SIZE - 6)
#define MVPP2_PE_VLAN_DBL (MVPP2_PRS_TCAM_SRAM_SIZE - 5)
#define MVPP2_PE_VLAN_NONE (MVPP2_PRS_TCAM_SRAM_SIZE - 4)
#define MVPP2_PE_MAC_MC_ALL (MVPP2_PRS_TCAM_SRAM_SIZE - 3)
#define MVPP2_PE_MAC_PROMISCUOUS (MVPP2_PRS_TCAM_SRAM_SIZE - 2)
#define MVPP2_PE_MAC_NON_PROMISCUOUS (MVPP2_PRS_TCAM_SRAM_SIZE - 1)
/* Sram structure
* The fields are represented by MVPP2_PRS_TCAM_DATA_REG(3)->(0).
*/
#define MVPP2_PRS_SRAM_RI_OFFS 0
#define MVPP2_PRS_SRAM_RI_WORD 0
#define MVPP2_PRS_SRAM_RI_CTRL_OFFS 32
#define MVPP2_PRS_SRAM_RI_CTRL_WORD 1
#define MVPP2_PRS_SRAM_RI_CTRL_BITS 32
#define MVPP2_PRS_SRAM_SHIFT_OFFS 64
#define MVPP2_PRS_SRAM_SHIFT_SIGN_BIT 72
#define MVPP2_PRS_SRAM_UDF_OFFS 73
#define MVPP2_PRS_SRAM_UDF_BITS 8
#define MVPP2_PRS_SRAM_UDF_MASK 0xff
#define MVPP2_PRS_SRAM_UDF_SIGN_BIT 81
#define MVPP2_PRS_SRAM_UDF_TYPE_OFFS 82
#define MVPP2_PRS_SRAM_UDF_TYPE_MASK 0x7
#define MVPP2_PRS_SRAM_UDF_TYPE_L3 1
#define MVPP2_PRS_SRAM_UDF_TYPE_L4 4
#define MVPP2_PRS_SRAM_OP_SEL_SHIFT_OFFS 85
#define MVPP2_PRS_SRAM_OP_SEL_SHIFT_MASK 0x3
#define MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD 1
#define MVPP2_PRS_SRAM_OP_SEL_SHIFT_IP4_ADD 2
#define MVPP2_PRS_SRAM_OP_SEL_SHIFT_IP6_ADD 3
#define MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS 87
#define MVPP2_PRS_SRAM_OP_SEL_UDF_BITS 2
#define MVPP2_PRS_SRAM_OP_SEL_UDF_MASK 0x3
#define MVPP2_PRS_SRAM_OP_SEL_UDF_ADD 0
#define MVPP2_PRS_SRAM_OP_SEL_UDF_IP4_ADD 2
#define MVPP2_PRS_SRAM_OP_SEL_UDF_IP6_ADD 3
#define MVPP2_PRS_SRAM_OP_SEL_BASE_OFFS 89
#define MVPP2_PRS_SRAM_AI_OFFS 90
#define MVPP2_PRS_SRAM_AI_CTRL_OFFS 98
#define MVPP2_PRS_SRAM_AI_CTRL_BITS 8
#define MVPP2_PRS_SRAM_AI_MASK 0xff
#define MVPP2_PRS_SRAM_NEXT_LU_OFFS 106
#define MVPP2_PRS_SRAM_NEXT_LU_MASK 0xf
#define MVPP2_PRS_SRAM_LU_DONE_BIT 110
#define MVPP2_PRS_SRAM_LU_GEN_BIT 111
/* Sram result info bits assignment */
#define MVPP2_PRS_RI_MAC_ME_MASK 0x1
#define MVPP2_PRS_RI_DSA_MASK 0x2
net: mvpp2: simplify MVPP2_PRS_RI_* definitions Some of the MVPP2_PRS_RI_* definitions use the ~(value) syntax, which doesn't compile nicely on 64-bit. Moreover, those definitions are in fact unneeded, since they are always used in combination with a bit mask that ensures only the appropriate bits are modified. Therefore, such definitions should just be set to 0x0. In addition, as suggested by Russell King, we change the _MASK definitions to also use the BIT() macro so that it is clear they are related to the values defined afterwards. For example: #define MVPP2_PRS_RI_L2_CAST_MASK 0x600 #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) becomes #define MVPP2_PRS_RI_L2_CAST_MASK (BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_UCAST 0x0 #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) Because the values (MVPP2_PRS_RI_L2_UCAST, MVPP2_PRS_RI_L2_MCAST and MVPP2_PRS_RI_L2_BCAST) are always applied with MVPP2_PRS_RI_L2_CAST_MASK, and therefore there is no need for MVPP2_PRS_RI_L2_UCAST to be defined as ~(BIT(9) | BIT(10)). It fixes the following warnings when building the driver on a 64-bit platform (which is not possible as of this commit, but will be enabled in a follow-up commit): drivers/net/ethernet/marvell/mvpp2.c: In function ‘mvpp2_prs_mac_promisc_set’: drivers/net/ethernet/marvell/mvpp2.c:524:33: warning: large integer implicitly truncated to unsigned type [-Woverflow] #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) ^ drivers/net/ethernet/marvell/mvpp2.c:1459:33: note: in expansion of macro ‘MVPP2_PRS_RI_L2_UCAST’ mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L2_UCAST, Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Acked-by: Russell King <rmk+kernel@armlinux.org.uk> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-02-21 18:28:11 +08:00
#define MVPP2_PRS_RI_VLAN_MASK (BIT(2) | BIT(3))
#define MVPP2_PRS_RI_VLAN_NONE 0x0
#define MVPP2_PRS_RI_VLAN_SINGLE BIT(2)
#define MVPP2_PRS_RI_VLAN_DOUBLE BIT(3)
#define MVPP2_PRS_RI_VLAN_TRIPLE (BIT(2) | BIT(3))
#define MVPP2_PRS_RI_CPU_CODE_MASK 0x70
#define MVPP2_PRS_RI_CPU_CODE_RX_SPEC BIT(4)
net: mvpp2: simplify MVPP2_PRS_RI_* definitions Some of the MVPP2_PRS_RI_* definitions use the ~(value) syntax, which doesn't compile nicely on 64-bit. Moreover, those definitions are in fact unneeded, since they are always used in combination with a bit mask that ensures only the appropriate bits are modified. Therefore, such definitions should just be set to 0x0. In addition, as suggested by Russell King, we change the _MASK definitions to also use the BIT() macro so that it is clear they are related to the values defined afterwards. For example: #define MVPP2_PRS_RI_L2_CAST_MASK 0x600 #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) becomes #define MVPP2_PRS_RI_L2_CAST_MASK (BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_UCAST 0x0 #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) Because the values (MVPP2_PRS_RI_L2_UCAST, MVPP2_PRS_RI_L2_MCAST and MVPP2_PRS_RI_L2_BCAST) are always applied with MVPP2_PRS_RI_L2_CAST_MASK, and therefore there is no need for MVPP2_PRS_RI_L2_UCAST to be defined as ~(BIT(9) | BIT(10)). It fixes the following warnings when building the driver on a 64-bit platform (which is not possible as of this commit, but will be enabled in a follow-up commit): drivers/net/ethernet/marvell/mvpp2.c: In function ‘mvpp2_prs_mac_promisc_set’: drivers/net/ethernet/marvell/mvpp2.c:524:33: warning: large integer implicitly truncated to unsigned type [-Woverflow] #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) ^ drivers/net/ethernet/marvell/mvpp2.c:1459:33: note: in expansion of macro ‘MVPP2_PRS_RI_L2_UCAST’ mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L2_UCAST, Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Acked-by: Russell King <rmk+kernel@armlinux.org.uk> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-02-21 18:28:11 +08:00
#define MVPP2_PRS_RI_L2_CAST_MASK (BIT(9) | BIT(10))
#define MVPP2_PRS_RI_L2_UCAST 0x0
#define MVPP2_PRS_RI_L2_MCAST BIT(9)
#define MVPP2_PRS_RI_L2_BCAST BIT(10)
#define MVPP2_PRS_RI_PPPOE_MASK 0x800
net: mvpp2: simplify MVPP2_PRS_RI_* definitions Some of the MVPP2_PRS_RI_* definitions use the ~(value) syntax, which doesn't compile nicely on 64-bit. Moreover, those definitions are in fact unneeded, since they are always used in combination with a bit mask that ensures only the appropriate bits are modified. Therefore, such definitions should just be set to 0x0. In addition, as suggested by Russell King, we change the _MASK definitions to also use the BIT() macro so that it is clear they are related to the values defined afterwards. For example: #define MVPP2_PRS_RI_L2_CAST_MASK 0x600 #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) becomes #define MVPP2_PRS_RI_L2_CAST_MASK (BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_UCAST 0x0 #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) Because the values (MVPP2_PRS_RI_L2_UCAST, MVPP2_PRS_RI_L2_MCAST and MVPP2_PRS_RI_L2_BCAST) are always applied with MVPP2_PRS_RI_L2_CAST_MASK, and therefore there is no need for MVPP2_PRS_RI_L2_UCAST to be defined as ~(BIT(9) | BIT(10)). It fixes the following warnings when building the driver on a 64-bit platform (which is not possible as of this commit, but will be enabled in a follow-up commit): drivers/net/ethernet/marvell/mvpp2.c: In function ‘mvpp2_prs_mac_promisc_set’: drivers/net/ethernet/marvell/mvpp2.c:524:33: warning: large integer implicitly truncated to unsigned type [-Woverflow] #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) ^ drivers/net/ethernet/marvell/mvpp2.c:1459:33: note: in expansion of macro ‘MVPP2_PRS_RI_L2_UCAST’ mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L2_UCAST, Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Acked-by: Russell King <rmk+kernel@armlinux.org.uk> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-02-21 18:28:11 +08:00
#define MVPP2_PRS_RI_L3_PROTO_MASK (BIT(12) | BIT(13) | BIT(14))
#define MVPP2_PRS_RI_L3_UN 0x0
#define MVPP2_PRS_RI_L3_IP4 BIT(12)
#define MVPP2_PRS_RI_L3_IP4_OPT BIT(13)
#define MVPP2_PRS_RI_L3_IP4_OTHER (BIT(12) | BIT(13))
#define MVPP2_PRS_RI_L3_IP6 BIT(14)
#define MVPP2_PRS_RI_L3_IP6_EXT (BIT(12) | BIT(14))
#define MVPP2_PRS_RI_L3_ARP (BIT(13) | BIT(14))
net: mvpp2: simplify MVPP2_PRS_RI_* definitions Some of the MVPP2_PRS_RI_* definitions use the ~(value) syntax, which doesn't compile nicely on 64-bit. Moreover, those definitions are in fact unneeded, since they are always used in combination with a bit mask that ensures only the appropriate bits are modified. Therefore, such definitions should just be set to 0x0. In addition, as suggested by Russell King, we change the _MASK definitions to also use the BIT() macro so that it is clear they are related to the values defined afterwards. For example: #define MVPP2_PRS_RI_L2_CAST_MASK 0x600 #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) becomes #define MVPP2_PRS_RI_L2_CAST_MASK (BIT(9) | BIT(10)) #define MVPP2_PRS_RI_L2_UCAST 0x0 #define MVPP2_PRS_RI_L2_MCAST BIT(9) #define MVPP2_PRS_RI_L2_BCAST BIT(10) Because the values (MVPP2_PRS_RI_L2_UCAST, MVPP2_PRS_RI_L2_MCAST and MVPP2_PRS_RI_L2_BCAST) are always applied with MVPP2_PRS_RI_L2_CAST_MASK, and therefore there is no need for MVPP2_PRS_RI_L2_UCAST to be defined as ~(BIT(9) | BIT(10)). It fixes the following warnings when building the driver on a 64-bit platform (which is not possible as of this commit, but will be enabled in a follow-up commit): drivers/net/ethernet/marvell/mvpp2.c: In function ‘mvpp2_prs_mac_promisc_set’: drivers/net/ethernet/marvell/mvpp2.c:524:33: warning: large integer implicitly truncated to unsigned type [-Woverflow] #define MVPP2_PRS_RI_L2_UCAST ~(BIT(9) | BIT(10)) ^ drivers/net/ethernet/marvell/mvpp2.c:1459:33: note: in expansion of macro ‘MVPP2_PRS_RI_L2_UCAST’ mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L2_UCAST, Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Acked-by: Russell King <rmk+kernel@armlinux.org.uk> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-02-21 18:28:11 +08:00
#define MVPP2_PRS_RI_L3_ADDR_MASK (BIT(15) | BIT(16))
#define MVPP2_PRS_RI_L3_UCAST 0x0
#define MVPP2_PRS_RI_L3_MCAST BIT(15)
#define MVPP2_PRS_RI_L3_BCAST (BIT(15) | BIT(16))
#define MVPP2_PRS_RI_IP_FRAG_MASK 0x20000
#define MVPP2_PRS_RI_IP_FRAG_TRUE BIT(17)
#define MVPP2_PRS_RI_UDF3_MASK 0x300000
#define MVPP2_PRS_RI_UDF3_RX_SPECIAL BIT(21)
#define MVPP2_PRS_RI_L4_PROTO_MASK 0x1c00000
#define MVPP2_PRS_RI_L4_TCP BIT(22)
#define MVPP2_PRS_RI_L4_UDP BIT(23)
#define MVPP2_PRS_RI_L4_OTHER (BIT(22) | BIT(23))
#define MVPP2_PRS_RI_UDF7_MASK 0x60000000
#define MVPP2_PRS_RI_UDF7_IP6_LITE BIT(29)
#define MVPP2_PRS_RI_DROP_MASK 0x80000000
/* Sram additional info bits assignment */
#define MVPP2_PRS_IPV4_DIP_AI_BIT BIT(0)
#define MVPP2_PRS_IPV6_NO_EXT_AI_BIT BIT(0)
#define MVPP2_PRS_IPV6_EXT_AI_BIT BIT(1)
#define MVPP2_PRS_IPV6_EXT_AH_AI_BIT BIT(2)
#define MVPP2_PRS_IPV6_EXT_AH_LEN_AI_BIT BIT(3)
#define MVPP2_PRS_IPV6_EXT_AH_L4_AI_BIT BIT(4)
#define MVPP2_PRS_SINGLE_VLAN_AI 0
#define MVPP2_PRS_DBL_VLAN_AI_BIT BIT(7)
/* DSA/EDSA type */
#define MVPP2_PRS_TAGGED true
#define MVPP2_PRS_UNTAGGED false
#define MVPP2_PRS_EDSA true
#define MVPP2_PRS_DSA false
/* MAC entries, shadow udf */
enum mvpp2_prs_udf {
MVPP2_PRS_UDF_MAC_DEF,
MVPP2_PRS_UDF_MAC_RANGE,
MVPP2_PRS_UDF_L2_DEF,
MVPP2_PRS_UDF_L2_DEF_COPY,
MVPP2_PRS_UDF_L2_USER,
};
/* Lookup ID */
enum mvpp2_prs_lookup {
MVPP2_PRS_LU_MH,
MVPP2_PRS_LU_MAC,
MVPP2_PRS_LU_DSA,
MVPP2_PRS_LU_VLAN,
MVPP2_PRS_LU_L2,
MVPP2_PRS_LU_PPPOE,
MVPP2_PRS_LU_IP4,
MVPP2_PRS_LU_IP6,
MVPP2_PRS_LU_FLOWS,
MVPP2_PRS_LU_LAST,
};
/* L3 cast enum */
enum mvpp2_prs_l3_cast {
MVPP2_PRS_L3_UNI_CAST,
MVPP2_PRS_L3_MULTI_CAST,
MVPP2_PRS_L3_BROAD_CAST
};
/* Classifier constants */
#define MVPP2_CLS_FLOWS_TBL_SIZE 512
#define MVPP2_CLS_FLOWS_TBL_DATA_WORDS 3
#define MVPP2_CLS_LKP_TBL_SIZE 64
#define MVPP2_CLS_RX_QUEUES 256
/* RSS constants */
#define MVPP22_RSS_TABLE_ENTRIES 32
/* BM constants */
#define MVPP2_BM_POOLS_NUM 8
#define MVPP2_BM_LONG_BUF_NUM 1024
#define MVPP2_BM_SHORT_BUF_NUM 2048
#define MVPP2_BM_POOL_SIZE_MAX (16*1024 - MVPP2_BM_POOL_PTR_ALIGN/4)
#define MVPP2_BM_POOL_PTR_ALIGN 128
#define MVPP2_BM_SWF_LONG_POOL(port) ((port > 2) ? 2 : port)
#define MVPP2_BM_SWF_SHORT_POOL 3
/* BM cookie (32 bits) definition */
#define MVPP2_BM_COOKIE_POOL_OFFS 8
#define MVPP2_BM_COOKIE_CPU_OFFS 24
/* BM short pool packet size
* These value assure that for SWF the total number
* of bytes allocated for each buffer will be 512
*/
#define MVPP2_BM_SHORT_PKT_SIZE MVPP2_RX_MAX_PKT_SIZE(512)
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
#define MVPP21_ADDR_SPACE_SZ 0
#define MVPP22_ADDR_SPACE_SZ SZ_64K
#define MVPP2_MAX_THREADS 8
#define MVPP2_MAX_QVECS MVPP2_MAX_THREADS
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
enum mvpp2_bm_type {
MVPP2_BM_FREE,
MVPP2_BM_SWF_LONG,
MVPP2_BM_SWF_SHORT
};
/* GMAC MIB Counters register definitions */
#define MVPP21_MIB_COUNTERS_OFFSET 0x1000
#define MVPP21_MIB_COUNTERS_PORT_SZ 0x400
#define MVPP22_MIB_COUNTERS_OFFSET 0x0
#define MVPP22_MIB_COUNTERS_PORT_SZ 0x100
#define MVPP2_MIB_GOOD_OCTETS_RCVD 0x0
#define MVPP2_MIB_BAD_OCTETS_RCVD 0x8
#define MVPP2_MIB_CRC_ERRORS_SENT 0xc
#define MVPP2_MIB_UNICAST_FRAMES_RCVD 0x10
#define MVPP2_MIB_BROADCAST_FRAMES_RCVD 0x18
#define MVPP2_MIB_MULTICAST_FRAMES_RCVD 0x1c
#define MVPP2_MIB_FRAMES_64_OCTETS 0x20
#define MVPP2_MIB_FRAMES_65_TO_127_OCTETS 0x24
#define MVPP2_MIB_FRAMES_128_TO_255_OCTETS 0x28
#define MVPP2_MIB_FRAMES_256_TO_511_OCTETS 0x2c
#define MVPP2_MIB_FRAMES_512_TO_1023_OCTETS 0x30
#define MVPP2_MIB_FRAMES_1024_TO_MAX_OCTETS 0x34
#define MVPP2_MIB_GOOD_OCTETS_SENT 0x38
#define MVPP2_MIB_UNICAST_FRAMES_SENT 0x40
#define MVPP2_MIB_MULTICAST_FRAMES_SENT 0x48
#define MVPP2_MIB_BROADCAST_FRAMES_SENT 0x4c
#define MVPP2_MIB_FC_SENT 0x54
#define MVPP2_MIB_FC_RCVD 0x58
#define MVPP2_MIB_RX_FIFO_OVERRUN 0x5c
#define MVPP2_MIB_UNDERSIZE_RCVD 0x60
#define MVPP2_MIB_FRAGMENTS_RCVD 0x64
#define MVPP2_MIB_OVERSIZE_RCVD 0x68
#define MVPP2_MIB_JABBER_RCVD 0x6c
#define MVPP2_MIB_MAC_RCV_ERROR 0x70
#define MVPP2_MIB_BAD_CRC_EVENT 0x74
#define MVPP2_MIB_COLLISION 0x78
#define MVPP2_MIB_LATE_COLLISION 0x7c
#define MVPP2_MIB_COUNTERS_STATS_DELAY (1 * HZ)
/* Definitions */
/* Shared Packet Processor resources */
struct mvpp2 {
/* Shared registers' base addresses */
void __iomem *lms_base;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
void __iomem *iface_base;
/* On PPv2.2, each "software thread" can access the base
* register through a separate address space, each 64 KB apart
* from each other. Typically, such address spaces will be
* used per CPU.
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
*/
void __iomem *swth_base[MVPP2_MAX_THREADS];
/* On PPv2.2, some port control registers are located into the system
* controller space. These registers are accessible through a regmap.
*/
struct regmap *sysctrl_base;
/* Common clocks */
struct clk *pp_clk;
struct clk *gop_clk;
struct clk *mg_clk;
struct clk *axi_clk;
/* List of pointers to port structures */
int port_count;
struct mvpp2_port **port_list;
/* Aggregated TXQs */
struct mvpp2_tx_queue *aggr_txqs;
/* BM pools */
struct mvpp2_bm_pool *bm_pools;
/* PRS shadow table */
struct mvpp2_prs_shadow *prs_shadow;
/* PRS auxiliary table for double vlan entries control */
bool *prs_double_vlans;
/* Tclk value */
u32 tclk;
/* HW version */
enum { MVPP21, MVPP22 } hw_version;
/* Maximum number of RXQs per port */
unsigned int max_port_rxqs;
/* Workqueue to gather hardware statistics */
char queue_name[30];
struct workqueue_struct *stats_queue;
};
struct mvpp2_pcpu_stats {
struct u64_stats_sync syncp;
u64 rx_packets;
u64 rx_bytes;
u64 tx_packets;
u64 tx_bytes;
};
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
/* Per-CPU port control */
struct mvpp2_port_pcpu {
struct hrtimer tx_done_timer;
bool timer_scheduled;
/* Tasklet for egress finalization */
struct tasklet_struct tx_done_tasklet;
};
struct mvpp2_queue_vector {
int irq;
struct napi_struct napi;
enum { MVPP2_QUEUE_VECTOR_SHARED, MVPP2_QUEUE_VECTOR_PRIVATE } type;
int sw_thread_id;
u16 sw_thread_mask;
int first_rxq;
int nrxqs;
u32 pending_cause_rx;
struct mvpp2_port *port;
};
struct mvpp2_port {
u8 id;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
/* Index of the port from the "group of ports" complex point
* of view
*/
int gop_id;
int link_irq;
struct mvpp2 *priv;
/* Per-port registers' base address */
void __iomem *base;
void __iomem *stats_base;
struct mvpp2_rx_queue **rxqs;
unsigned int nrxqs;
struct mvpp2_tx_queue **txqs;
unsigned int ntxqs;
struct net_device *dev;
int pkt_size;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
/* Per-CPU port control */
struct mvpp2_port_pcpu __percpu *pcpu;
/* Flags */
unsigned long flags;
u16 tx_ring_size;
u16 rx_ring_size;
struct mvpp2_pcpu_stats __percpu *stats;
u64 *ethtool_stats;
/* Per-port work and its lock to gather hardware statistics */
struct mutex gather_stats_lock;
struct delayed_work stats_work;
phy_interface_t phy_interface;
struct device_node *phy_node;
struct phy *comphy;
unsigned int link;
unsigned int duplex;
unsigned int speed;
struct mvpp2_bm_pool *pool_long;
struct mvpp2_bm_pool *pool_short;
/* Index of first port's physical RXQ */
u8 first_rxq;
struct mvpp2_queue_vector qvecs[MVPP2_MAX_QVECS];
unsigned int nqvecs;
bool has_tx_irqs;
u32 tx_time_coal;
};
/* The mvpp2_tx_desc and mvpp2_rx_desc structures describe the
* layout of the transmit and reception DMA descriptors, and their
* layout is therefore defined by the hardware design
*/
#define MVPP2_TXD_L3_OFF_SHIFT 0
#define MVPP2_TXD_IP_HLEN_SHIFT 8
#define MVPP2_TXD_L4_CSUM_FRAG BIT(13)
#define MVPP2_TXD_L4_CSUM_NOT BIT(14)
#define MVPP2_TXD_IP_CSUM_DISABLE BIT(15)
#define MVPP2_TXD_PADDING_DISABLE BIT(23)
#define MVPP2_TXD_L4_UDP BIT(24)
#define MVPP2_TXD_L3_IP6 BIT(26)
#define MVPP2_TXD_L_DESC BIT(28)
#define MVPP2_TXD_F_DESC BIT(29)
#define MVPP2_RXD_ERR_SUMMARY BIT(15)
#define MVPP2_RXD_ERR_CODE_MASK (BIT(13) | BIT(14))
#define MVPP2_RXD_ERR_CRC 0x0
#define MVPP2_RXD_ERR_OVERRUN BIT(13)
#define MVPP2_RXD_ERR_RESOURCE (BIT(13) | BIT(14))
#define MVPP2_RXD_BM_POOL_ID_OFFS 16
#define MVPP2_RXD_BM_POOL_ID_MASK (BIT(16) | BIT(17) | BIT(18))
#define MVPP2_RXD_HWF_SYNC BIT(21)
#define MVPP2_RXD_L4_CSUM_OK BIT(22)
#define MVPP2_RXD_IP4_HEADER_ERR BIT(24)
#define MVPP2_RXD_L4_TCP BIT(25)
#define MVPP2_RXD_L4_UDP BIT(26)
#define MVPP2_RXD_L3_IP4 BIT(28)
#define MVPP2_RXD_L3_IP6 BIT(30)
#define MVPP2_RXD_BUF_HDR BIT(31)
/* HW TX descriptor for PPv2.1 */
struct mvpp21_tx_desc {
u32 command; /* Options used by HW for packet transmitting.*/
u8 packet_offset; /* the offset from the buffer beginning */
u8 phys_txq; /* destination queue ID */
u16 data_size; /* data size of transmitted packet in bytes */
u32 buf_dma_addr; /* physical addr of transmitted buffer */
u32 buf_cookie; /* cookie for access to TX buffer in tx path */
u32 reserved1[3]; /* hw_cmd (for future use, BM, PON, PNC) */
u32 reserved2; /* reserved (for future use) */
};
/* HW RX descriptor for PPv2.1 */
struct mvpp21_rx_desc {
u32 status; /* info about received packet */
u16 reserved1; /* parser_info (for future use, PnC) */
u16 data_size; /* size of received packet in bytes */
u32 buf_dma_addr; /* physical address of the buffer */
u32 buf_cookie; /* cookie for access to RX buffer in rx path */
u16 reserved2; /* gem_port_id (for future use, PON) */
u16 reserved3; /* csum_l4 (for future use, PnC) */
u8 reserved4; /* bm_qset (for future use, BM) */
u8 reserved5;
u16 reserved6; /* classify_info (for future use, PnC) */
u32 reserved7; /* flow_id (for future use, PnC) */
u32 reserved8;
};
/* HW TX descriptor for PPv2.2 */
struct mvpp22_tx_desc {
u32 command;
u8 packet_offset;
u8 phys_txq;
u16 data_size;
u64 reserved1;
u64 buf_dma_addr_ptp;
u64 buf_cookie_misc;
};
/* HW RX descriptor for PPv2.2 */
struct mvpp22_rx_desc {
u32 status;
u16 reserved1;
u16 data_size;
u32 reserved2;
u32 reserved3;
u64 buf_dma_addr_key_hash;
u64 buf_cookie_misc;
};
/* Opaque type used by the driver to manipulate the HW TX and RX
* descriptors
*/
struct mvpp2_tx_desc {
union {
struct mvpp21_tx_desc pp21;
struct mvpp22_tx_desc pp22;
};
};
struct mvpp2_rx_desc {
union {
struct mvpp21_rx_desc pp21;
struct mvpp22_rx_desc pp22;
};
};
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
struct mvpp2_txq_pcpu_buf {
/* Transmitted SKB */
struct sk_buff *skb;
/* Physical address of transmitted buffer */
dma_addr_t dma;
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
/* Size transmitted */
size_t size;
};
/* Per-CPU Tx queue control */
struct mvpp2_txq_pcpu {
int cpu;
/* Number of Tx DMA descriptors in the descriptor ring */
int size;
/* Number of currently used Tx DMA descriptor in the
* descriptor ring
*/
int count;
int wake_threshold;
int stop_threshold;
/* Number of Tx DMA descriptors reserved for each CPU */
int reserved_num;
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
/* Infos about transmitted buffers */
struct mvpp2_txq_pcpu_buf *buffs;
/* Index of last TX DMA descriptor that was inserted */
int txq_put_index;
/* Index of the TX DMA descriptor to be cleaned up */
int txq_get_index;
/* DMA buffer for TSO headers */
char *tso_headers;
dma_addr_t tso_headers_dma;
};
struct mvpp2_tx_queue {
/* Physical number of this Tx queue */
u8 id;
/* Logical number of this Tx queue */
u8 log_id;
/* Number of Tx DMA descriptors in the descriptor ring */
int size;
/* Number of currently used Tx DMA descriptor in the descriptor ring */
int count;
/* Per-CPU control of physical Tx queues */
struct mvpp2_txq_pcpu __percpu *pcpu;
u32 done_pkts_coal;
/* Virtual address of thex Tx DMA descriptors array */
struct mvpp2_tx_desc *descs;
/* DMA address of the Tx DMA descriptors array */
dma_addr_t descs_dma;
/* Index of the last Tx DMA descriptor */
int last_desc;
/* Index of the next Tx DMA descriptor to process */
int next_desc_to_proc;
};
struct mvpp2_rx_queue {
/* RX queue number, in the range 0-31 for physical RXQs */
u8 id;
/* Num of rx descriptors in the rx descriptor ring */
int size;
u32 pkts_coal;
u32 time_coal;
/* Virtual address of the RX DMA descriptors array */
struct mvpp2_rx_desc *descs;
/* DMA address of the RX DMA descriptors array */
dma_addr_t descs_dma;
/* Index of the last RX DMA descriptor */
int last_desc;
/* Index of the next RX DMA descriptor to process */
int next_desc_to_proc;
/* ID of port to which physical RXQ is mapped */
int port;
/* Port's logic RXQ number to which physical RXQ is mapped */
int logic_rxq;
};
union mvpp2_prs_tcam_entry {
u32 word[MVPP2_PRS_TCAM_WORDS];
u8 byte[MVPP2_PRS_TCAM_WORDS * 4];
};
union mvpp2_prs_sram_entry {
u32 word[MVPP2_PRS_SRAM_WORDS];
u8 byte[MVPP2_PRS_SRAM_WORDS * 4];
};
struct mvpp2_prs_entry {
u32 index;
union mvpp2_prs_tcam_entry tcam;
union mvpp2_prs_sram_entry sram;
};
struct mvpp2_prs_shadow {
bool valid;
bool finish;
/* Lookup ID */
int lu;
/* User defined offset */
int udf;
/* Result info */
u32 ri;
u32 ri_mask;
};
struct mvpp2_cls_flow_entry {
u32 index;
u32 data[MVPP2_CLS_FLOWS_TBL_DATA_WORDS];
};
struct mvpp2_cls_lookup_entry {
u32 lkpid;
u32 way;
u32 data;
};
struct mvpp2_bm_pool {
/* Pool number in the range 0-7 */
int id;
enum mvpp2_bm_type type;
/* Buffer Pointers Pool External (BPPE) size */
int size;
/* BPPE size in bytes */
int size_bytes;
/* Number of buffers for this pool */
int buf_num;
/* Pool buffer size */
int buf_size;
/* Packet size */
int pkt_size;
int frag_size;
/* BPPE virtual base address */
u32 *virt_addr;
/* BPPE DMA base address */
dma_addr_t dma_addr;
/* Ports using BM pool */
u32 port_map;
};
#define IS_TSO_HEADER(txq_pcpu, addr) \
((addr) >= (txq_pcpu)->tso_headers_dma && \
(addr) < (txq_pcpu)->tso_headers_dma + \
(txq_pcpu)->size * TSO_HEADER_SIZE)
/* Queue modes */
#define MVPP2_QDIST_SINGLE_MODE 0
#define MVPP2_QDIST_MULTI_MODE 1
static int queue_mode = MVPP2_QDIST_SINGLE_MODE;
module_param(queue_mode, int, 0444);
MODULE_PARM_DESC(queue_mode, "Set queue_mode (single=0, multi=1)");
#define MVPP2_DRIVER_NAME "mvpp2"
#define MVPP2_DRIVER_VERSION "1.0"
/* Utility/helper methods */
static void mvpp2_write(struct mvpp2 *priv, u32 offset, u32 data)
{
writel(data, priv->swth_base[0] + offset);
}
static u32 mvpp2_read(struct mvpp2 *priv, u32 offset)
{
return readl(priv->swth_base[0] + offset);
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
}
/* These accessors should be used to access:
*
* - per-CPU registers, where each CPU has its own copy of the
* register.
*
* MVPP2_BM_VIRT_ALLOC_REG
* MVPP2_BM_ADDR_HIGH_ALLOC
* MVPP22_BM_ADDR_HIGH_RLS_REG
* MVPP2_BM_VIRT_RLS_REG
* MVPP2_ISR_RX_TX_CAUSE_REG
* MVPP2_ISR_RX_TX_MASK_REG
* MVPP2_TXQ_NUM_REG
* MVPP2_AGGR_TXQ_UPDATE_REG
* MVPP2_TXQ_RSVD_REQ_REG
* MVPP2_TXQ_RSVD_RSLT_REG
* MVPP2_TXQ_SENT_REG
* MVPP2_RXQ_NUM_REG
*
* - global registers that must be accessed through a specific CPU
* window, because they are related to an access to a per-CPU
* register
*
* MVPP2_BM_PHY_ALLOC_REG (related to MVPP2_BM_VIRT_ALLOC_REG)
* MVPP2_BM_PHY_RLS_REG (related to MVPP2_BM_VIRT_RLS_REG)
* MVPP2_RXQ_THRESH_REG (related to MVPP2_RXQ_NUM_REG)
* MVPP2_RXQ_DESC_ADDR_REG (related to MVPP2_RXQ_NUM_REG)
* MVPP2_RXQ_DESC_SIZE_REG (related to MVPP2_RXQ_NUM_REG)
* MVPP2_RXQ_INDEX_REG (related to MVPP2_RXQ_NUM_REG)
* MVPP2_TXQ_PENDING_REG (related to MVPP2_TXQ_NUM_REG)
* MVPP2_TXQ_DESC_ADDR_REG (related to MVPP2_TXQ_NUM_REG)
* MVPP2_TXQ_DESC_SIZE_REG (related to MVPP2_TXQ_NUM_REG)
* MVPP2_TXQ_INDEX_REG (related to MVPP2_TXQ_NUM_REG)
* MVPP2_TXQ_PENDING_REG (related to MVPP2_TXQ_NUM_REG)
* MVPP2_TXQ_PREF_BUF_REG (related to MVPP2_TXQ_NUM_REG)
* MVPP2_TXQ_PREF_BUF_REG (related to MVPP2_TXQ_NUM_REG)
*/
static void mvpp2_percpu_write(struct mvpp2 *priv, int cpu,
u32 offset, u32 data)
{
writel(data, priv->swth_base[cpu] + offset);
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
}
static u32 mvpp2_percpu_read(struct mvpp2 *priv, int cpu,
u32 offset)
{
return readl(priv->swth_base[cpu] + offset);
}
static dma_addr_t mvpp2_txdesc_dma_addr_get(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc)
{
if (port->priv->hw_version == MVPP21)
return tx_desc->pp21.buf_dma_addr;
else
return tx_desc->pp22.buf_dma_addr_ptp & GENMASK_ULL(40, 0);
}
static void mvpp2_txdesc_dma_addr_set(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc,
dma_addr_t dma_addr)
{
dma_addr_t addr, offset;
addr = dma_addr & ~MVPP2_TX_DESC_ALIGN;
offset = dma_addr & MVPP2_TX_DESC_ALIGN;
if (port->priv->hw_version == MVPP21) {
tx_desc->pp21.buf_dma_addr = addr;
tx_desc->pp21.packet_offset = offset;
} else {
u64 val = (u64)addr;
tx_desc->pp22.buf_dma_addr_ptp &= ~GENMASK_ULL(40, 0);
tx_desc->pp22.buf_dma_addr_ptp |= val;
tx_desc->pp22.packet_offset = offset;
}
}
static size_t mvpp2_txdesc_size_get(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc)
{
if (port->priv->hw_version == MVPP21)
return tx_desc->pp21.data_size;
else
return tx_desc->pp22.data_size;
}
static void mvpp2_txdesc_size_set(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc,
size_t size)
{
if (port->priv->hw_version == MVPP21)
tx_desc->pp21.data_size = size;
else
tx_desc->pp22.data_size = size;
}
static void mvpp2_txdesc_txq_set(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc,
unsigned int txq)
{
if (port->priv->hw_version == MVPP21)
tx_desc->pp21.phys_txq = txq;
else
tx_desc->pp22.phys_txq = txq;
}
static void mvpp2_txdesc_cmd_set(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc,
unsigned int command)
{
if (port->priv->hw_version == MVPP21)
tx_desc->pp21.command = command;
else
tx_desc->pp22.command = command;
}
static unsigned int mvpp2_txdesc_offset_get(struct mvpp2_port *port,
struct mvpp2_tx_desc *tx_desc)
{
if (port->priv->hw_version == MVPP21)
return tx_desc->pp21.packet_offset;
else
return tx_desc->pp22.packet_offset;
}
static dma_addr_t mvpp2_rxdesc_dma_addr_get(struct mvpp2_port *port,
struct mvpp2_rx_desc *rx_desc)
{
if (port->priv->hw_version == MVPP21)
return rx_desc->pp21.buf_dma_addr;
else
return rx_desc->pp22.buf_dma_addr_key_hash & GENMASK_ULL(40, 0);
}
static unsigned long mvpp2_rxdesc_cookie_get(struct mvpp2_port *port,
struct mvpp2_rx_desc *rx_desc)
{
if (port->priv->hw_version == MVPP21)
return rx_desc->pp21.buf_cookie;
else
return rx_desc->pp22.buf_cookie_misc & GENMASK_ULL(40, 0);
}
static size_t mvpp2_rxdesc_size_get(struct mvpp2_port *port,
struct mvpp2_rx_desc *rx_desc)
{
if (port->priv->hw_version == MVPP21)
return rx_desc->pp21.data_size;
else
return rx_desc->pp22.data_size;
}
static u32 mvpp2_rxdesc_status_get(struct mvpp2_port *port,
struct mvpp2_rx_desc *rx_desc)
{
if (port->priv->hw_version == MVPP21)
return rx_desc->pp21.status;
else
return rx_desc->pp22.status;
}
static void mvpp2_txq_inc_get(struct mvpp2_txq_pcpu *txq_pcpu)
{
txq_pcpu->txq_get_index++;
if (txq_pcpu->txq_get_index == txq_pcpu->size)
txq_pcpu->txq_get_index = 0;
}
static void mvpp2_txq_inc_put(struct mvpp2_port *port,
struct mvpp2_txq_pcpu *txq_pcpu,
struct sk_buff *skb,
struct mvpp2_tx_desc *tx_desc)
{
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
struct mvpp2_txq_pcpu_buf *tx_buf =
txq_pcpu->buffs + txq_pcpu->txq_put_index;
tx_buf->skb = skb;
tx_buf->size = mvpp2_txdesc_size_get(port, tx_desc);
tx_buf->dma = mvpp2_txdesc_dma_addr_get(port, tx_desc) +
mvpp2_txdesc_offset_get(port, tx_desc);
txq_pcpu->txq_put_index++;
if (txq_pcpu->txq_put_index == txq_pcpu->size)
txq_pcpu->txq_put_index = 0;
}
/* Get number of physical egress port */
static inline int mvpp2_egress_port(struct mvpp2_port *port)
{
return MVPP2_MAX_TCONT + port->id;
}
/* Get number of physical TXQ */
static inline int mvpp2_txq_phys(int port, int txq)
{
return (MVPP2_MAX_TCONT + port) * MVPP2_MAX_TXQ + txq;
}
/* Parser configuration routines */
/* Update parser tcam and sram hw entries */
static int mvpp2_prs_hw_write(struct mvpp2 *priv, struct mvpp2_prs_entry *pe)
{
int i;
if (pe->index > MVPP2_PRS_TCAM_SRAM_SIZE - 1)
return -EINVAL;
/* Clear entry invalidation bit */
pe->tcam.word[MVPP2_PRS_TCAM_INV_WORD] &= ~MVPP2_PRS_TCAM_INV_MASK;
/* Write tcam index - indirect access */
mvpp2_write(priv, MVPP2_PRS_TCAM_IDX_REG, pe->index);
for (i = 0; i < MVPP2_PRS_TCAM_WORDS; i++)
mvpp2_write(priv, MVPP2_PRS_TCAM_DATA_REG(i), pe->tcam.word[i]);
/* Write sram index - indirect access */
mvpp2_write(priv, MVPP2_PRS_SRAM_IDX_REG, pe->index);
for (i = 0; i < MVPP2_PRS_SRAM_WORDS; i++)
mvpp2_write(priv, MVPP2_PRS_SRAM_DATA_REG(i), pe->sram.word[i]);
return 0;
}
/* Read tcam entry from hw */
static int mvpp2_prs_hw_read(struct mvpp2 *priv, struct mvpp2_prs_entry *pe)
{
int i;
if (pe->index > MVPP2_PRS_TCAM_SRAM_SIZE - 1)
return -EINVAL;
/* Write tcam index - indirect access */
mvpp2_write(priv, MVPP2_PRS_TCAM_IDX_REG, pe->index);
pe->tcam.word[MVPP2_PRS_TCAM_INV_WORD] = mvpp2_read(priv,
MVPP2_PRS_TCAM_DATA_REG(MVPP2_PRS_TCAM_INV_WORD));
if (pe->tcam.word[MVPP2_PRS_TCAM_INV_WORD] & MVPP2_PRS_TCAM_INV_MASK)
return MVPP2_PRS_TCAM_ENTRY_INVALID;
for (i = 0; i < MVPP2_PRS_TCAM_WORDS; i++)
pe->tcam.word[i] = mvpp2_read(priv, MVPP2_PRS_TCAM_DATA_REG(i));
/* Write sram index - indirect access */
mvpp2_write(priv, MVPP2_PRS_SRAM_IDX_REG, pe->index);
for (i = 0; i < MVPP2_PRS_SRAM_WORDS; i++)
pe->sram.word[i] = mvpp2_read(priv, MVPP2_PRS_SRAM_DATA_REG(i));
return 0;
}
/* Invalidate tcam hw entry */
static void mvpp2_prs_hw_inv(struct mvpp2 *priv, int index)
{
/* Write index - indirect access */
mvpp2_write(priv, MVPP2_PRS_TCAM_IDX_REG, index);
mvpp2_write(priv, MVPP2_PRS_TCAM_DATA_REG(MVPP2_PRS_TCAM_INV_WORD),
MVPP2_PRS_TCAM_INV_MASK);
}
/* Enable shadow table entry and set its lookup ID */
static void mvpp2_prs_shadow_set(struct mvpp2 *priv, int index, int lu)
{
priv->prs_shadow[index].valid = true;
priv->prs_shadow[index].lu = lu;
}
/* Update ri fields in shadow table entry */
static void mvpp2_prs_shadow_ri_set(struct mvpp2 *priv, int index,
unsigned int ri, unsigned int ri_mask)
{
priv->prs_shadow[index].ri_mask = ri_mask;
priv->prs_shadow[index].ri = ri;
}
/* Update lookup field in tcam sw entry */
static void mvpp2_prs_tcam_lu_set(struct mvpp2_prs_entry *pe, unsigned int lu)
{
int enable_off = MVPP2_PRS_TCAM_EN_OFFS(MVPP2_PRS_TCAM_LU_BYTE);
pe->tcam.byte[MVPP2_PRS_TCAM_LU_BYTE] = lu;
pe->tcam.byte[enable_off] = MVPP2_PRS_LU_MASK;
}
/* Update mask for single port in tcam sw entry */
static void mvpp2_prs_tcam_port_set(struct mvpp2_prs_entry *pe,
unsigned int port, bool add)
{
int enable_off = MVPP2_PRS_TCAM_EN_OFFS(MVPP2_PRS_TCAM_PORT_BYTE);
if (add)
pe->tcam.byte[enable_off] &= ~(1 << port);
else
pe->tcam.byte[enable_off] |= 1 << port;
}
/* Update port map in tcam sw entry */
static void mvpp2_prs_tcam_port_map_set(struct mvpp2_prs_entry *pe,
unsigned int ports)
{
unsigned char port_mask = MVPP2_PRS_PORT_MASK;
int enable_off = MVPP2_PRS_TCAM_EN_OFFS(MVPP2_PRS_TCAM_PORT_BYTE);
pe->tcam.byte[MVPP2_PRS_TCAM_PORT_BYTE] = 0;
pe->tcam.byte[enable_off] &= ~port_mask;
pe->tcam.byte[enable_off] |= ~ports & MVPP2_PRS_PORT_MASK;
}
/* Obtain port map from tcam sw entry */
static unsigned int mvpp2_prs_tcam_port_map_get(struct mvpp2_prs_entry *pe)
{
int enable_off = MVPP2_PRS_TCAM_EN_OFFS(MVPP2_PRS_TCAM_PORT_BYTE);
return ~(pe->tcam.byte[enable_off]) & MVPP2_PRS_PORT_MASK;
}
/* Set byte of data and its enable bits in tcam sw entry */
static void mvpp2_prs_tcam_data_byte_set(struct mvpp2_prs_entry *pe,
unsigned int offs, unsigned char byte,
unsigned char enable)
{
pe->tcam.byte[MVPP2_PRS_TCAM_DATA_BYTE(offs)] = byte;
pe->tcam.byte[MVPP2_PRS_TCAM_DATA_BYTE_EN(offs)] = enable;
}
/* Get byte of data and its enable bits from tcam sw entry */
static void mvpp2_prs_tcam_data_byte_get(struct mvpp2_prs_entry *pe,
unsigned int offs, unsigned char *byte,
unsigned char *enable)
{
*byte = pe->tcam.byte[MVPP2_PRS_TCAM_DATA_BYTE(offs)];
*enable = pe->tcam.byte[MVPP2_PRS_TCAM_DATA_BYTE_EN(offs)];
}
/* Compare tcam data bytes with a pattern */
static bool mvpp2_prs_tcam_data_cmp(struct mvpp2_prs_entry *pe, int offs,
u16 data)
{
int off = MVPP2_PRS_TCAM_DATA_BYTE(offs);
u16 tcam_data;
tcam_data = (pe->tcam.byte[off + 1] << 8) | pe->tcam.byte[off];
if (tcam_data != data)
return false;
return true;
}
/* Update ai bits in tcam sw entry */
static void mvpp2_prs_tcam_ai_update(struct mvpp2_prs_entry *pe,
unsigned int bits, unsigned int enable)
{
int i, ai_idx = MVPP2_PRS_TCAM_AI_BYTE;
for (i = 0; i < MVPP2_PRS_AI_BITS; i++) {
if (!(enable & BIT(i)))
continue;
if (bits & BIT(i))
pe->tcam.byte[ai_idx] |= 1 << i;
else
pe->tcam.byte[ai_idx] &= ~(1 << i);
}
pe->tcam.byte[MVPP2_PRS_TCAM_EN_OFFS(ai_idx)] |= enable;
}
/* Get ai bits from tcam sw entry */
static int mvpp2_prs_tcam_ai_get(struct mvpp2_prs_entry *pe)
{
return pe->tcam.byte[MVPP2_PRS_TCAM_AI_BYTE];
}
/* Set ethertype in tcam sw entry */
static void mvpp2_prs_match_etype(struct mvpp2_prs_entry *pe, int offset,
unsigned short ethertype)
{
mvpp2_prs_tcam_data_byte_set(pe, offset + 0, ethertype >> 8, 0xff);
mvpp2_prs_tcam_data_byte_set(pe, offset + 1, ethertype & 0xff, 0xff);
}
/* Set bits in sram sw entry */
static void mvpp2_prs_sram_bits_set(struct mvpp2_prs_entry *pe, int bit_num,
int val)
{
pe->sram.byte[MVPP2_BIT_TO_BYTE(bit_num)] |= (val << (bit_num % 8));
}
/* Clear bits in sram sw entry */
static void mvpp2_prs_sram_bits_clear(struct mvpp2_prs_entry *pe, int bit_num,
int val)
{
pe->sram.byte[MVPP2_BIT_TO_BYTE(bit_num)] &= ~(val << (bit_num % 8));
}
/* Update ri bits in sram sw entry */
static void mvpp2_prs_sram_ri_update(struct mvpp2_prs_entry *pe,
unsigned int bits, unsigned int mask)
{
unsigned int i;
for (i = 0; i < MVPP2_PRS_SRAM_RI_CTRL_BITS; i++) {
int ri_off = MVPP2_PRS_SRAM_RI_OFFS;
if (!(mask & BIT(i)))
continue;
if (bits & BIT(i))
mvpp2_prs_sram_bits_set(pe, ri_off + i, 1);
else
mvpp2_prs_sram_bits_clear(pe, ri_off + i, 1);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_RI_CTRL_OFFS + i, 1);
}
}
/* Obtain ri bits from sram sw entry */
static int mvpp2_prs_sram_ri_get(struct mvpp2_prs_entry *pe)
{
return pe->sram.word[MVPP2_PRS_SRAM_RI_WORD];
}
/* Update ai bits in sram sw entry */
static void mvpp2_prs_sram_ai_update(struct mvpp2_prs_entry *pe,
unsigned int bits, unsigned int mask)
{
unsigned int i;
int ai_off = MVPP2_PRS_SRAM_AI_OFFS;
for (i = 0; i < MVPP2_PRS_SRAM_AI_CTRL_BITS; i++) {
if (!(mask & BIT(i)))
continue;
if (bits & BIT(i))
mvpp2_prs_sram_bits_set(pe, ai_off + i, 1);
else
mvpp2_prs_sram_bits_clear(pe, ai_off + i, 1);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_AI_CTRL_OFFS + i, 1);
}
}
/* Read ai bits from sram sw entry */
static int mvpp2_prs_sram_ai_get(struct mvpp2_prs_entry *pe)
{
u8 bits;
int ai_off = MVPP2_BIT_TO_BYTE(MVPP2_PRS_SRAM_AI_OFFS);
int ai_en_off = ai_off + 1;
int ai_shift = MVPP2_PRS_SRAM_AI_OFFS % 8;
bits = (pe->sram.byte[ai_off] >> ai_shift) |
(pe->sram.byte[ai_en_off] << (8 - ai_shift));
return bits;
}
/* In sram sw entry set lookup ID field of the tcam key to be used in the next
* lookup interation
*/
static void mvpp2_prs_sram_next_lu_set(struct mvpp2_prs_entry *pe,
unsigned int lu)
{
int sram_next_off = MVPP2_PRS_SRAM_NEXT_LU_OFFS;
mvpp2_prs_sram_bits_clear(pe, sram_next_off,
MVPP2_PRS_SRAM_NEXT_LU_MASK);
mvpp2_prs_sram_bits_set(pe, sram_next_off, lu);
}
/* In the sram sw entry set sign and value of the next lookup offset
* and the offset value generated to the classifier
*/
static void mvpp2_prs_sram_shift_set(struct mvpp2_prs_entry *pe, int shift,
unsigned int op)
{
/* Set sign */
if (shift < 0) {
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_SHIFT_SIGN_BIT, 1);
shift = 0 - shift;
} else {
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_SHIFT_SIGN_BIT, 1);
}
/* Set value */
pe->sram.byte[MVPP2_BIT_TO_BYTE(MVPP2_PRS_SRAM_SHIFT_OFFS)] =
(unsigned char)shift;
/* Reset and set operation */
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_OP_SEL_SHIFT_OFFS,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_MASK);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_OP_SEL_SHIFT_OFFS, op);
/* Set base offset as current */
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_OP_SEL_BASE_OFFS, 1);
}
/* In the sram sw entry set sign and value of the user defined offset
* generated to the classifier
*/
static void mvpp2_prs_sram_offset_set(struct mvpp2_prs_entry *pe,
unsigned int type, int offset,
unsigned int op)
{
/* Set sign */
if (offset < 0) {
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_UDF_SIGN_BIT, 1);
offset = 0 - offset;
} else {
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_UDF_SIGN_BIT, 1);
}
/* Set value */
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_UDF_OFFS,
MVPP2_PRS_SRAM_UDF_MASK);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_UDF_OFFS, offset);
pe->sram.byte[MVPP2_BIT_TO_BYTE(MVPP2_PRS_SRAM_UDF_OFFS +
MVPP2_PRS_SRAM_UDF_BITS)] &=
~(MVPP2_PRS_SRAM_UDF_MASK >> (8 - (MVPP2_PRS_SRAM_UDF_OFFS % 8)));
pe->sram.byte[MVPP2_BIT_TO_BYTE(MVPP2_PRS_SRAM_UDF_OFFS +
MVPP2_PRS_SRAM_UDF_BITS)] |=
(offset >> (8 - (MVPP2_PRS_SRAM_UDF_OFFS % 8)));
/* Set offset type */
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_UDF_TYPE_OFFS,
MVPP2_PRS_SRAM_UDF_TYPE_MASK);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_UDF_TYPE_OFFS, type);
/* Set offset operation */
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS,
MVPP2_PRS_SRAM_OP_SEL_UDF_MASK);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS, op);
pe->sram.byte[MVPP2_BIT_TO_BYTE(MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS +
MVPP2_PRS_SRAM_OP_SEL_UDF_BITS)] &=
~(MVPP2_PRS_SRAM_OP_SEL_UDF_MASK >>
(8 - (MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS % 8)));
pe->sram.byte[MVPP2_BIT_TO_BYTE(MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS +
MVPP2_PRS_SRAM_OP_SEL_UDF_BITS)] |=
(op >> (8 - (MVPP2_PRS_SRAM_OP_SEL_UDF_OFFS % 8)));
/* Set base offset as current */
mvpp2_prs_sram_bits_clear(pe, MVPP2_PRS_SRAM_OP_SEL_BASE_OFFS, 1);
}
/* Find parser flow entry */
static struct mvpp2_prs_entry *mvpp2_prs_flow_find(struct mvpp2 *priv, int flow)
{
struct mvpp2_prs_entry *pe;
int tid;
pe = kzalloc(sizeof(*pe), GFP_KERNEL);
if (!pe)
return NULL;
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_FLOWS);
/* Go through the all entires with MVPP2_PRS_LU_FLOWS */
for (tid = MVPP2_PRS_TCAM_SRAM_SIZE - 1; tid >= 0; tid--) {
u8 bits;
if (!priv->prs_shadow[tid].valid ||
priv->prs_shadow[tid].lu != MVPP2_PRS_LU_FLOWS)
continue;
pe->index = tid;
mvpp2_prs_hw_read(priv, pe);
bits = mvpp2_prs_sram_ai_get(pe);
/* Sram store classification lookup ID in AI bits [5:0] */
if ((bits & MVPP2_PRS_FLOW_ID_MASK) == flow)
return pe;
}
kfree(pe);
return NULL;
}
/* Return first free tcam index, seeking from start to end */
static int mvpp2_prs_tcam_first_free(struct mvpp2 *priv, unsigned char start,
unsigned char end)
{
int tid;
if (start > end)
swap(start, end);
if (end >= MVPP2_PRS_TCAM_SRAM_SIZE)
end = MVPP2_PRS_TCAM_SRAM_SIZE - 1;
for (tid = start; tid <= end; tid++) {
if (!priv->prs_shadow[tid].valid)
return tid;
}
return -EINVAL;
}
/* Enable/disable dropping all mac da's */
static void mvpp2_prs_mac_drop_all_set(struct mvpp2 *priv, int port, bool add)
{
struct mvpp2_prs_entry pe;
if (priv->prs_shadow[MVPP2_PE_DROP_ALL].valid) {
/* Entry exist - update port only */
pe.index = MVPP2_PE_DROP_ALL;
mvpp2_prs_hw_read(priv, &pe);
} else {
/* Entry doesn't exist - create new */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_MAC);
pe.index = MVPP2_PE_DROP_ALL;
/* Non-promiscuous mode for all ports - DROP unknown packets */
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_DROP_MASK,
MVPP2_PRS_RI_DROP_MASK);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
/* Update shadow table */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_MAC);
/* Mask all ports */
mvpp2_prs_tcam_port_map_set(&pe, 0);
}
/* Update port mask */
mvpp2_prs_tcam_port_set(&pe, port, add);
mvpp2_prs_hw_write(priv, &pe);
}
/* Set port to promiscuous mode */
static void mvpp2_prs_mac_promisc_set(struct mvpp2 *priv, int port, bool add)
{
struct mvpp2_prs_entry pe;
/* Promiscuous mode - Accept unknown packets */
if (priv->prs_shadow[MVPP2_PE_MAC_PROMISCUOUS].valid) {
/* Entry exist - update port only */
pe.index = MVPP2_PE_MAC_PROMISCUOUS;
mvpp2_prs_hw_read(priv, &pe);
} else {
/* Entry doesn't exist - create new */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_MAC);
pe.index = MVPP2_PE_MAC_PROMISCUOUS;
/* Continue - set next lookup */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_DSA);
/* Set result info bits */
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L2_UCAST,
MVPP2_PRS_RI_L2_CAST_MASK);
/* Shift to ethertype */
mvpp2_prs_sram_shift_set(&pe, 2 * ETH_ALEN,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Mask all ports */
mvpp2_prs_tcam_port_map_set(&pe, 0);
/* Update shadow table */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_MAC);
}
/* Update port mask */
mvpp2_prs_tcam_port_set(&pe, port, add);
mvpp2_prs_hw_write(priv, &pe);
}
/* Accept multicast */
static void mvpp2_prs_mac_multi_set(struct mvpp2 *priv, int port, int index,
bool add)
{
struct mvpp2_prs_entry pe;
unsigned char da_mc;
/* Ethernet multicast address first byte is
* 0x01 for IPv4 and 0x33 for IPv6
*/
da_mc = (index == MVPP2_PE_MAC_MC_ALL) ? 0x01 : 0x33;
if (priv->prs_shadow[index].valid) {
/* Entry exist - update port only */
pe.index = index;
mvpp2_prs_hw_read(priv, &pe);
} else {
/* Entry doesn't exist - create new */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_MAC);
pe.index = index;
/* Continue - set next lookup */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_DSA);
/* Set result info bits */
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L2_MCAST,
MVPP2_PRS_RI_L2_CAST_MASK);
/* Update tcam entry data first byte */
mvpp2_prs_tcam_data_byte_set(&pe, 0, da_mc, 0xff);
/* Shift to ethertype */
mvpp2_prs_sram_shift_set(&pe, 2 * ETH_ALEN,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Mask all ports */
mvpp2_prs_tcam_port_map_set(&pe, 0);
/* Update shadow table */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_MAC);
}
/* Update port mask */
mvpp2_prs_tcam_port_set(&pe, port, add);
mvpp2_prs_hw_write(priv, &pe);
}
/* Set entry for dsa packets */
static void mvpp2_prs_dsa_tag_set(struct mvpp2 *priv, int port, bool add,
bool tagged, bool extend)
{
struct mvpp2_prs_entry pe;
int tid, shift;
if (extend) {
tid = tagged ? MVPP2_PE_EDSA_TAGGED : MVPP2_PE_EDSA_UNTAGGED;
shift = 8;
} else {
tid = tagged ? MVPP2_PE_DSA_TAGGED : MVPP2_PE_DSA_UNTAGGED;
shift = 4;
}
if (priv->prs_shadow[tid].valid) {
/* Entry exist - update port only */
pe.index = tid;
mvpp2_prs_hw_read(priv, &pe);
} else {
/* Entry doesn't exist - create new */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_DSA);
pe.index = tid;
/* Shift 4 bytes if DSA tag or 8 bytes in case of EDSA tag*/
mvpp2_prs_sram_shift_set(&pe, shift,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Update shadow table */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_DSA);
if (tagged) {
/* Set tagged bit in DSA tag */
mvpp2_prs_tcam_data_byte_set(&pe, 0,
MVPP2_PRS_TCAM_DSA_TAGGED_BIT,
MVPP2_PRS_TCAM_DSA_TAGGED_BIT);
/* Clear all ai bits for next iteration */
mvpp2_prs_sram_ai_update(&pe, 0,
MVPP2_PRS_SRAM_AI_MASK);
/* If packet is tagged continue check vlans */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_VLAN);
} else {
/* Set result info bits to 'no vlans' */
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_VLAN_NONE,
MVPP2_PRS_RI_VLAN_MASK);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_L2);
}
/* Mask all ports */
mvpp2_prs_tcam_port_map_set(&pe, 0);
}
/* Update port mask */
mvpp2_prs_tcam_port_set(&pe, port, add);
mvpp2_prs_hw_write(priv, &pe);
}
/* Set entry for dsa ethertype */
static void mvpp2_prs_dsa_tag_ethertype_set(struct mvpp2 *priv, int port,
bool add, bool tagged, bool extend)
{
struct mvpp2_prs_entry pe;
int tid, shift, port_mask;
if (extend) {
tid = tagged ? MVPP2_PE_ETYPE_EDSA_TAGGED :
MVPP2_PE_ETYPE_EDSA_UNTAGGED;
port_mask = 0;
shift = 8;
} else {
tid = tagged ? MVPP2_PE_ETYPE_DSA_TAGGED :
MVPP2_PE_ETYPE_DSA_UNTAGGED;
port_mask = MVPP2_PRS_PORT_MASK;
shift = 4;
}
if (priv->prs_shadow[tid].valid) {
/* Entry exist - update port only */
pe.index = tid;
mvpp2_prs_hw_read(priv, &pe);
} else {
/* Entry doesn't exist - create new */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_DSA);
pe.index = tid;
/* Set ethertype */
mvpp2_prs_match_etype(&pe, 0, ETH_P_EDSA);
mvpp2_prs_match_etype(&pe, 2, 0);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_DSA_MASK,
MVPP2_PRS_RI_DSA_MASK);
/* Shift ethertype + 2 byte reserved + tag*/
mvpp2_prs_sram_shift_set(&pe, 2 + MVPP2_ETH_TYPE_LEN + shift,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Update shadow table */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_DSA);
if (tagged) {
/* Set tagged bit in DSA tag */
mvpp2_prs_tcam_data_byte_set(&pe,
MVPP2_ETH_TYPE_LEN + 2 + 3,
MVPP2_PRS_TCAM_DSA_TAGGED_BIT,
MVPP2_PRS_TCAM_DSA_TAGGED_BIT);
/* Clear all ai bits for next iteration */
mvpp2_prs_sram_ai_update(&pe, 0,
MVPP2_PRS_SRAM_AI_MASK);
/* If packet is tagged continue check vlans */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_VLAN);
} else {
/* Set result info bits to 'no vlans' */
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_VLAN_NONE,
MVPP2_PRS_RI_VLAN_MASK);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_L2);
}
/* Mask/unmask all ports, depending on dsa type */
mvpp2_prs_tcam_port_map_set(&pe, port_mask);
}
/* Update port mask */
mvpp2_prs_tcam_port_set(&pe, port, add);
mvpp2_prs_hw_write(priv, &pe);
}
/* Search for existing single/triple vlan entry */
static struct mvpp2_prs_entry *mvpp2_prs_vlan_find(struct mvpp2 *priv,
unsigned short tpid, int ai)
{
struct mvpp2_prs_entry *pe;
int tid;
pe = kzalloc(sizeof(*pe), GFP_KERNEL);
if (!pe)
return NULL;
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_VLAN);
/* Go through the all entries with MVPP2_PRS_LU_VLAN */
for (tid = MVPP2_PE_FIRST_FREE_TID;
tid <= MVPP2_PE_LAST_FREE_TID; tid++) {
unsigned int ri_bits, ai_bits;
bool match;
if (!priv->prs_shadow[tid].valid ||
priv->prs_shadow[tid].lu != MVPP2_PRS_LU_VLAN)
continue;
pe->index = tid;
mvpp2_prs_hw_read(priv, pe);
match = mvpp2_prs_tcam_data_cmp(pe, 0, swab16(tpid));
if (!match)
continue;
/* Get vlan type */
ri_bits = mvpp2_prs_sram_ri_get(pe);
ri_bits &= MVPP2_PRS_RI_VLAN_MASK;
/* Get current ai value from tcam */
ai_bits = mvpp2_prs_tcam_ai_get(pe);
/* Clear double vlan bit */
ai_bits &= ~MVPP2_PRS_DBL_VLAN_AI_BIT;
if (ai != ai_bits)
continue;
if (ri_bits == MVPP2_PRS_RI_VLAN_SINGLE ||
ri_bits == MVPP2_PRS_RI_VLAN_TRIPLE)
return pe;
}
kfree(pe);
return NULL;
}
/* Add/update single/triple vlan entry */
static int mvpp2_prs_vlan_add(struct mvpp2 *priv, unsigned short tpid, int ai,
unsigned int port_map)
{
struct mvpp2_prs_entry *pe;
int tid_aux, tid;
int ret = 0;
pe = mvpp2_prs_vlan_find(priv, tpid, ai);
if (!pe) {
/* Create new tcam entry */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_LAST_FREE_TID,
MVPP2_PE_FIRST_FREE_TID);
if (tid < 0)
return tid;
pe = kzalloc(sizeof(*pe), GFP_KERNEL);
if (!pe)
return -ENOMEM;
/* Get last double vlan tid */
for (tid_aux = MVPP2_PE_LAST_FREE_TID;
tid_aux >= MVPP2_PE_FIRST_FREE_TID; tid_aux--) {
unsigned int ri_bits;
if (!priv->prs_shadow[tid_aux].valid ||
priv->prs_shadow[tid_aux].lu != MVPP2_PRS_LU_VLAN)
continue;
pe->index = tid_aux;
mvpp2_prs_hw_read(priv, pe);
ri_bits = mvpp2_prs_sram_ri_get(pe);
if ((ri_bits & MVPP2_PRS_RI_VLAN_MASK) ==
MVPP2_PRS_RI_VLAN_DOUBLE)
break;
}
if (tid <= tid_aux) {
ret = -EINVAL;
goto free_pe;
}
memset(pe, 0, sizeof(*pe));
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_VLAN);
pe->index = tid;
mvpp2_prs_match_etype(pe, 0, tpid);
mvpp2_prs_sram_next_lu_set(pe, MVPP2_PRS_LU_L2);
/* Shift 4 bytes - skip 1 vlan tag */
mvpp2_prs_sram_shift_set(pe, MVPP2_VLAN_TAG_LEN,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Clear all ai bits for next iteration */
mvpp2_prs_sram_ai_update(pe, 0, MVPP2_PRS_SRAM_AI_MASK);
if (ai == MVPP2_PRS_SINGLE_VLAN_AI) {
mvpp2_prs_sram_ri_update(pe, MVPP2_PRS_RI_VLAN_SINGLE,
MVPP2_PRS_RI_VLAN_MASK);
} else {
ai |= MVPP2_PRS_DBL_VLAN_AI_BIT;
mvpp2_prs_sram_ri_update(pe, MVPP2_PRS_RI_VLAN_TRIPLE,
MVPP2_PRS_RI_VLAN_MASK);
}
mvpp2_prs_tcam_ai_update(pe, ai, MVPP2_PRS_SRAM_AI_MASK);
mvpp2_prs_shadow_set(priv, pe->index, MVPP2_PRS_LU_VLAN);
}
/* Update ports' mask */
mvpp2_prs_tcam_port_map_set(pe, port_map);
mvpp2_prs_hw_write(priv, pe);
free_pe:
kfree(pe);
return ret;
}
/* Get first free double vlan ai number */
static int mvpp2_prs_double_vlan_ai_free_get(struct mvpp2 *priv)
{
int i;
for (i = 1; i < MVPP2_PRS_DBL_VLANS_MAX; i++) {
if (!priv->prs_double_vlans[i])
return i;
}
return -EINVAL;
}
/* Search for existing double vlan entry */
static struct mvpp2_prs_entry *mvpp2_prs_double_vlan_find(struct mvpp2 *priv,
unsigned short tpid1,
unsigned short tpid2)
{
struct mvpp2_prs_entry *pe;
int tid;
pe = kzalloc(sizeof(*pe), GFP_KERNEL);
if (!pe)
return NULL;
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_VLAN);
/* Go through the all entries with MVPP2_PRS_LU_VLAN */
for (tid = MVPP2_PE_FIRST_FREE_TID;
tid <= MVPP2_PE_LAST_FREE_TID; tid++) {
unsigned int ri_mask;
bool match;
if (!priv->prs_shadow[tid].valid ||
priv->prs_shadow[tid].lu != MVPP2_PRS_LU_VLAN)
continue;
pe->index = tid;
mvpp2_prs_hw_read(priv, pe);
match = mvpp2_prs_tcam_data_cmp(pe, 0, swab16(tpid1))
&& mvpp2_prs_tcam_data_cmp(pe, 4, swab16(tpid2));
if (!match)
continue;
ri_mask = mvpp2_prs_sram_ri_get(pe) & MVPP2_PRS_RI_VLAN_MASK;
if (ri_mask == MVPP2_PRS_RI_VLAN_DOUBLE)
return pe;
}
kfree(pe);
return NULL;
}
/* Add or update double vlan entry */
static int mvpp2_prs_double_vlan_add(struct mvpp2 *priv, unsigned short tpid1,
unsigned short tpid2,
unsigned int port_map)
{
struct mvpp2_prs_entry *pe;
int tid_aux, tid, ai, ret = 0;
pe = mvpp2_prs_double_vlan_find(priv, tpid1, tpid2);
if (!pe) {
/* Create new tcam entry */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
pe = kzalloc(sizeof(*pe), GFP_KERNEL);
if (!pe)
return -ENOMEM;
/* Set ai value for new double vlan entry */
ai = mvpp2_prs_double_vlan_ai_free_get(priv);
if (ai < 0) {
ret = ai;
goto free_pe;
}
/* Get first single/triple vlan tid */
for (tid_aux = MVPP2_PE_FIRST_FREE_TID;
tid_aux <= MVPP2_PE_LAST_FREE_TID; tid_aux++) {
unsigned int ri_bits;
if (!priv->prs_shadow[tid_aux].valid ||
priv->prs_shadow[tid_aux].lu != MVPP2_PRS_LU_VLAN)
continue;
pe->index = tid_aux;
mvpp2_prs_hw_read(priv, pe);
ri_bits = mvpp2_prs_sram_ri_get(pe);
ri_bits &= MVPP2_PRS_RI_VLAN_MASK;
if (ri_bits == MVPP2_PRS_RI_VLAN_SINGLE ||
ri_bits == MVPP2_PRS_RI_VLAN_TRIPLE)
break;
}
if (tid >= tid_aux) {
ret = -ERANGE;
goto free_pe;
}
memset(pe, 0, sizeof(*pe));
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_VLAN);
pe->index = tid;
priv->prs_double_vlans[ai] = true;
mvpp2_prs_match_etype(pe, 0, tpid1);
mvpp2_prs_match_etype(pe, 4, tpid2);
mvpp2_prs_sram_next_lu_set(pe, MVPP2_PRS_LU_VLAN);
/* Shift 8 bytes - skip 2 vlan tags */
mvpp2_prs_sram_shift_set(pe, 2 * MVPP2_VLAN_TAG_LEN,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_sram_ri_update(pe, MVPP2_PRS_RI_VLAN_DOUBLE,
MVPP2_PRS_RI_VLAN_MASK);
mvpp2_prs_sram_ai_update(pe, ai | MVPP2_PRS_DBL_VLAN_AI_BIT,
MVPP2_PRS_SRAM_AI_MASK);
mvpp2_prs_shadow_set(priv, pe->index, MVPP2_PRS_LU_VLAN);
}
/* Update ports' mask */
mvpp2_prs_tcam_port_map_set(pe, port_map);
mvpp2_prs_hw_write(priv, pe);
free_pe:
kfree(pe);
return ret;
}
/* IPv4 header parsing for fragmentation and L4 offset */
static int mvpp2_prs_ip4_proto(struct mvpp2 *priv, unsigned short proto,
unsigned int ri, unsigned int ri_mask)
{
struct mvpp2_prs_entry pe;
int tid;
if ((proto != IPPROTO_TCP) && (proto != IPPROTO_UDP) &&
(proto != IPPROTO_IGMP))
return -EINVAL;
/* Not fragmented packet */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP4);
pe.index = tid;
/* Set next lu to IPv4 */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP4);
mvpp2_prs_sram_shift_set(&pe, 12, MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Set L4 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L4,
sizeof(struct iphdr) - 4,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
mvpp2_prs_sram_ai_update(&pe, MVPP2_PRS_IPV4_DIP_AI_BIT,
MVPP2_PRS_IPV4_DIP_AI_BIT);
mvpp2_prs_sram_ri_update(&pe, ri, ri_mask | MVPP2_PRS_RI_IP_FRAG_MASK);
mvpp2_prs_tcam_data_byte_set(&pe, 2, 0x00,
MVPP2_PRS_TCAM_PROTO_MASK_L);
mvpp2_prs_tcam_data_byte_set(&pe, 3, 0x00,
MVPP2_PRS_TCAM_PROTO_MASK);
mvpp2_prs_tcam_data_byte_set(&pe, 5, proto, MVPP2_PRS_TCAM_PROTO_MASK);
mvpp2_prs_tcam_ai_update(&pe, 0, MVPP2_PRS_IPV4_DIP_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
/* Fragmented packet */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
pe.index = tid;
/* Clear ri before updating */
pe.sram.word[MVPP2_PRS_SRAM_RI_WORD] = 0x0;
pe.sram.word[MVPP2_PRS_SRAM_RI_CTRL_WORD] = 0x0;
mvpp2_prs_sram_ri_update(&pe, ri, ri_mask);
mvpp2_prs_sram_ri_update(&pe, ri | MVPP2_PRS_RI_IP_FRAG_TRUE,
ri_mask | MVPP2_PRS_RI_IP_FRAG_MASK);
mvpp2_prs_tcam_data_byte_set(&pe, 2, 0x00, 0x0);
mvpp2_prs_tcam_data_byte_set(&pe, 3, 0x00, 0x0);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* IPv4 L3 multicast or broadcast */
static int mvpp2_prs_ip4_cast(struct mvpp2 *priv, unsigned short l3_cast)
{
struct mvpp2_prs_entry pe;
int mask, tid;
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP4);
pe.index = tid;
switch (l3_cast) {
case MVPP2_PRS_L3_MULTI_CAST:
mvpp2_prs_tcam_data_byte_set(&pe, 0, MVPP2_PRS_IPV4_MC,
MVPP2_PRS_IPV4_MC_MASK);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_MCAST,
MVPP2_PRS_RI_L3_ADDR_MASK);
break;
case MVPP2_PRS_L3_BROAD_CAST:
mask = MVPP2_PRS_IPV4_BC_MASK;
mvpp2_prs_tcam_data_byte_set(&pe, 0, mask, mask);
mvpp2_prs_tcam_data_byte_set(&pe, 1, mask, mask);
mvpp2_prs_tcam_data_byte_set(&pe, 2, mask, mask);
mvpp2_prs_tcam_data_byte_set(&pe, 3, mask, mask);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_BCAST,
MVPP2_PRS_RI_L3_ADDR_MASK);
break;
default:
return -EINVAL;
}
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_IPV4_DIP_AI_BIT,
MVPP2_PRS_IPV4_DIP_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Set entries for protocols over IPv6 */
static int mvpp2_prs_ip6_proto(struct mvpp2 *priv, unsigned short proto,
unsigned int ri, unsigned int ri_mask)
{
struct mvpp2_prs_entry pe;
int tid;
if ((proto != IPPROTO_TCP) && (proto != IPPROTO_UDP) &&
(proto != IPPROTO_ICMPV6) && (proto != IPPROTO_IPIP))
return -EINVAL;
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP6);
pe.index = tid;
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, ri, ri_mask);
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L4,
sizeof(struct ipv6hdr) - 6,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
mvpp2_prs_tcam_data_byte_set(&pe, 0, proto, MVPP2_PRS_TCAM_PROTO_MASK);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_IPV6_NO_EXT_AI_BIT,
MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Write HW */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP6);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* IPv6 L3 multicast entry */
static int mvpp2_prs_ip6_cast(struct mvpp2 *priv, unsigned short l3_cast)
{
struct mvpp2_prs_entry pe;
int tid;
if (l3_cast != MVPP2_PRS_L3_MULTI_CAST)
return -EINVAL;
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP6);
pe.index = tid;
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP6);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_MCAST,
MVPP2_PRS_RI_L3_ADDR_MASK);
mvpp2_prs_sram_ai_update(&pe, MVPP2_PRS_IPV6_NO_EXT_AI_BIT,
MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Shift back to IPv6 NH */
mvpp2_prs_sram_shift_set(&pe, -18, MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_tcam_data_byte_set(&pe, 0, MVPP2_PRS_IPV6_MC,
MVPP2_PRS_IPV6_MC_MASK);
mvpp2_prs_tcam_ai_update(&pe, 0, MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP6);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Parser per-port initialization */
static void mvpp2_prs_hw_port_init(struct mvpp2 *priv, int port, int lu_first,
int lu_max, int offset)
{
u32 val;
/* Set lookup ID */
val = mvpp2_read(priv, MVPP2_PRS_INIT_LOOKUP_REG);
val &= ~MVPP2_PRS_PORT_LU_MASK(port);
val |= MVPP2_PRS_PORT_LU_VAL(port, lu_first);
mvpp2_write(priv, MVPP2_PRS_INIT_LOOKUP_REG, val);
/* Set maximum number of loops for packet received from port */
val = mvpp2_read(priv, MVPP2_PRS_MAX_LOOP_REG(port));
val &= ~MVPP2_PRS_MAX_LOOP_MASK(port);
val |= MVPP2_PRS_MAX_LOOP_VAL(port, lu_max);
mvpp2_write(priv, MVPP2_PRS_MAX_LOOP_REG(port), val);
/* Set initial offset for packet header extraction for the first
* searching loop
*/
val = mvpp2_read(priv, MVPP2_PRS_INIT_OFFS_REG(port));
val &= ~MVPP2_PRS_INIT_OFF_MASK(port);
val |= MVPP2_PRS_INIT_OFF_VAL(port, offset);
mvpp2_write(priv, MVPP2_PRS_INIT_OFFS_REG(port), val);
}
/* Default flow entries initialization for all ports */
static void mvpp2_prs_def_flow_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
int port;
for (port = 0; port < MVPP2_MAX_PORTS; port++) {
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
pe.index = MVPP2_PE_FIRST_DEFAULT_FLOW - port;
/* Mask all ports */
mvpp2_prs_tcam_port_map_set(&pe, 0);
/* Set flow ID*/
mvpp2_prs_sram_ai_update(&pe, port, MVPP2_PRS_FLOW_ID_MASK);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_DONE_BIT, 1);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_hw_write(priv, &pe);
}
}
/* Set default entry for Marvell Header field */
static void mvpp2_prs_mh_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
memset(&pe, 0, sizeof(pe));
pe.index = MVPP2_PE_MH_DEFAULT;
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_MH);
mvpp2_prs_sram_shift_set(&pe, MVPP2_MH_SIZE,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_MAC);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_MH);
mvpp2_prs_hw_write(priv, &pe);
}
/* Set default entires (place holder) for promiscuous, non-promiscuous and
* multicast MAC addresses
*/
static void mvpp2_prs_mac_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
memset(&pe, 0, sizeof(pe));
/* Non-promiscuous mode for all ports - DROP unknown packets */
pe.index = MVPP2_PE_MAC_NON_PROMISCUOUS;
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_MAC);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_DROP_MASK,
MVPP2_PRS_RI_DROP_MASK);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_MAC);
mvpp2_prs_hw_write(priv, &pe);
/* place holders only - no ports */
mvpp2_prs_mac_drop_all_set(priv, 0, false);
mvpp2_prs_mac_promisc_set(priv, 0, false);
mvpp2_prs_mac_multi_set(priv, 0, MVPP2_PE_MAC_MC_ALL, false);
mvpp2_prs_mac_multi_set(priv, 0, MVPP2_PE_MAC_MC_IP6, false);
}
/* Set default entries for various types of dsa packets */
static void mvpp2_prs_dsa_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
/* None tagged EDSA entry - place holder */
mvpp2_prs_dsa_tag_set(priv, 0, false, MVPP2_PRS_UNTAGGED,
MVPP2_PRS_EDSA);
/* Tagged EDSA entry - place holder */
mvpp2_prs_dsa_tag_set(priv, 0, false, MVPP2_PRS_TAGGED, MVPP2_PRS_EDSA);
/* None tagged DSA entry - place holder */
mvpp2_prs_dsa_tag_set(priv, 0, false, MVPP2_PRS_UNTAGGED,
MVPP2_PRS_DSA);
/* Tagged DSA entry - place holder */
mvpp2_prs_dsa_tag_set(priv, 0, false, MVPP2_PRS_TAGGED, MVPP2_PRS_DSA);
/* None tagged EDSA ethertype entry - place holder*/
mvpp2_prs_dsa_tag_ethertype_set(priv, 0, false,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_EDSA);
/* Tagged EDSA ethertype entry - place holder*/
mvpp2_prs_dsa_tag_ethertype_set(priv, 0, false,
MVPP2_PRS_TAGGED, MVPP2_PRS_EDSA);
/* None tagged DSA ethertype entry */
mvpp2_prs_dsa_tag_ethertype_set(priv, 0, true,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_DSA);
/* Tagged DSA ethertype entry */
mvpp2_prs_dsa_tag_ethertype_set(priv, 0, true,
MVPP2_PRS_TAGGED, MVPP2_PRS_DSA);
/* Set default entry, in case DSA or EDSA tag not found */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_DSA);
pe.index = MVPP2_PE_DSA_DEFAULT;
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_VLAN);
/* Shift 0 bytes */
mvpp2_prs_sram_shift_set(&pe, 0, MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_MAC);
/* Clear all sram ai bits for next iteration */
mvpp2_prs_sram_ai_update(&pe, 0, MVPP2_PRS_SRAM_AI_MASK);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
mvpp2_prs_hw_write(priv, &pe);
}
/* Match basic ethertypes */
static int mvpp2_prs_etype_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
int tid;
/* Ethertype: PPPoE */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_L2);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, ETH_P_PPP_SES);
mvpp2_prs_sram_shift_set(&pe, MVPP2_PPPOE_HDR_SIZE,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_PPPOE);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_PPPOE_MASK,
MVPP2_PRS_RI_PPPOE_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = false;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_PPPOE_MASK,
MVPP2_PRS_RI_PPPOE_MASK);
mvpp2_prs_hw_write(priv, &pe);
/* Ethertype: ARP */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_L2);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, ETH_P_ARP);
/* Generate flow in the next iteration*/
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_ARP,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Set L3 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = true;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_L3_ARP,
MVPP2_PRS_RI_L3_PROTO_MASK);
mvpp2_prs_hw_write(priv, &pe);
/* Ethertype: LBTD */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_L2);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, MVPP2_IP_LBDT_TYPE);
/* Generate flow in the next iteration*/
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_CPU_CODE_RX_SPEC |
MVPP2_PRS_RI_UDF3_RX_SPECIAL,
MVPP2_PRS_RI_CPU_CODE_MASK |
MVPP2_PRS_RI_UDF3_MASK);
/* Set L3 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = true;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_CPU_CODE_RX_SPEC |
MVPP2_PRS_RI_UDF3_RX_SPECIAL,
MVPP2_PRS_RI_CPU_CODE_MASK |
MVPP2_PRS_RI_UDF3_MASK);
mvpp2_prs_hw_write(priv, &pe);
/* Ethertype: IPv4 without options */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_L2);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, ETH_P_IP);
mvpp2_prs_tcam_data_byte_set(&pe, MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_IPV4_HEAD | MVPP2_PRS_IPV4_IHL,
MVPP2_PRS_IPV4_HEAD_MASK |
MVPP2_PRS_IPV4_IHL_MASK);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP4);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_IP4,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Skip eth_type + 4 bytes of IP header */
mvpp2_prs_sram_shift_set(&pe, MVPP2_ETH_TYPE_LEN + 4,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Set L3 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = false;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_L3_IP4,
MVPP2_PRS_RI_L3_PROTO_MASK);
mvpp2_prs_hw_write(priv, &pe);
/* Ethertype: IPv4 with options */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
pe.index = tid;
/* Clear tcam data before updating */
pe.tcam.byte[MVPP2_PRS_TCAM_DATA_BYTE(MVPP2_ETH_TYPE_LEN)] = 0x0;
pe.tcam.byte[MVPP2_PRS_TCAM_DATA_BYTE_EN(MVPP2_ETH_TYPE_LEN)] = 0x0;
mvpp2_prs_tcam_data_byte_set(&pe, MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_IPV4_HEAD,
MVPP2_PRS_IPV4_HEAD_MASK);
/* Clear ri before updating */
pe.sram.word[MVPP2_PRS_SRAM_RI_WORD] = 0x0;
pe.sram.word[MVPP2_PRS_SRAM_RI_CTRL_WORD] = 0x0;
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_IP4_OPT,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = false;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_L3_IP4_OPT,
MVPP2_PRS_RI_L3_PROTO_MASK);
mvpp2_prs_hw_write(priv, &pe);
/* Ethertype: IPv6 without options */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_L2);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, ETH_P_IPV6);
/* Skip DIP of IPV6 header */
mvpp2_prs_sram_shift_set(&pe, MVPP2_ETH_TYPE_LEN + 8 +
MVPP2_MAX_L3_ADDR_SIZE,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP6);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_IP6,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Set L3 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = false;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_L3_IP6,
MVPP2_PRS_RI_L3_PROTO_MASK);
mvpp2_prs_hw_write(priv, &pe);
/* Default entry for MVPP2_PRS_LU_L2 - Unknown ethtype */
memset(&pe, 0, sizeof(struct mvpp2_prs_entry));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_L2);
pe.index = MVPP2_PE_ETH_TYPE_UN;
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Generate flow in the next iteration*/
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_UN,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Set L3 offset even it's unknown L3 */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_L2);
priv->prs_shadow[pe.index].udf = MVPP2_PRS_UDF_L2_DEF;
priv->prs_shadow[pe.index].finish = true;
mvpp2_prs_shadow_ri_set(priv, pe.index, MVPP2_PRS_RI_L3_UN,
MVPP2_PRS_RI_L3_PROTO_MASK);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Configure vlan entries and detect up to 2 successive VLAN tags.
* Possible options:
* 0x8100, 0x88A8
* 0x8100, 0x8100
* 0x8100
* 0x88A8
*/
static int mvpp2_prs_vlan_init(struct platform_device *pdev, struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
int err;
priv->prs_double_vlans = devm_kcalloc(&pdev->dev, sizeof(bool),
MVPP2_PRS_DBL_VLANS_MAX,
GFP_KERNEL);
if (!priv->prs_double_vlans)
return -ENOMEM;
/* Double VLAN: 0x8100, 0x88A8 */
err = mvpp2_prs_double_vlan_add(priv, ETH_P_8021Q, ETH_P_8021AD,
MVPP2_PRS_PORT_MASK);
if (err)
return err;
/* Double VLAN: 0x8100, 0x8100 */
err = mvpp2_prs_double_vlan_add(priv, ETH_P_8021Q, ETH_P_8021Q,
MVPP2_PRS_PORT_MASK);
if (err)
return err;
/* Single VLAN: 0x88a8 */
err = mvpp2_prs_vlan_add(priv, ETH_P_8021AD, MVPP2_PRS_SINGLE_VLAN_AI,
MVPP2_PRS_PORT_MASK);
if (err)
return err;
/* Single VLAN: 0x8100 */
err = mvpp2_prs_vlan_add(priv, ETH_P_8021Q, MVPP2_PRS_SINGLE_VLAN_AI,
MVPP2_PRS_PORT_MASK);
if (err)
return err;
/* Set default double vlan entry */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_VLAN);
pe.index = MVPP2_PE_VLAN_DBL;
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_L2);
/* Clear ai for next iterations */
mvpp2_prs_sram_ai_update(&pe, 0, MVPP2_PRS_SRAM_AI_MASK);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_VLAN_DOUBLE,
MVPP2_PRS_RI_VLAN_MASK);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_DBL_VLAN_AI_BIT,
MVPP2_PRS_DBL_VLAN_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_VLAN);
mvpp2_prs_hw_write(priv, &pe);
/* Set default vlan none entry */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_VLAN);
pe.index = MVPP2_PE_VLAN_NONE;
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_L2);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_VLAN_NONE,
MVPP2_PRS_RI_VLAN_MASK);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_VLAN);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Set entries for PPPoE ethertype */
static int mvpp2_prs_pppoe_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
int tid;
/* IPv4 over PPPoE with options */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_PPPOE);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, PPP_IP);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP4);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_IP4_OPT,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Skip eth_type + 4 bytes of IP header */
mvpp2_prs_sram_shift_set(&pe, MVPP2_ETH_TYPE_LEN + 4,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Set L3 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_PPPOE);
mvpp2_prs_hw_write(priv, &pe);
/* IPv4 over PPPoE without options */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
pe.index = tid;
mvpp2_prs_tcam_data_byte_set(&pe, MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_IPV4_HEAD | MVPP2_PRS_IPV4_IHL,
MVPP2_PRS_IPV4_HEAD_MASK |
MVPP2_PRS_IPV4_IHL_MASK);
/* Clear ri before updating */
pe.sram.word[MVPP2_PRS_SRAM_RI_WORD] = 0x0;
pe.sram.word[MVPP2_PRS_SRAM_RI_CTRL_WORD] = 0x0;
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_IP4,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_PPPOE);
mvpp2_prs_hw_write(priv, &pe);
/* IPv6 over PPPoE */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_PPPOE);
pe.index = tid;
mvpp2_prs_match_etype(&pe, 0, PPP_IPV6);
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP6);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_IP6,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Skip eth_type + 4 bytes of IPv6 header */
mvpp2_prs_sram_shift_set(&pe, MVPP2_ETH_TYPE_LEN + 4,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Set L3 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_PPPOE);
mvpp2_prs_hw_write(priv, &pe);
/* Non-IP over PPPoE */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_PPPOE);
pe.index = tid;
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_UN,
MVPP2_PRS_RI_L3_PROTO_MASK);
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
/* Set L3 offset even if it's unknown L3 */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L3,
MVPP2_ETH_TYPE_LEN,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_PPPOE);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Initialize entries for IPv4 */
static int mvpp2_prs_ip4_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
int err;
/* Set entries for TCP, UDP and IGMP over IPv4 */
err = mvpp2_prs_ip4_proto(priv, IPPROTO_TCP, MVPP2_PRS_RI_L4_TCP,
MVPP2_PRS_RI_L4_PROTO_MASK);
if (err)
return err;
err = mvpp2_prs_ip4_proto(priv, IPPROTO_UDP, MVPP2_PRS_RI_L4_UDP,
MVPP2_PRS_RI_L4_PROTO_MASK);
if (err)
return err;
err = mvpp2_prs_ip4_proto(priv, IPPROTO_IGMP,
MVPP2_PRS_RI_CPU_CODE_RX_SPEC |
MVPP2_PRS_RI_UDF3_RX_SPECIAL,
MVPP2_PRS_RI_CPU_CODE_MASK |
MVPP2_PRS_RI_UDF3_MASK);
if (err)
return err;
/* IPv4 Broadcast */
err = mvpp2_prs_ip4_cast(priv, MVPP2_PRS_L3_BROAD_CAST);
if (err)
return err;
/* IPv4 Multicast */
err = mvpp2_prs_ip4_cast(priv, MVPP2_PRS_L3_MULTI_CAST);
if (err)
return err;
/* Default IPv4 entry for unknown protocols */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP4);
pe.index = MVPP2_PE_IP4_PROTO_UN;
/* Set next lu to IPv4 */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP4);
mvpp2_prs_sram_shift_set(&pe, 12, MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Set L4 offset */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L4,
sizeof(struct iphdr) - 4,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
mvpp2_prs_sram_ai_update(&pe, MVPP2_PRS_IPV4_DIP_AI_BIT,
MVPP2_PRS_IPV4_DIP_AI_BIT);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L4_OTHER,
MVPP2_PRS_RI_L4_PROTO_MASK);
mvpp2_prs_tcam_ai_update(&pe, 0, MVPP2_PRS_IPV4_DIP_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
/* Default IPv4 entry for unicast address */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP4);
pe.index = MVPP2_PE_IP4_ADDR_UN;
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_UCAST,
MVPP2_PRS_RI_L3_ADDR_MASK);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_IPV4_DIP_AI_BIT,
MVPP2_PRS_IPV4_DIP_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Initialize entries for IPv6 */
static int mvpp2_prs_ip6_init(struct mvpp2 *priv)
{
struct mvpp2_prs_entry pe;
int tid, err;
/* Set entries for TCP, UDP and ICMP over IPv6 */
err = mvpp2_prs_ip6_proto(priv, IPPROTO_TCP,
MVPP2_PRS_RI_L4_TCP,
MVPP2_PRS_RI_L4_PROTO_MASK);
if (err)
return err;
err = mvpp2_prs_ip6_proto(priv, IPPROTO_UDP,
MVPP2_PRS_RI_L4_UDP,
MVPP2_PRS_RI_L4_PROTO_MASK);
if (err)
return err;
err = mvpp2_prs_ip6_proto(priv, IPPROTO_ICMPV6,
MVPP2_PRS_RI_CPU_CODE_RX_SPEC |
MVPP2_PRS_RI_UDF3_RX_SPECIAL,
MVPP2_PRS_RI_CPU_CODE_MASK |
MVPP2_PRS_RI_UDF3_MASK);
if (err)
return err;
/* IPv4 is the last header. This is similar case as 6-TCP or 17-UDP */
/* Result Info: UDF7=1, DS lite */
err = mvpp2_prs_ip6_proto(priv, IPPROTO_IPIP,
MVPP2_PRS_RI_UDF7_IP6_LITE,
MVPP2_PRS_RI_UDF7_MASK);
if (err)
return err;
/* IPv6 multicast */
err = mvpp2_prs_ip6_cast(priv, MVPP2_PRS_L3_MULTI_CAST);
if (err)
return err;
/* Entry for checking hop limit */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
MVPP2_PE_LAST_FREE_TID);
if (tid < 0)
return tid;
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP6);
pe.index = tid;
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_UN |
MVPP2_PRS_RI_DROP_MASK,
MVPP2_PRS_RI_L3_PROTO_MASK |
MVPP2_PRS_RI_DROP_MASK);
mvpp2_prs_tcam_data_byte_set(&pe, 1, 0x00, MVPP2_PRS_IPV6_HOP_MASK);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_IPV6_NO_EXT_AI_BIT,
MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
/* Default IPv6 entry for unknown protocols */
memset(&pe, 0, sizeof(pe));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP6);
pe.index = MVPP2_PE_IP6_PROTO_UN;
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L4_OTHER,
MVPP2_PRS_RI_L4_PROTO_MASK);
/* Set L4 offset relatively to our current place */
mvpp2_prs_sram_offset_set(&pe, MVPP2_PRS_SRAM_UDF_TYPE_L4,
sizeof(struct ipv6hdr) - 4,
MVPP2_PRS_SRAM_OP_SEL_UDF_ADD);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_IPV6_NO_EXT_AI_BIT,
MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
/* Default IPv6 entry for unknown ext protocols */
memset(&pe, 0, sizeof(struct mvpp2_prs_entry));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP6);
pe.index = MVPP2_PE_IP6_EXT_PROTO_UN;
/* Finished: go to flowid generation */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_FLOWS);
mvpp2_prs_sram_bits_set(&pe, MVPP2_PRS_SRAM_LU_GEN_BIT, 1);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L4_OTHER,
MVPP2_PRS_RI_L4_PROTO_MASK);
mvpp2_prs_tcam_ai_update(&pe, MVPP2_PRS_IPV6_EXT_AI_BIT,
MVPP2_PRS_IPV6_EXT_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP4);
mvpp2_prs_hw_write(priv, &pe);
/* Default IPv6 entry for unicast address */
memset(&pe, 0, sizeof(struct mvpp2_prs_entry));
mvpp2_prs_tcam_lu_set(&pe, MVPP2_PRS_LU_IP6);
pe.index = MVPP2_PE_IP6_ADDR_UN;
/* Finished: go to IPv6 again */
mvpp2_prs_sram_next_lu_set(&pe, MVPP2_PRS_LU_IP6);
mvpp2_prs_sram_ri_update(&pe, MVPP2_PRS_RI_L3_UCAST,
MVPP2_PRS_RI_L3_ADDR_MASK);
mvpp2_prs_sram_ai_update(&pe, MVPP2_PRS_IPV6_NO_EXT_AI_BIT,
MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Shift back to IPV6 NH */
mvpp2_prs_sram_shift_set(&pe, -18, MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
mvpp2_prs_tcam_ai_update(&pe, 0, MVPP2_PRS_IPV6_NO_EXT_AI_BIT);
/* Unmask all ports */
mvpp2_prs_tcam_port_map_set(&pe, MVPP2_PRS_PORT_MASK);
/* Update shadow table and hw entry */
mvpp2_prs_shadow_set(priv, pe.index, MVPP2_PRS_LU_IP6);
mvpp2_prs_hw_write(priv, &pe);
return 0;
}
/* Parser default initialization */
static int mvpp2_prs_default_init(struct platform_device *pdev,
struct mvpp2 *priv)
{
int err, index, i;
/* Enable tcam table */
mvpp2_write(priv, MVPP2_PRS_TCAM_CTRL_REG, MVPP2_PRS_TCAM_EN_MASK);
/* Clear all tcam and sram entries */
for (index = 0; index < MVPP2_PRS_TCAM_SRAM_SIZE; index++) {
mvpp2_write(priv, MVPP2_PRS_TCAM_IDX_REG, index);
for (i = 0; i < MVPP2_PRS_TCAM_WORDS; i++)
mvpp2_write(priv, MVPP2_PRS_TCAM_DATA_REG(i), 0);
mvpp2_write(priv, MVPP2_PRS_SRAM_IDX_REG, index);
for (i = 0; i < MVPP2_PRS_SRAM_WORDS; i++)
mvpp2_write(priv, MVPP2_PRS_SRAM_DATA_REG(i), 0);
}
/* Invalidate all tcam entries */
for (index = 0; index < MVPP2_PRS_TCAM_SRAM_SIZE; index++)
mvpp2_prs_hw_inv(priv, index);
priv->prs_shadow = devm_kcalloc(&pdev->dev, MVPP2_PRS_TCAM_SRAM_SIZE,
sizeof(*priv->prs_shadow),
GFP_KERNEL);
if (!priv->prs_shadow)
return -ENOMEM;
/* Always start from lookup = 0 */
for (index = 0; index < MVPP2_MAX_PORTS; index++)
mvpp2_prs_hw_port_init(priv, index, MVPP2_PRS_LU_MH,
MVPP2_PRS_PORT_LU_MAX, 0);
mvpp2_prs_def_flow_init(priv);
mvpp2_prs_mh_init(priv);
mvpp2_prs_mac_init(priv);
mvpp2_prs_dsa_init(priv);
err = mvpp2_prs_etype_init(priv);
if (err)
return err;
err = mvpp2_prs_vlan_init(pdev, priv);
if (err)
return err;
err = mvpp2_prs_pppoe_init(priv);
if (err)
return err;
err = mvpp2_prs_ip6_init(priv);
if (err)
return err;
err = mvpp2_prs_ip4_init(priv);
if (err)
return err;
return 0;
}
/* Compare MAC DA with tcam entry data */
static bool mvpp2_prs_mac_range_equals(struct mvpp2_prs_entry *pe,
const u8 *da, unsigned char *mask)
{
unsigned char tcam_byte, tcam_mask;
int index;
for (index = 0; index < ETH_ALEN; index++) {
mvpp2_prs_tcam_data_byte_get(pe, index, &tcam_byte, &tcam_mask);
if (tcam_mask != mask[index])
return false;
if ((tcam_mask & tcam_byte) != (da[index] & mask[index]))
return false;
}
return true;
}
/* Find tcam entry with matched pair <MAC DA, port> */
static struct mvpp2_prs_entry *
mvpp2_prs_mac_da_range_find(struct mvpp2 *priv, int pmap, const u8 *da,
unsigned char *mask, int udf_type)
{
struct mvpp2_prs_entry *pe;
int tid;
pe = kzalloc(sizeof(*pe), GFP_ATOMIC);
if (!pe)
return NULL;
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_MAC);
/* Go through the all entires with MVPP2_PRS_LU_MAC */
for (tid = MVPP2_PE_FIRST_FREE_TID;
tid <= MVPP2_PE_LAST_FREE_TID; tid++) {
unsigned int entry_pmap;
if (!priv->prs_shadow[tid].valid ||
(priv->prs_shadow[tid].lu != MVPP2_PRS_LU_MAC) ||
(priv->prs_shadow[tid].udf != udf_type))
continue;
pe->index = tid;
mvpp2_prs_hw_read(priv, pe);
entry_pmap = mvpp2_prs_tcam_port_map_get(pe);
if (mvpp2_prs_mac_range_equals(pe, da, mask) &&
entry_pmap == pmap)
return pe;
}
kfree(pe);
return NULL;
}
/* Update parser's mac da entry */
static int mvpp2_prs_mac_da_accept(struct mvpp2 *priv, int port,
const u8 *da, bool add)
{
struct mvpp2_prs_entry *pe;
unsigned int pmap, len, ri;
unsigned char mask[ETH_ALEN] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff };
int tid;
/* Scan TCAM and see if entry with this <MAC DA, port> already exist */
pe = mvpp2_prs_mac_da_range_find(priv, (1 << port), da, mask,
MVPP2_PRS_UDF_MAC_DEF);
/* No such entry */
if (!pe) {
if (!add)
return 0;
/* Create new TCAM entry */
/* Find first range mac entry*/
for (tid = MVPP2_PE_FIRST_FREE_TID;
tid <= MVPP2_PE_LAST_FREE_TID; tid++)
if (priv->prs_shadow[tid].valid &&
(priv->prs_shadow[tid].lu == MVPP2_PRS_LU_MAC) &&
(priv->prs_shadow[tid].udf ==
MVPP2_PRS_UDF_MAC_RANGE))
break;
/* Go through the all entries from first to last */
tid = mvpp2_prs_tcam_first_free(priv, MVPP2_PE_FIRST_FREE_TID,
tid - 1);
if (tid < 0)
return tid;
pe = kzalloc(sizeof(*pe), GFP_ATOMIC);
if (!pe)
return -ENOMEM;
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_MAC);
pe->index = tid;
/* Mask all ports */
mvpp2_prs_tcam_port_map_set(pe, 0);
}
/* Update port mask */
mvpp2_prs_tcam_port_set(pe, port, add);
/* Invalidate the entry if no ports are left enabled */
pmap = mvpp2_prs_tcam_port_map_get(pe);
if (pmap == 0) {
if (add) {
kfree(pe);
return -EINVAL;
}
mvpp2_prs_hw_inv(priv, pe->index);
priv->prs_shadow[pe->index].valid = false;
kfree(pe);
return 0;
}
/* Continue - set next lookup */
mvpp2_prs_sram_next_lu_set(pe, MVPP2_PRS_LU_DSA);
/* Set match on DA */
len = ETH_ALEN;
while (len--)
mvpp2_prs_tcam_data_byte_set(pe, len, da[len], 0xff);
/* Set result info bits */
if (is_broadcast_ether_addr(da))
ri = MVPP2_PRS_RI_L2_BCAST;
else if (is_multicast_ether_addr(da))
ri = MVPP2_PRS_RI_L2_MCAST;
else
ri = MVPP2_PRS_RI_L2_UCAST | MVPP2_PRS_RI_MAC_ME_MASK;
mvpp2_prs_sram_ri_update(pe, ri, MVPP2_PRS_RI_L2_CAST_MASK |
MVPP2_PRS_RI_MAC_ME_MASK);
mvpp2_prs_shadow_ri_set(priv, pe->index, ri, MVPP2_PRS_RI_L2_CAST_MASK |
MVPP2_PRS_RI_MAC_ME_MASK);
/* Shift to ethertype */
mvpp2_prs_sram_shift_set(pe, 2 * ETH_ALEN,
MVPP2_PRS_SRAM_OP_SEL_SHIFT_ADD);
/* Update shadow table and hw entry */
priv->prs_shadow[pe->index].udf = MVPP2_PRS_UDF_MAC_DEF;
mvpp2_prs_shadow_set(priv, pe->index, MVPP2_PRS_LU_MAC);
mvpp2_prs_hw_write(priv, pe);
kfree(pe);
return 0;
}
static int mvpp2_prs_update_mac_da(struct net_device *dev, const u8 *da)
{
struct mvpp2_port *port = netdev_priv(dev);
int err;
/* Remove old parser entry */
err = mvpp2_prs_mac_da_accept(port->priv, port->id, dev->dev_addr,
false);
if (err)
return err;
/* Add new parser entry */
err = mvpp2_prs_mac_da_accept(port->priv, port->id, da, true);
if (err)
return err;
/* Set addr in the device */
ether_addr_copy(dev->dev_addr, da);
return 0;
}
/* Delete all port's multicast simple (not range) entries */
static void mvpp2_prs_mcast_del_all(struct mvpp2 *priv, int port)
{
struct mvpp2_prs_entry pe;
int index, tid;
for (tid = MVPP2_PE_FIRST_FREE_TID;
tid <= MVPP2_PE_LAST_FREE_TID; tid++) {
unsigned char da[ETH_ALEN], da_mask[ETH_ALEN];
if (!priv->prs_shadow[tid].valid ||
(priv->prs_shadow[tid].lu != MVPP2_PRS_LU_MAC) ||
(priv->prs_shadow[tid].udf != MVPP2_PRS_UDF_MAC_DEF))
continue;
/* Only simple mac entries */
pe.index = tid;
mvpp2_prs_hw_read(priv, &pe);
/* Read mac addr from entry */
for (index = 0; index < ETH_ALEN; index++)
mvpp2_prs_tcam_data_byte_get(&pe, index, &da[index],
&da_mask[index]);
if (is_multicast_ether_addr(da) && !is_broadcast_ether_addr(da))
/* Delete this entry */
mvpp2_prs_mac_da_accept(priv, port, da, false);
}
}
static int mvpp2_prs_tag_mode_set(struct mvpp2 *priv, int port, int type)
{
switch (type) {
case MVPP2_TAG_TYPE_EDSA:
/* Add port to EDSA entries */
mvpp2_prs_dsa_tag_set(priv, port, true,
MVPP2_PRS_TAGGED, MVPP2_PRS_EDSA);
mvpp2_prs_dsa_tag_set(priv, port, true,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_EDSA);
/* Remove port from DSA entries */
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_TAGGED, MVPP2_PRS_DSA);
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_DSA);
break;
case MVPP2_TAG_TYPE_DSA:
/* Add port to DSA entries */
mvpp2_prs_dsa_tag_set(priv, port, true,
MVPP2_PRS_TAGGED, MVPP2_PRS_DSA);
mvpp2_prs_dsa_tag_set(priv, port, true,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_DSA);
/* Remove port from EDSA entries */
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_TAGGED, MVPP2_PRS_EDSA);
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_EDSA);
break;
case MVPP2_TAG_TYPE_MH:
case MVPP2_TAG_TYPE_NONE:
/* Remove port form EDSA and DSA entries */
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_TAGGED, MVPP2_PRS_DSA);
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_DSA);
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_TAGGED, MVPP2_PRS_EDSA);
mvpp2_prs_dsa_tag_set(priv, port, false,
MVPP2_PRS_UNTAGGED, MVPP2_PRS_EDSA);
break;
default:
if ((type < 0) || (type > MVPP2_TAG_TYPE_EDSA))
return -EINVAL;
}
return 0;
}
/* Set prs flow for the port */
static int mvpp2_prs_def_flow(struct mvpp2_port *port)
{
struct mvpp2_prs_entry *pe;
int tid;
pe = mvpp2_prs_flow_find(port->priv, port->id);
/* Such entry not exist */
if (!pe) {
/* Go through the all entires from last to first */
tid = mvpp2_prs_tcam_first_free(port->priv,
MVPP2_PE_LAST_FREE_TID,
MVPP2_PE_FIRST_FREE_TID);
if (tid < 0)
return tid;
pe = kzalloc(sizeof(*pe), GFP_KERNEL);
if (!pe)
return -ENOMEM;
mvpp2_prs_tcam_lu_set(pe, MVPP2_PRS_LU_FLOWS);
pe->index = tid;
/* Set flow ID*/
mvpp2_prs_sram_ai_update(pe, port->id, MVPP2_PRS_FLOW_ID_MASK);
mvpp2_prs_sram_bits_set(pe, MVPP2_PRS_SRAM_LU_DONE_BIT, 1);
/* Update shadow table */
mvpp2_prs_shadow_set(port->priv, pe->index, MVPP2_PRS_LU_FLOWS);
}
mvpp2_prs_tcam_port_map_set(pe, (1 << port->id));
mvpp2_prs_hw_write(port->priv, pe);
kfree(pe);
return 0;
}
/* Classifier configuration routines */
/* Update classification flow table registers */
static void mvpp2_cls_flow_write(struct mvpp2 *priv,
struct mvpp2_cls_flow_entry *fe)
{
mvpp2_write(priv, MVPP2_CLS_FLOW_INDEX_REG, fe->index);
mvpp2_write(priv, MVPP2_CLS_FLOW_TBL0_REG, fe->data[0]);
mvpp2_write(priv, MVPP2_CLS_FLOW_TBL1_REG, fe->data[1]);
mvpp2_write(priv, MVPP2_CLS_FLOW_TBL2_REG, fe->data[2]);
}
/* Update classification lookup table register */
static void mvpp2_cls_lookup_write(struct mvpp2 *priv,
struct mvpp2_cls_lookup_entry *le)
{
u32 val;
val = (le->way << MVPP2_CLS_LKP_INDEX_WAY_OFFS) | le->lkpid;
mvpp2_write(priv, MVPP2_CLS_LKP_INDEX_REG, val);
mvpp2_write(priv, MVPP2_CLS_LKP_TBL_REG, le->data);
}
/* Classifier default initialization */
static void mvpp2_cls_init(struct mvpp2 *priv)
{
struct mvpp2_cls_lookup_entry le;
struct mvpp2_cls_flow_entry fe;
int index;
/* Enable classifier */
mvpp2_write(priv, MVPP2_CLS_MODE_REG, MVPP2_CLS_MODE_ACTIVE_MASK);
/* Clear classifier flow table */
memset(&fe.data, 0, sizeof(fe.data));
for (index = 0; index < MVPP2_CLS_FLOWS_TBL_SIZE; index++) {
fe.index = index;
mvpp2_cls_flow_write(priv, &fe);
}
/* Clear classifier lookup table */
le.data = 0;
for (index = 0; index < MVPP2_CLS_LKP_TBL_SIZE; index++) {
le.lkpid = index;
le.way = 0;
mvpp2_cls_lookup_write(priv, &le);
le.way = 1;
mvpp2_cls_lookup_write(priv, &le);
}
}
static void mvpp2_cls_port_config(struct mvpp2_port *port)
{
struct mvpp2_cls_lookup_entry le;
u32 val;
/* Set way for the port */
val = mvpp2_read(port->priv, MVPP2_CLS_PORT_WAY_REG);
val &= ~MVPP2_CLS_PORT_WAY_MASK(port->id);
mvpp2_write(port->priv, MVPP2_CLS_PORT_WAY_REG, val);
/* Pick the entry to be accessed in lookup ID decoding table
* according to the way and lkpid.
*/
le.lkpid = port->id;
le.way = 0;
le.data = 0;
/* Set initial CPU queue for receiving packets */
le.data &= ~MVPP2_CLS_LKP_TBL_RXQ_MASK;
le.data |= port->first_rxq;
/* Disable classification engines */
le.data &= ~MVPP2_CLS_LKP_TBL_LOOKUP_EN_MASK;
/* Update lookup ID table entry */
mvpp2_cls_lookup_write(port->priv, &le);
}
/* Set CPU queue number for oversize packets */
static void mvpp2_cls_oversize_rxq_set(struct mvpp2_port *port)
{
u32 val;
mvpp2_write(port->priv, MVPP2_CLS_OVERSIZE_RXQ_LOW_REG(port->id),
port->first_rxq & MVPP2_CLS_OVERSIZE_RXQ_LOW_MASK);
mvpp2_write(port->priv, MVPP2_CLS_SWFWD_P2HQ_REG(port->id),
(port->first_rxq >> MVPP2_CLS_OVERSIZE_RXQ_LOW_BITS));
val = mvpp2_read(port->priv, MVPP2_CLS_SWFWD_PCTRL_REG);
val |= MVPP2_CLS_SWFWD_PCTRL_MASK(port->id);
mvpp2_write(port->priv, MVPP2_CLS_SWFWD_PCTRL_REG, val);
}
static void *mvpp2_frag_alloc(const struct mvpp2_bm_pool *pool)
{
if (likely(pool->frag_size <= PAGE_SIZE))
return netdev_alloc_frag(pool->frag_size);
else
return kmalloc(pool->frag_size, GFP_ATOMIC);
}
static void mvpp2_frag_free(const struct mvpp2_bm_pool *pool, void *data)
{
if (likely(pool->frag_size <= PAGE_SIZE))
skb_free_frag(data);
else
kfree(data);
}
/* Buffer Manager configuration routines */
/* Create pool */
static int mvpp2_bm_pool_create(struct platform_device *pdev,
struct mvpp2 *priv,
struct mvpp2_bm_pool *bm_pool, int size)
{
u32 val;
/* Number of buffer pointers must be a multiple of 16, as per
* hardware constraints
*/
if (!IS_ALIGNED(size, 16))
return -EINVAL;
/* PPv2.1 needs 8 bytes per buffer pointer, PPv2.2 needs 16
* bytes per buffer pointer
*/
if (priv->hw_version == MVPP21)
bm_pool->size_bytes = 2 * sizeof(u32) * size;
else
bm_pool->size_bytes = 2 * sizeof(u64) * size;
bm_pool->virt_addr = dma_alloc_coherent(&pdev->dev, bm_pool->size_bytes,
&bm_pool->dma_addr,
GFP_KERNEL);
if (!bm_pool->virt_addr)
return -ENOMEM;
if (!IS_ALIGNED((unsigned long)bm_pool->virt_addr,
MVPP2_BM_POOL_PTR_ALIGN)) {
dma_free_coherent(&pdev->dev, bm_pool->size_bytes,
bm_pool->virt_addr, bm_pool->dma_addr);
dev_err(&pdev->dev, "BM pool %d is not %d bytes aligned\n",
bm_pool->id, MVPP2_BM_POOL_PTR_ALIGN);
return -ENOMEM;
}
mvpp2_write(priv, MVPP2_BM_POOL_BASE_REG(bm_pool->id),
lower_32_bits(bm_pool->dma_addr));
mvpp2_write(priv, MVPP2_BM_POOL_SIZE_REG(bm_pool->id), size);
val = mvpp2_read(priv, MVPP2_BM_POOL_CTRL_REG(bm_pool->id));
val |= MVPP2_BM_START_MASK;
mvpp2_write(priv, MVPP2_BM_POOL_CTRL_REG(bm_pool->id), val);
bm_pool->type = MVPP2_BM_FREE;
bm_pool->size = size;
bm_pool->pkt_size = 0;
bm_pool->buf_num = 0;
return 0;
}
/* Set pool buffer size */
static void mvpp2_bm_pool_bufsize_set(struct mvpp2 *priv,
struct mvpp2_bm_pool *bm_pool,
int buf_size)
{
u32 val;
bm_pool->buf_size = buf_size;
val = ALIGN(buf_size, 1 << MVPP2_POOL_BUF_SIZE_OFFSET);
mvpp2_write(priv, MVPP2_POOL_BUF_SIZE_REG(bm_pool->id), val);
}
static void mvpp2_bm_bufs_get_addrs(struct device *dev, struct mvpp2 *priv,
struct mvpp2_bm_pool *bm_pool,
dma_addr_t *dma_addr,
phys_addr_t *phys_addr)
{
int cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
*dma_addr = mvpp2_percpu_read(priv, cpu,
MVPP2_BM_PHY_ALLOC_REG(bm_pool->id));
*phys_addr = mvpp2_percpu_read(priv, cpu, MVPP2_BM_VIRT_ALLOC_REG);
if (priv->hw_version == MVPP22) {
u32 val;
u32 dma_addr_highbits, phys_addr_highbits;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
val = mvpp2_percpu_read(priv, cpu, MVPP22_BM_ADDR_HIGH_ALLOC);
dma_addr_highbits = (val & MVPP22_BM_ADDR_HIGH_PHYS_MASK);
phys_addr_highbits = (val & MVPP22_BM_ADDR_HIGH_VIRT_MASK) >>
MVPP22_BM_ADDR_HIGH_VIRT_SHIFT;
if (sizeof(dma_addr_t) == 8)
*dma_addr |= (u64)dma_addr_highbits << 32;
if (sizeof(phys_addr_t) == 8)
*phys_addr |= (u64)phys_addr_highbits << 32;
}
put_cpu();
}
/* Free all buffers from the pool */
static void mvpp2_bm_bufs_free(struct device *dev, struct mvpp2 *priv,
struct mvpp2_bm_pool *bm_pool)
{
int i;
for (i = 0; i < bm_pool->buf_num; i++) {
dma_addr_t buf_dma_addr;
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
phys_addr_t buf_phys_addr;
void *data;
mvpp2_bm_bufs_get_addrs(dev, priv, bm_pool,
&buf_dma_addr, &buf_phys_addr);
dma_unmap_single(dev, buf_dma_addr,
bm_pool->buf_size, DMA_FROM_DEVICE);
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
data = (void *)phys_to_virt(buf_phys_addr);
if (!data)
break;
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
mvpp2_frag_free(bm_pool, data);
}
/* Update BM driver with number of buffers removed from pool */
bm_pool->buf_num -= i;
}
/* Cleanup pool */
static int mvpp2_bm_pool_destroy(struct platform_device *pdev,
struct mvpp2 *priv,
struct mvpp2_bm_pool *bm_pool)
{
u32 val;
mvpp2_bm_bufs_free(&pdev->dev, priv, bm_pool);
if (bm_pool->buf_num) {
WARN(1, "cannot free all buffers in pool %d\n", bm_pool->id);
return 0;
}
val = mvpp2_read(priv, MVPP2_BM_POOL_CTRL_REG(bm_pool->id));
val |= MVPP2_BM_STOP_MASK;
mvpp2_write(priv, MVPP2_BM_POOL_CTRL_REG(bm_pool->id), val);
dma_free_coherent(&pdev->dev, bm_pool->size_bytes,
bm_pool->virt_addr,
bm_pool->dma_addr);
return 0;
}
static int mvpp2_bm_pools_init(struct platform_device *pdev,
struct mvpp2 *priv)
{
int i, err, size;
struct mvpp2_bm_pool *bm_pool;
/* Create all pools with maximum size */
size = MVPP2_BM_POOL_SIZE_MAX;
for (i = 0; i < MVPP2_BM_POOLS_NUM; i++) {
bm_pool = &priv->bm_pools[i];
bm_pool->id = i;
err = mvpp2_bm_pool_create(pdev, priv, bm_pool, size);
if (err)
goto err_unroll_pools;
mvpp2_bm_pool_bufsize_set(priv, bm_pool, 0);
}
return 0;
err_unroll_pools:
dev_err(&pdev->dev, "failed to create BM pool %d, size %d\n", i, size);
for (i = i - 1; i >= 0; i--)
mvpp2_bm_pool_destroy(pdev, priv, &priv->bm_pools[i]);
return err;
}
static int mvpp2_bm_init(struct platform_device *pdev, struct mvpp2 *priv)
{
int i, err;
for (i = 0; i < MVPP2_BM_POOLS_NUM; i++) {
/* Mask BM all interrupts */
mvpp2_write(priv, MVPP2_BM_INTR_MASK_REG(i), 0);
/* Clear BM cause register */
mvpp2_write(priv, MVPP2_BM_INTR_CAUSE_REG(i), 0);
}
/* Allocate and initialize BM pools */
priv->bm_pools = devm_kcalloc(&pdev->dev, MVPP2_BM_POOLS_NUM,
sizeof(*priv->bm_pools), GFP_KERNEL);
if (!priv->bm_pools)
return -ENOMEM;
err = mvpp2_bm_pools_init(pdev, priv);
if (err < 0)
return err;
return 0;
}
/* Attach long pool to rxq */
static void mvpp2_rxq_long_pool_set(struct mvpp2_port *port,
int lrxq, int long_pool)
{
u32 val, mask;
int prxq;
/* Get queue physical ID */
prxq = port->rxqs[lrxq]->id;
if (port->priv->hw_version == MVPP21)
mask = MVPP21_RXQ_POOL_LONG_MASK;
else
mask = MVPP22_RXQ_POOL_LONG_MASK;
val = mvpp2_read(port->priv, MVPP2_RXQ_CONFIG_REG(prxq));
val &= ~mask;
val |= (long_pool << MVPP2_RXQ_POOL_LONG_OFFS) & mask;
mvpp2_write(port->priv, MVPP2_RXQ_CONFIG_REG(prxq), val);
}
/* Attach short pool to rxq */
static void mvpp2_rxq_short_pool_set(struct mvpp2_port *port,
int lrxq, int short_pool)
{
u32 val, mask;
int prxq;
/* Get queue physical ID */
prxq = port->rxqs[lrxq]->id;
if (port->priv->hw_version == MVPP21)
mask = MVPP21_RXQ_POOL_SHORT_MASK;
else
mask = MVPP22_RXQ_POOL_SHORT_MASK;
val = mvpp2_read(port->priv, MVPP2_RXQ_CONFIG_REG(prxq));
val &= ~mask;
val |= (short_pool << MVPP2_RXQ_POOL_SHORT_OFFS) & mask;
mvpp2_write(port->priv, MVPP2_RXQ_CONFIG_REG(prxq), val);
}
static void *mvpp2_buf_alloc(struct mvpp2_port *port,
struct mvpp2_bm_pool *bm_pool,
dma_addr_t *buf_dma_addr,
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
phys_addr_t *buf_phys_addr,
gfp_t gfp_mask)
{
dma_addr_t dma_addr;
void *data;
data = mvpp2_frag_alloc(bm_pool);
if (!data)
return NULL;
dma_addr = dma_map_single(port->dev->dev.parent, data,
MVPP2_RX_BUF_SIZE(bm_pool->pkt_size),
DMA_FROM_DEVICE);
if (unlikely(dma_mapping_error(port->dev->dev.parent, dma_addr))) {
mvpp2_frag_free(bm_pool, data);
return NULL;
}
*buf_dma_addr = dma_addr;
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
*buf_phys_addr = virt_to_phys(data);
return data;
}
/* Release buffer to BM */
static inline void mvpp2_bm_pool_put(struct mvpp2_port *port, int pool,
dma_addr_t buf_dma_addr,
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
phys_addr_t buf_phys_addr)
{
int cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
if (port->priv->hw_version == MVPP22) {
u32 val = 0;
if (sizeof(dma_addr_t) == 8)
val |= upper_32_bits(buf_dma_addr) &
MVPP22_BM_ADDR_HIGH_PHYS_RLS_MASK;
if (sizeof(phys_addr_t) == 8)
val |= (upper_32_bits(buf_phys_addr)
<< MVPP22_BM_ADDR_HIGH_VIRT_RLS_SHIFT) &
MVPP22_BM_ADDR_HIGH_VIRT_RLS_MASK;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu,
MVPP22_BM_ADDR_HIGH_RLS_REG, val);
}
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
/* MVPP2_BM_VIRT_RLS_REG is not interpreted by HW, and simply
* returned in the "cookie" field of the RX
* descriptor. Instead of storing the virtual address, we
* store the physical address
*/
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu,
MVPP2_BM_VIRT_RLS_REG, buf_phys_addr);
mvpp2_percpu_write(port->priv, cpu,
MVPP2_BM_PHY_RLS_REG(pool), buf_dma_addr);
put_cpu();
}
/* Allocate buffers for the pool */
static int mvpp2_bm_bufs_add(struct mvpp2_port *port,
struct mvpp2_bm_pool *bm_pool, int buf_num)
{
int i, buf_size, total_size;
dma_addr_t dma_addr;
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
phys_addr_t phys_addr;
void *buf;
buf_size = MVPP2_RX_BUF_SIZE(bm_pool->pkt_size);
total_size = MVPP2_RX_TOTAL_SIZE(buf_size);
if (buf_num < 0 ||
(buf_num + bm_pool->buf_num > bm_pool->size)) {
netdev_err(port->dev,
"cannot allocate %d buffers for pool %d\n",
buf_num, bm_pool->id);
return 0;
}
for (i = 0; i < buf_num; i++) {
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
buf = mvpp2_buf_alloc(port, bm_pool, &dma_addr,
&phys_addr, GFP_KERNEL);
if (!buf)
break;
mvpp2_bm_pool_put(port, bm_pool->id, dma_addr,
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
phys_addr);
}
/* Update BM driver with number of buffers added to pool */
bm_pool->buf_num += i;
netdev_dbg(port->dev,
"%s pool %d: pkt_size=%4d, buf_size=%4d, total_size=%4d\n",
bm_pool->type == MVPP2_BM_SWF_SHORT ? "short" : " long",
bm_pool->id, bm_pool->pkt_size, buf_size, total_size);
netdev_dbg(port->dev,
"%s pool %d: %d of %d buffers added\n",
bm_pool->type == MVPP2_BM_SWF_SHORT ? "short" : " long",
bm_pool->id, i, buf_num);
return i;
}
/* Notify the driver that BM pool is being used as specific type and return the
* pool pointer on success
*/
static struct mvpp2_bm_pool *
mvpp2_bm_pool_use(struct mvpp2_port *port, int pool, enum mvpp2_bm_type type,
int pkt_size)
{
struct mvpp2_bm_pool *new_pool = &port->priv->bm_pools[pool];
int num;
if (new_pool->type != MVPP2_BM_FREE && new_pool->type != type) {
netdev_err(port->dev, "mixing pool types is forbidden\n");
return NULL;
}
if (new_pool->type == MVPP2_BM_FREE)
new_pool->type = type;
/* Allocate buffers in case BM pool is used as long pool, but packet
* size doesn't match MTU or BM pool hasn't being used yet
*/
if (((type == MVPP2_BM_SWF_LONG) && (pkt_size > new_pool->pkt_size)) ||
(new_pool->pkt_size == 0)) {
int pkts_num;
/* Set default buffer number or free all the buffers in case
* the pool is not empty
*/
pkts_num = new_pool->buf_num;
if (pkts_num == 0)
pkts_num = type == MVPP2_BM_SWF_LONG ?
MVPP2_BM_LONG_BUF_NUM :
MVPP2_BM_SHORT_BUF_NUM;
else
mvpp2_bm_bufs_free(port->dev->dev.parent,
port->priv, new_pool);
new_pool->pkt_size = pkt_size;
new_pool->frag_size =
SKB_DATA_ALIGN(MVPP2_RX_BUF_SIZE(pkt_size)) +
MVPP2_SKB_SHINFO_SIZE;
/* Allocate buffers for this pool */
num = mvpp2_bm_bufs_add(port, new_pool, pkts_num);
if (num != pkts_num) {
WARN(1, "pool %d: %d of %d allocated\n",
new_pool->id, num, pkts_num);
return NULL;
}
}
mvpp2_bm_pool_bufsize_set(port->priv, new_pool,
MVPP2_RX_BUF_SIZE(new_pool->pkt_size));
return new_pool;
}
/* Initialize pools for swf */
static int mvpp2_swf_bm_pool_init(struct mvpp2_port *port)
{
int rxq;
if (!port->pool_long) {
port->pool_long =
mvpp2_bm_pool_use(port, MVPP2_BM_SWF_LONG_POOL(port->id),
MVPP2_BM_SWF_LONG,
port->pkt_size);
if (!port->pool_long)
return -ENOMEM;
port->pool_long->port_map |= (1 << port->id);
for (rxq = 0; rxq < port->nrxqs; rxq++)
mvpp2_rxq_long_pool_set(port, rxq, port->pool_long->id);
}
if (!port->pool_short) {
port->pool_short =
mvpp2_bm_pool_use(port, MVPP2_BM_SWF_SHORT_POOL,
MVPP2_BM_SWF_SHORT,
MVPP2_BM_SHORT_PKT_SIZE);
if (!port->pool_short)
return -ENOMEM;
port->pool_short->port_map |= (1 << port->id);
for (rxq = 0; rxq < port->nrxqs; rxq++)
mvpp2_rxq_short_pool_set(port, rxq,
port->pool_short->id);
}
return 0;
}
static int mvpp2_bm_update_mtu(struct net_device *dev, int mtu)
{
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2_bm_pool *port_pool = port->pool_long;
int num, pkts_num = port_pool->buf_num;
int pkt_size = MVPP2_RX_PKT_SIZE(mtu);
/* Update BM pool with new buffer size */
mvpp2_bm_bufs_free(dev->dev.parent, port->priv, port_pool);
if (port_pool->buf_num) {
WARN(1, "cannot free all buffers in pool %d\n", port_pool->id);
return -EIO;
}
port_pool->pkt_size = pkt_size;
port_pool->frag_size = SKB_DATA_ALIGN(MVPP2_RX_BUF_SIZE(pkt_size)) +
MVPP2_SKB_SHINFO_SIZE;
num = mvpp2_bm_bufs_add(port, port_pool, pkts_num);
if (num != pkts_num) {
WARN(1, "pool %d: %d of %d allocated\n",
port_pool->id, num, pkts_num);
return -EIO;
}
mvpp2_bm_pool_bufsize_set(port->priv, port_pool,
MVPP2_RX_BUF_SIZE(port_pool->pkt_size));
dev->mtu = mtu;
netdev_update_features(dev);
return 0;
}
static inline void mvpp2_interrupts_enable(struct mvpp2_port *port)
{
int i, sw_thread_mask = 0;
for (i = 0; i < port->nqvecs; i++)
sw_thread_mask |= port->qvecs[i].sw_thread_mask;
mvpp2_write(port->priv, MVPP2_ISR_ENABLE_REG(port->id),
MVPP2_ISR_ENABLE_INTERRUPT(sw_thread_mask));
}
static inline void mvpp2_interrupts_disable(struct mvpp2_port *port)
{
int i, sw_thread_mask = 0;
for (i = 0; i < port->nqvecs; i++)
sw_thread_mask |= port->qvecs[i].sw_thread_mask;
mvpp2_write(port->priv, MVPP2_ISR_ENABLE_REG(port->id),
MVPP2_ISR_DISABLE_INTERRUPT(sw_thread_mask));
}
static inline void mvpp2_qvec_interrupt_enable(struct mvpp2_queue_vector *qvec)
{
struct mvpp2_port *port = qvec->port;
mvpp2_write(port->priv, MVPP2_ISR_ENABLE_REG(port->id),
MVPP2_ISR_ENABLE_INTERRUPT(qvec->sw_thread_mask));
}
static inline void mvpp2_qvec_interrupt_disable(struct mvpp2_queue_vector *qvec)
{
struct mvpp2_port *port = qvec->port;
mvpp2_write(port->priv, MVPP2_ISR_ENABLE_REG(port->id),
MVPP2_ISR_DISABLE_INTERRUPT(qvec->sw_thread_mask));
}
/* Mask the current CPU's Rx/Tx interrupts
* Called by on_each_cpu(), guaranteed to run with migration disabled,
* using smp_processor_id() is OK.
*/
static void mvpp2_interrupts_mask(void *arg)
{
struct mvpp2_port *port = arg;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, smp_processor_id(),
MVPP2_ISR_RX_TX_MASK_REG(port->id), 0);
}
/* Unmask the current CPU's Rx/Tx interrupts.
* Called by on_each_cpu(), guaranteed to run with migration disabled,
* using smp_processor_id() is OK.
*/
static void mvpp2_interrupts_unmask(void *arg)
{
struct mvpp2_port *port = arg;
u32 val;
val = MVPP2_CAUSE_MISC_SUM_MASK |
MVPP2_CAUSE_RXQ_OCCUP_DESC_ALL_MASK;
if (port->has_tx_irqs)
val |= MVPP2_CAUSE_TXQ_OCCUP_DESC_ALL_MASK;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, smp_processor_id(),
MVPP2_ISR_RX_TX_MASK_REG(port->id), val);
}
static void
mvpp2_shared_interrupt_mask_unmask(struct mvpp2_port *port, bool mask)
{
u32 val;
int i;
if (port->priv->hw_version != MVPP22)
return;
if (mask)
val = 0;
else
val = MVPP2_CAUSE_RXQ_OCCUP_DESC_ALL_MASK;
for (i = 0; i < port->nqvecs; i++) {
struct mvpp2_queue_vector *v = port->qvecs + i;
if (v->type != MVPP2_QUEUE_VECTOR_SHARED)
continue;
mvpp2_percpu_write(port->priv, v->sw_thread_id,
MVPP2_ISR_RX_TX_MASK_REG(port->id), val);
}
}
/* Port configuration routines */
static void mvpp22_gop_init_rgmii(struct mvpp2_port *port)
{
struct mvpp2 *priv = port->priv;
u32 val;
regmap_read(priv->sysctrl_base, GENCONF_PORT_CTRL0, &val);
val |= GENCONF_PORT_CTRL0_BUS_WIDTH_SELECT;
regmap_write(priv->sysctrl_base, GENCONF_PORT_CTRL0, val);
regmap_read(priv->sysctrl_base, GENCONF_CTRL0, &val);
if (port->gop_id == 2)
val |= GENCONF_CTRL0_PORT0_RGMII | GENCONF_CTRL0_PORT1_RGMII;
else if (port->gop_id == 3)
val |= GENCONF_CTRL0_PORT1_RGMII_MII;
regmap_write(priv->sysctrl_base, GENCONF_CTRL0, val);
}
static void mvpp22_gop_init_sgmii(struct mvpp2_port *port)
{
struct mvpp2 *priv = port->priv;
u32 val;
regmap_read(priv->sysctrl_base, GENCONF_PORT_CTRL0, &val);
val |= GENCONF_PORT_CTRL0_BUS_WIDTH_SELECT |
GENCONF_PORT_CTRL0_RX_DATA_SAMPLE;
regmap_write(priv->sysctrl_base, GENCONF_PORT_CTRL0, val);
if (port->gop_id > 1) {
regmap_read(priv->sysctrl_base, GENCONF_CTRL0, &val);
if (port->gop_id == 2)
val &= ~GENCONF_CTRL0_PORT0_RGMII;
else if (port->gop_id == 3)
val &= ~GENCONF_CTRL0_PORT1_RGMII_MII;
regmap_write(priv->sysctrl_base, GENCONF_CTRL0, val);
}
}
static void mvpp22_gop_init_10gkr(struct mvpp2_port *port)
{
struct mvpp2 *priv = port->priv;
void __iomem *mpcs = priv->iface_base + MVPP22_MPCS_BASE(port->gop_id);
void __iomem *xpcs = priv->iface_base + MVPP22_XPCS_BASE(port->gop_id);
u32 val;
/* XPCS */
val = readl(xpcs + MVPP22_XPCS_CFG0);
val &= ~(MVPP22_XPCS_CFG0_PCS_MODE(0x3) |
MVPP22_XPCS_CFG0_ACTIVE_LANE(0x3));
val |= MVPP22_XPCS_CFG0_ACTIVE_LANE(2);
writel(val, xpcs + MVPP22_XPCS_CFG0);
/* MPCS */
val = readl(mpcs + MVPP22_MPCS_CTRL);
val &= ~MVPP22_MPCS_CTRL_FWD_ERR_CONN;
writel(val, mpcs + MVPP22_MPCS_CTRL);
val = readl(mpcs + MVPP22_MPCS_CLK_RESET);
val &= ~(MVPP22_MPCS_CLK_RESET_DIV_RATIO(0x7) | MAC_CLK_RESET_MAC |
MAC_CLK_RESET_SD_RX | MAC_CLK_RESET_SD_TX);
val |= MVPP22_MPCS_CLK_RESET_DIV_RATIO(1);
writel(val, mpcs + MVPP22_MPCS_CLK_RESET);
val &= ~MVPP22_MPCS_CLK_RESET_DIV_SET;
val |= MAC_CLK_RESET_MAC | MAC_CLK_RESET_SD_RX | MAC_CLK_RESET_SD_TX;
writel(val, mpcs + MVPP22_MPCS_CLK_RESET);
}
static int mvpp22_gop_init(struct mvpp2_port *port)
{
struct mvpp2 *priv = port->priv;
u32 val;
if (!priv->sysctrl_base)
return 0;
switch (port->phy_interface) {
case PHY_INTERFACE_MODE_RGMII:
case PHY_INTERFACE_MODE_RGMII_ID:
case PHY_INTERFACE_MODE_RGMII_RXID:
case PHY_INTERFACE_MODE_RGMII_TXID:
if (port->gop_id == 0)
goto invalid_conf;
mvpp22_gop_init_rgmii(port);
break;
case PHY_INTERFACE_MODE_SGMII:
mvpp22_gop_init_sgmii(port);
break;
case PHY_INTERFACE_MODE_10GKR:
if (port->gop_id != 0)
goto invalid_conf;
mvpp22_gop_init_10gkr(port);
break;
default:
goto unsupported_conf;
}
regmap_read(priv->sysctrl_base, GENCONF_PORT_CTRL1, &val);
val |= GENCONF_PORT_CTRL1_RESET(port->gop_id) |
GENCONF_PORT_CTRL1_EN(port->gop_id);
regmap_write(priv->sysctrl_base, GENCONF_PORT_CTRL1, val);
regmap_read(priv->sysctrl_base, GENCONF_PORT_CTRL0, &val);
val |= GENCONF_PORT_CTRL0_CLK_DIV_PHASE_CLR;
regmap_write(priv->sysctrl_base, GENCONF_PORT_CTRL0, val);
regmap_read(priv->sysctrl_base, GENCONF_SOFT_RESET1, &val);
val |= GENCONF_SOFT_RESET1_GOP;
regmap_write(priv->sysctrl_base, GENCONF_SOFT_RESET1, val);
unsupported_conf:
return 0;
invalid_conf:
netdev_err(port->dev, "Invalid port configuration\n");
return -EINVAL;
}
static void mvpp22_gop_unmask_irq(struct mvpp2_port *port)
{
u32 val;
if (phy_interface_mode_is_rgmii(port->phy_interface) ||
port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
/* Enable the GMAC link status irq for this port */
val = readl(port->base + MVPP22_GMAC_INT_SUM_MASK);
val |= MVPP22_GMAC_INT_SUM_MASK_LINK_STAT;
writel(val, port->base + MVPP22_GMAC_INT_SUM_MASK);
}
if (port->gop_id == 0) {
/* Enable the XLG/GIG irqs for this port */
val = readl(port->base + MVPP22_XLG_EXT_INT_MASK);
if (port->phy_interface == PHY_INTERFACE_MODE_10GKR)
val |= MVPP22_XLG_EXT_INT_MASK_XLG;
else
val |= MVPP22_XLG_EXT_INT_MASK_GIG;
writel(val, port->base + MVPP22_XLG_EXT_INT_MASK);
}
}
static void mvpp22_gop_mask_irq(struct mvpp2_port *port)
{
u32 val;
if (port->gop_id == 0) {
val = readl(port->base + MVPP22_XLG_EXT_INT_MASK);
val &= ~(MVPP22_XLG_EXT_INT_MASK_XLG |
MVPP22_XLG_EXT_INT_MASK_GIG);
writel(val, port->base + MVPP22_XLG_EXT_INT_MASK);
}
if (phy_interface_mode_is_rgmii(port->phy_interface) ||
port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
val = readl(port->base + MVPP22_GMAC_INT_SUM_MASK);
val &= ~MVPP22_GMAC_INT_SUM_MASK_LINK_STAT;
writel(val, port->base + MVPP22_GMAC_INT_SUM_MASK);
}
}
static void mvpp22_gop_setup_irq(struct mvpp2_port *port)
{
u32 val;
if (phy_interface_mode_is_rgmii(port->phy_interface) ||
port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
val = readl(port->base + MVPP22_GMAC_INT_MASK);
val |= MVPP22_GMAC_INT_MASK_LINK_STAT;
writel(val, port->base + MVPP22_GMAC_INT_MASK);
}
if (port->gop_id == 0) {
val = readl(port->base + MVPP22_XLG_INT_MASK);
val |= MVPP22_XLG_INT_MASK_LINK;
writel(val, port->base + MVPP22_XLG_INT_MASK);
}
mvpp22_gop_unmask_irq(port);
}
static int mvpp22_comphy_init(struct mvpp2_port *port)
{
enum phy_mode mode;
int ret;
if (!port->comphy)
return 0;
switch (port->phy_interface) {
case PHY_INTERFACE_MODE_SGMII:
mode = PHY_MODE_SGMII;
break;
case PHY_INTERFACE_MODE_10GKR:
mode = PHY_MODE_10GKR;
break;
default:
return -EINVAL;
}
ret = phy_set_mode(port->comphy, mode);
if (ret)
return ret;
return phy_power_on(port->comphy);
}
static void mvpp2_port_mii_gmac_configure_mode(struct mvpp2_port *port)
{
u32 val;
if (port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
val = readl(port->base + MVPP22_GMAC_CTRL_4_REG);
val |= MVPP22_CTRL4_SYNC_BYPASS_DIS | MVPP22_CTRL4_DP_CLK_SEL |
MVPP22_CTRL4_QSGMII_BYPASS_ACTIVE;
val &= ~MVPP22_CTRL4_EXT_PIN_GMII_SEL;
writel(val, port->base + MVPP22_GMAC_CTRL_4_REG);
val = readl(port->base + MVPP2_GMAC_CTRL_2_REG);
val |= MVPP2_GMAC_DISABLE_PADDING;
val &= ~MVPP2_GMAC_FLOW_CTRL_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_2_REG);
} else if (phy_interface_mode_is_rgmii(port->phy_interface)) {
val = readl(port->base + MVPP22_GMAC_CTRL_4_REG);
val |= MVPP22_CTRL4_EXT_PIN_GMII_SEL |
MVPP22_CTRL4_SYNC_BYPASS_DIS |
MVPP22_CTRL4_QSGMII_BYPASS_ACTIVE;
val &= ~MVPP22_CTRL4_DP_CLK_SEL;
writel(val, port->base + MVPP22_GMAC_CTRL_4_REG);
val = readl(port->base + MVPP2_GMAC_CTRL_2_REG);
val &= ~MVPP2_GMAC_DISABLE_PADDING;
writel(val, port->base + MVPP2_GMAC_CTRL_2_REG);
}
/* The port is connected to a copper PHY */
val = readl(port->base + MVPP2_GMAC_CTRL_0_REG);
val &= ~MVPP2_GMAC_PORT_TYPE_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_0_REG);
val = readl(port->base + MVPP2_GMAC_AUTONEG_CONFIG);
val |= MVPP2_GMAC_IN_BAND_AUTONEG_BYPASS |
MVPP2_GMAC_AN_SPEED_EN | MVPP2_GMAC_FLOW_CTRL_AUTONEG |
MVPP2_GMAC_AN_DUPLEX_EN;
if (port->phy_interface == PHY_INTERFACE_MODE_SGMII)
val |= MVPP2_GMAC_IN_BAND_AUTONEG;
writel(val, port->base + MVPP2_GMAC_AUTONEG_CONFIG);
}
static void mvpp2_port_mii_gmac_configure(struct mvpp2_port *port)
{
u32 val;
/* Force link down */
val = readl(port->base + MVPP2_GMAC_AUTONEG_CONFIG);
val &= ~MVPP2_GMAC_FORCE_LINK_PASS;
val |= MVPP2_GMAC_FORCE_LINK_DOWN;
writel(val, port->base + MVPP2_GMAC_AUTONEG_CONFIG);
/* Set the GMAC in a reset state */
val = readl(port->base + MVPP2_GMAC_CTRL_2_REG);
val |= MVPP2_GMAC_PORT_RESET_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_2_REG);
/* Configure the PCS and in-band AN */
val = readl(port->base + MVPP2_GMAC_CTRL_2_REG);
if (port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
val |= MVPP2_GMAC_INBAND_AN_MASK | MVPP2_GMAC_PCS_ENABLE_MASK;
} else if (phy_interface_mode_is_rgmii(port->phy_interface)) {
val &= ~MVPP2_GMAC_PCS_ENABLE_MASK;
}
writel(val, port->base + MVPP2_GMAC_CTRL_2_REG);
mvpp2_port_mii_gmac_configure_mode(port);
/* Unset the GMAC reset state */
val = readl(port->base + MVPP2_GMAC_CTRL_2_REG);
val &= ~MVPP2_GMAC_PORT_RESET_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_2_REG);
/* Stop forcing link down */
val = readl(port->base + MVPP2_GMAC_AUTONEG_CONFIG);
val &= ~MVPP2_GMAC_FORCE_LINK_DOWN;
writel(val, port->base + MVPP2_GMAC_AUTONEG_CONFIG);
}
static void mvpp2_port_mii_xlg_configure(struct mvpp2_port *port)
{
u32 val;
if (port->gop_id != 0)
return;
val = readl(port->base + MVPP22_XLG_CTRL0_REG);
val |= MVPP22_XLG_CTRL0_RX_FLOW_CTRL_EN;
writel(val, port->base + MVPP22_XLG_CTRL0_REG);
val = readl(port->base + MVPP22_XLG_CTRL4_REG);
val &= ~MVPP22_XLG_CTRL4_MACMODSELECT_GMAC;
val |= MVPP22_XLG_CTRL4_FWD_FC | MVPP22_XLG_CTRL4_FWD_PFC;
writel(val, port->base + MVPP22_XLG_CTRL4_REG);
}
static void mvpp22_port_mii_set(struct mvpp2_port *port)
{
u32 val;
/* Only GOP port 0 has an XLG MAC */
if (port->gop_id == 0) {
val = readl(port->base + MVPP22_XLG_CTRL3_REG);
val &= ~MVPP22_XLG_CTRL3_MACMODESELECT_MASK;
if (port->phy_interface == PHY_INTERFACE_MODE_XAUI ||
port->phy_interface == PHY_INTERFACE_MODE_10GKR)
val |= MVPP22_XLG_CTRL3_MACMODESELECT_10G;
else
val |= MVPP22_XLG_CTRL3_MACMODESELECT_GMAC;
writel(val, port->base + MVPP22_XLG_CTRL3_REG);
}
}
static void mvpp2_port_mii_set(struct mvpp2_port *port)
{
if (port->priv->hw_version == MVPP22)
mvpp22_port_mii_set(port);
if (phy_interface_mode_is_rgmii(port->phy_interface) ||
port->phy_interface == PHY_INTERFACE_MODE_SGMII)
mvpp2_port_mii_gmac_configure(port);
else if (port->phy_interface == PHY_INTERFACE_MODE_10GKR)
mvpp2_port_mii_xlg_configure(port);
}
static void mvpp2_port_fc_adv_enable(struct mvpp2_port *port)
{
u32 val;
val = readl(port->base + MVPP2_GMAC_AUTONEG_CONFIG);
val |= MVPP2_GMAC_FC_ADV_EN;
writel(val, port->base + MVPP2_GMAC_AUTONEG_CONFIG);
}
static void mvpp2_port_enable(struct mvpp2_port *port)
{
u32 val;
/* Only GOP port 0 has an XLG MAC */
if (port->gop_id == 0 &&
(port->phy_interface == PHY_INTERFACE_MODE_XAUI ||
port->phy_interface == PHY_INTERFACE_MODE_10GKR)) {
val = readl(port->base + MVPP22_XLG_CTRL0_REG);
val |= MVPP22_XLG_CTRL0_PORT_EN |
MVPP22_XLG_CTRL0_MAC_RESET_DIS;
val &= ~MVPP22_XLG_CTRL0_MIB_CNT_DIS;
writel(val, port->base + MVPP22_XLG_CTRL0_REG);
} else {
val = readl(port->base + MVPP2_GMAC_CTRL_0_REG);
val |= MVPP2_GMAC_PORT_EN_MASK;
val |= MVPP2_GMAC_MIB_CNTR_EN_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_0_REG);
}
}
static void mvpp2_port_disable(struct mvpp2_port *port)
{
u32 val;
/* Only GOP port 0 has an XLG MAC */
if (port->gop_id == 0 &&
(port->phy_interface == PHY_INTERFACE_MODE_XAUI ||
port->phy_interface == PHY_INTERFACE_MODE_10GKR)) {
val = readl(port->base + MVPP22_XLG_CTRL0_REG);
val &= ~(MVPP22_XLG_CTRL0_PORT_EN |
MVPP22_XLG_CTRL0_MAC_RESET_DIS);
writel(val, port->base + MVPP22_XLG_CTRL0_REG);
} else {
val = readl(port->base + MVPP2_GMAC_CTRL_0_REG);
val &= ~(MVPP2_GMAC_PORT_EN_MASK);
writel(val, port->base + MVPP2_GMAC_CTRL_0_REG);
}
}
/* Set IEEE 802.3x Flow Control Xon Packet Transmission Mode */
static void mvpp2_port_periodic_xon_disable(struct mvpp2_port *port)
{
u32 val;
val = readl(port->base + MVPP2_GMAC_CTRL_1_REG) &
~MVPP2_GMAC_PERIODIC_XON_EN_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_1_REG);
}
/* Configure loopback port */
static void mvpp2_port_loopback_set(struct mvpp2_port *port)
{
u32 val;
val = readl(port->base + MVPP2_GMAC_CTRL_1_REG);
if (port->speed == 1000)
val |= MVPP2_GMAC_GMII_LB_EN_MASK;
else
val &= ~MVPP2_GMAC_GMII_LB_EN_MASK;
if (port->phy_interface == PHY_INTERFACE_MODE_SGMII)
val |= MVPP2_GMAC_PCS_LB_EN_MASK;
else
val &= ~MVPP2_GMAC_PCS_LB_EN_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_1_REG);
}
struct mvpp2_ethtool_counter {
unsigned int offset;
const char string[ETH_GSTRING_LEN];
bool reg_is_64b;
};
static u64 mvpp2_read_count(struct mvpp2_port *port,
const struct mvpp2_ethtool_counter *counter)
{
u64 val;
val = readl(port->stats_base + counter->offset);
if (counter->reg_is_64b)
val += (u64)readl(port->stats_base + counter->offset + 4) << 32;
return val;
}
/* Due to the fact that software statistics and hardware statistics are, by
* design, incremented at different moments in the chain of packet processing,
* it is very likely that incoming packets could have been dropped after being
* counted by hardware but before reaching software statistics (most probably
* multicast packets), and in the oppposite way, during transmission, FCS bytes
* are added in between as well as TSO skb will be split and header bytes added.
* Hence, statistics gathered from userspace with ifconfig (software) and
* ethtool (hardware) cannot be compared.
*/
static const struct mvpp2_ethtool_counter mvpp2_ethtool_regs[] = {
{ MVPP2_MIB_GOOD_OCTETS_RCVD, "good_octets_received", true },
{ MVPP2_MIB_BAD_OCTETS_RCVD, "bad_octets_received" },
{ MVPP2_MIB_CRC_ERRORS_SENT, "crc_errors_sent" },
{ MVPP2_MIB_UNICAST_FRAMES_RCVD, "unicast_frames_received" },
{ MVPP2_MIB_BROADCAST_FRAMES_RCVD, "broadcast_frames_received" },
{ MVPP2_MIB_MULTICAST_FRAMES_RCVD, "multicast_frames_received" },
{ MVPP2_MIB_FRAMES_64_OCTETS, "frames_64_octets" },
{ MVPP2_MIB_FRAMES_65_TO_127_OCTETS, "frames_65_to_127_octet" },
{ MVPP2_MIB_FRAMES_128_TO_255_OCTETS, "frames_128_to_255_octet" },
{ MVPP2_MIB_FRAMES_256_TO_511_OCTETS, "frames_256_to_511_octet" },
{ MVPP2_MIB_FRAMES_512_TO_1023_OCTETS, "frames_512_to_1023_octet" },
{ MVPP2_MIB_FRAMES_1024_TO_MAX_OCTETS, "frames_1024_to_max_octet" },
{ MVPP2_MIB_GOOD_OCTETS_SENT, "good_octets_sent", true },
{ MVPP2_MIB_UNICAST_FRAMES_SENT, "unicast_frames_sent" },
{ MVPP2_MIB_MULTICAST_FRAMES_SENT, "multicast_frames_sent" },
{ MVPP2_MIB_BROADCAST_FRAMES_SENT, "broadcast_frames_sent" },
{ MVPP2_MIB_FC_SENT, "fc_sent" },
{ MVPP2_MIB_FC_RCVD, "fc_received" },
{ MVPP2_MIB_RX_FIFO_OVERRUN, "rx_fifo_overrun" },
{ MVPP2_MIB_UNDERSIZE_RCVD, "undersize_received" },
{ MVPP2_MIB_FRAGMENTS_RCVD, "fragments_received" },
{ MVPP2_MIB_OVERSIZE_RCVD, "oversize_received" },
{ MVPP2_MIB_JABBER_RCVD, "jabber_received" },
{ MVPP2_MIB_MAC_RCV_ERROR, "mac_receive_error" },
{ MVPP2_MIB_BAD_CRC_EVENT, "bad_crc_event" },
{ MVPP2_MIB_COLLISION, "collision" },
{ MVPP2_MIB_LATE_COLLISION, "late_collision" },
};
static void mvpp2_ethtool_get_strings(struct net_device *netdev, u32 sset,
u8 *data)
{
if (sset == ETH_SS_STATS) {
int i;
for (i = 0; i < ARRAY_SIZE(mvpp2_ethtool_regs); i++)
memcpy(data + i * ETH_GSTRING_LEN,
&mvpp2_ethtool_regs[i].string, ETH_GSTRING_LEN);
}
}
static void mvpp2_gather_hw_statistics(struct work_struct *work)
{
struct delayed_work *del_work = to_delayed_work(work);
struct mvpp2_port *port = container_of(del_work, struct mvpp2_port,
stats_work);
u64 *pstats;
int i;
mutex_lock(&port->gather_stats_lock);
pstats = port->ethtool_stats;
for (i = 0; i < ARRAY_SIZE(mvpp2_ethtool_regs); i++)
*pstats++ += mvpp2_read_count(port, &mvpp2_ethtool_regs[i]);
/* No need to read again the counters right after this function if it
* was called asynchronously by the user (ie. use of ethtool).
*/
cancel_delayed_work(&port->stats_work);
queue_delayed_work(port->priv->stats_queue, &port->stats_work,
MVPP2_MIB_COUNTERS_STATS_DELAY);
mutex_unlock(&port->gather_stats_lock);
}
static void mvpp2_ethtool_get_stats(struct net_device *dev,
struct ethtool_stats *stats, u64 *data)
{
struct mvpp2_port *port = netdev_priv(dev);
/* Update statistics for the given port, then take the lock to avoid
* concurrent accesses on the ethtool_stats structure during its copy.
*/
mvpp2_gather_hw_statistics(&port->stats_work.work);
mutex_lock(&port->gather_stats_lock);
memcpy(data, port->ethtool_stats,
sizeof(u64) * ARRAY_SIZE(mvpp2_ethtool_regs));
mutex_unlock(&port->gather_stats_lock);
}
static int mvpp2_ethtool_get_sset_count(struct net_device *dev, int sset)
{
if (sset == ETH_SS_STATS)
return ARRAY_SIZE(mvpp2_ethtool_regs);
return -EOPNOTSUPP;
}
static void mvpp2_port_reset(struct mvpp2_port *port)
{
u32 val;
unsigned int i;
/* Read the GOP statistics to reset the hardware counters */
for (i = 0; i < ARRAY_SIZE(mvpp2_ethtool_regs); i++)
mvpp2_read_count(port, &mvpp2_ethtool_regs[i]);
val = readl(port->base + MVPP2_GMAC_CTRL_2_REG) &
~MVPP2_GMAC_PORT_RESET_MASK;
writel(val, port->base + MVPP2_GMAC_CTRL_2_REG);
while (readl(port->base + MVPP2_GMAC_CTRL_2_REG) &
MVPP2_GMAC_PORT_RESET_MASK)
continue;
}
/* Change maximum receive size of the port */
static inline void mvpp2_gmac_max_rx_size_set(struct mvpp2_port *port)
{
u32 val;
val = readl(port->base + MVPP2_GMAC_CTRL_0_REG);
val &= ~MVPP2_GMAC_MAX_RX_SIZE_MASK;
val |= (((port->pkt_size - MVPP2_MH_SIZE) / 2) <<
MVPP2_GMAC_MAX_RX_SIZE_OFFS);
writel(val, port->base + MVPP2_GMAC_CTRL_0_REG);
}
/* Change maximum receive size of the port */
static inline void mvpp2_xlg_max_rx_size_set(struct mvpp2_port *port)
{
u32 val;
val = readl(port->base + MVPP22_XLG_CTRL1_REG);
val &= ~MVPP22_XLG_CTRL1_FRAMESIZELIMIT_MASK;
val |= ((port->pkt_size - MVPP2_MH_SIZE) / 2) <<
MVPP22_XLG_CTRL1_FRAMESIZELIMIT_OFFS;
writel(val, port->base + MVPP22_XLG_CTRL1_REG);
}
/* Set defaults to the MVPP2 port */
static void mvpp2_defaults_set(struct mvpp2_port *port)
{
int tx_port_num, val, queue, ptxq, lrxq;
if (port->priv->hw_version == MVPP21) {
/* Configure port to loopback if needed */
if (port->flags & MVPP2_F_LOOPBACK)
mvpp2_port_loopback_set(port);
/* Update TX FIFO MIN Threshold */
val = readl(port->base + MVPP2_GMAC_PORT_FIFO_CFG_1_REG);
val &= ~MVPP2_GMAC_TX_FIFO_MIN_TH_ALL_MASK;
/* Min. TX threshold must be less than minimal packet length */
val |= MVPP2_GMAC_TX_FIFO_MIN_TH_MASK(64 - 4 - 2);
writel(val, port->base + MVPP2_GMAC_PORT_FIFO_CFG_1_REG);
}
/* Disable Legacy WRR, Disable EJP, Release from reset */
tx_port_num = mvpp2_egress_port(port);
mvpp2_write(port->priv, MVPP2_TXP_SCHED_PORT_INDEX_REG,
tx_port_num);
mvpp2_write(port->priv, MVPP2_TXP_SCHED_CMD_1_REG, 0);
/* Close bandwidth for all queues */
for (queue = 0; queue < MVPP2_MAX_TXQ; queue++) {
ptxq = mvpp2_txq_phys(port->id, queue);
mvpp2_write(port->priv,
MVPP2_TXQ_SCHED_TOKEN_CNTR_REG(ptxq), 0);
}
/* Set refill period to 1 usec, refill tokens
* and bucket size to maximum
*/
mvpp2_write(port->priv, MVPP2_TXP_SCHED_PERIOD_REG,
port->priv->tclk / USEC_PER_SEC);
val = mvpp2_read(port->priv, MVPP2_TXP_SCHED_REFILL_REG);
val &= ~MVPP2_TXP_REFILL_PERIOD_ALL_MASK;
val |= MVPP2_TXP_REFILL_PERIOD_MASK(1);
val |= MVPP2_TXP_REFILL_TOKENS_ALL_MASK;
mvpp2_write(port->priv, MVPP2_TXP_SCHED_REFILL_REG, val);
val = MVPP2_TXP_TOKEN_SIZE_MAX;
mvpp2_write(port->priv, MVPP2_TXP_SCHED_TOKEN_SIZE_REG, val);
/* Set MaximumLowLatencyPacketSize value to 256 */
mvpp2_write(port->priv, MVPP2_RX_CTRL_REG(port->id),
MVPP2_RX_USE_PSEUDO_FOR_CSUM_MASK |
MVPP2_RX_LOW_LATENCY_PKT_SIZE(256));
/* Enable Rx cache snoop */
for (lrxq = 0; lrxq < port->nrxqs; lrxq++) {
queue = port->rxqs[lrxq]->id;
val = mvpp2_read(port->priv, MVPP2_RXQ_CONFIG_REG(queue));
val |= MVPP2_SNOOP_PKT_SIZE_MASK |
MVPP2_SNOOP_BUF_HDR_MASK;
mvpp2_write(port->priv, MVPP2_RXQ_CONFIG_REG(queue), val);
}
/* At default, mask all interrupts to all present cpus */
mvpp2_interrupts_disable(port);
}
/* Enable/disable receiving packets */
static void mvpp2_ingress_enable(struct mvpp2_port *port)
{
u32 val;
int lrxq, queue;
for (lrxq = 0; lrxq < port->nrxqs; lrxq++) {
queue = port->rxqs[lrxq]->id;
val = mvpp2_read(port->priv, MVPP2_RXQ_CONFIG_REG(queue));
val &= ~MVPP2_RXQ_DISABLE_MASK;
mvpp2_write(port->priv, MVPP2_RXQ_CONFIG_REG(queue), val);
}
}
static void mvpp2_ingress_disable(struct mvpp2_port *port)
{
u32 val;
int lrxq, queue;
for (lrxq = 0; lrxq < port->nrxqs; lrxq++) {
queue = port->rxqs[lrxq]->id;
val = mvpp2_read(port->priv, MVPP2_RXQ_CONFIG_REG(queue));
val |= MVPP2_RXQ_DISABLE_MASK;
mvpp2_write(port->priv, MVPP2_RXQ_CONFIG_REG(queue), val);
}
}
/* Enable transmit via physical egress queue
* - HW starts take descriptors from DRAM
*/
static void mvpp2_egress_enable(struct mvpp2_port *port)
{
u32 qmap;
int queue;
int tx_port_num = mvpp2_egress_port(port);
/* Enable all initialized TXs. */
qmap = 0;
for (queue = 0; queue < port->ntxqs; queue++) {
struct mvpp2_tx_queue *txq = port->txqs[queue];
if (txq->descs)
qmap |= (1 << queue);
}
mvpp2_write(port->priv, MVPP2_TXP_SCHED_PORT_INDEX_REG, tx_port_num);
mvpp2_write(port->priv, MVPP2_TXP_SCHED_Q_CMD_REG, qmap);
}
/* Disable transmit via physical egress queue
* - HW doesn't take descriptors from DRAM
*/
static void mvpp2_egress_disable(struct mvpp2_port *port)
{
u32 reg_data;
int delay;
int tx_port_num = mvpp2_egress_port(port);
/* Issue stop command for active channels only */
mvpp2_write(port->priv, MVPP2_TXP_SCHED_PORT_INDEX_REG, tx_port_num);
reg_data = (mvpp2_read(port->priv, MVPP2_TXP_SCHED_Q_CMD_REG)) &
MVPP2_TXP_SCHED_ENQ_MASK;
if (reg_data != 0)
mvpp2_write(port->priv, MVPP2_TXP_SCHED_Q_CMD_REG,
(reg_data << MVPP2_TXP_SCHED_DISQ_OFFSET));
/* Wait for all Tx activity to terminate. */
delay = 0;
do {
if (delay >= MVPP2_TX_DISABLE_TIMEOUT_MSEC) {
netdev_warn(port->dev,
"Tx stop timed out, status=0x%08x\n",
reg_data);
break;
}
mdelay(1);
delay++;
/* Check port TX Command register that all
* Tx queues are stopped
*/
reg_data = mvpp2_read(port->priv, MVPP2_TXP_SCHED_Q_CMD_REG);
} while (reg_data & MVPP2_TXP_SCHED_ENQ_MASK);
}
/* Rx descriptors helper methods */
/* Get number of Rx descriptors occupied by received packets */
static inline int
mvpp2_rxq_received(struct mvpp2_port *port, int rxq_id)
{
u32 val = mvpp2_read(port->priv, MVPP2_RXQ_STATUS_REG(rxq_id));
return val & MVPP2_RXQ_OCCUPIED_MASK;
}
/* Update Rx queue status with the number of occupied and available
* Rx descriptor slots.
*/
static inline void
mvpp2_rxq_status_update(struct mvpp2_port *port, int rxq_id,
int used_count, int free_count)
{
/* Decrement the number of used descriptors and increment count
* increment the number of free descriptors.
*/
u32 val = used_count | (free_count << MVPP2_RXQ_NUM_NEW_OFFSET);
mvpp2_write(port->priv, MVPP2_RXQ_STATUS_UPDATE_REG(rxq_id), val);
}
/* Get pointer to next RX descriptor to be processed by SW */
static inline struct mvpp2_rx_desc *
mvpp2_rxq_next_desc_get(struct mvpp2_rx_queue *rxq)
{
int rx_desc = rxq->next_desc_to_proc;
rxq->next_desc_to_proc = MVPP2_QUEUE_NEXT_DESC(rxq, rx_desc);
prefetch(rxq->descs + rxq->next_desc_to_proc);
return rxq->descs + rx_desc;
}
/* Set rx queue offset */
static void mvpp2_rxq_offset_set(struct mvpp2_port *port,
int prxq, int offset)
{
u32 val;
/* Convert offset from bytes to units of 32 bytes */
offset = offset >> 5;
val = mvpp2_read(port->priv, MVPP2_RXQ_CONFIG_REG(prxq));
val &= ~MVPP2_RXQ_PACKET_OFFSET_MASK;
/* Offset is in */
val |= ((offset << MVPP2_RXQ_PACKET_OFFSET_OFFS) &
MVPP2_RXQ_PACKET_OFFSET_MASK);
mvpp2_write(port->priv, MVPP2_RXQ_CONFIG_REG(prxq), val);
}
/* Tx descriptors helper methods */
/* Get pointer to next Tx descriptor to be processed (send) by HW */
static struct mvpp2_tx_desc *
mvpp2_txq_next_desc_get(struct mvpp2_tx_queue *txq)
{
int tx_desc = txq->next_desc_to_proc;
txq->next_desc_to_proc = MVPP2_QUEUE_NEXT_DESC(txq, tx_desc);
return txq->descs + tx_desc;
}
/* Update HW with number of aggregated Tx descriptors to be sent
*
* Called only from mvpp2_tx(), so migration is disabled, using
* smp_processor_id() is OK.
*/
static void mvpp2_aggr_txq_pend_desc_add(struct mvpp2_port *port, int pending)
{
/* aggregated access - relevant TXQ number is written in TX desc */
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, smp_processor_id(),
MVPP2_AGGR_TXQ_UPDATE_REG, pending);
}
/* Check if there are enough free descriptors in aggregated txq.
* If not, update the number of occupied descriptors and repeat the check.
*
* Called only from mvpp2_tx(), so migration is disabled, using
* smp_processor_id() is OK.
*/
static int mvpp2_aggr_desc_num_check(struct mvpp2 *priv,
struct mvpp2_tx_queue *aggr_txq, int num)
{
if ((aggr_txq->count + num) > MVPP2_AGGR_TXQ_SIZE) {
/* Update number of occupied aggregated Tx descriptors */
int cpu = smp_processor_id();
u32 val = mvpp2_read(priv, MVPP2_AGGR_TXQ_STATUS_REG(cpu));
aggr_txq->count = val & MVPP2_AGGR_TXQ_PENDING_MASK;
}
if ((aggr_txq->count + num) > MVPP2_AGGR_TXQ_SIZE)
return -ENOMEM;
return 0;
}
/* Reserved Tx descriptors allocation request
*
* Called only from mvpp2_txq_reserved_desc_num_proc(), itself called
* only by mvpp2_tx(), so migration is disabled, using
* smp_processor_id() is OK.
*/
static int mvpp2_txq_alloc_reserved_desc(struct mvpp2 *priv,
struct mvpp2_tx_queue *txq, int num)
{
u32 val;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
int cpu = smp_processor_id();
val = (txq->id << MVPP2_TXQ_RSVD_REQ_Q_OFFSET) | num;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(priv, cpu, MVPP2_TXQ_RSVD_REQ_REG, val);
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
val = mvpp2_percpu_read(priv, cpu, MVPP2_TXQ_RSVD_RSLT_REG);
return val & MVPP2_TXQ_RSVD_RSLT_MASK;
}
/* Check if there are enough reserved descriptors for transmission.
* If not, request chunk of reserved descriptors and check again.
*/
static int mvpp2_txq_reserved_desc_num_proc(struct mvpp2 *priv,
struct mvpp2_tx_queue *txq,
struct mvpp2_txq_pcpu *txq_pcpu,
int num)
{
int req, cpu, desc_count;
if (txq_pcpu->reserved_num >= num)
return 0;
/* Not enough descriptors reserved! Update the reserved descriptor
* count and check again.
*/
desc_count = 0;
/* Compute total of used descriptors */
for_each_present_cpu(cpu) {
struct mvpp2_txq_pcpu *txq_pcpu_aux;
txq_pcpu_aux = per_cpu_ptr(txq->pcpu, cpu);
desc_count += txq_pcpu_aux->count;
desc_count += txq_pcpu_aux->reserved_num;
}
req = max(MVPP2_CPU_DESC_CHUNK, num - txq_pcpu->reserved_num);
desc_count += req;
if (desc_count >
(txq->size - (num_present_cpus() * MVPP2_CPU_DESC_CHUNK)))
return -ENOMEM;
txq_pcpu->reserved_num += mvpp2_txq_alloc_reserved_desc(priv, txq, req);
/* OK, the descriptor cound has been updated: check again. */
if (txq_pcpu->reserved_num < num)
return -ENOMEM;
return 0;
}
/* Release the last allocated Tx descriptor. Useful to handle DMA
* mapping failures in the Tx path.
*/
static void mvpp2_txq_desc_put(struct mvpp2_tx_queue *txq)
{
if (txq->next_desc_to_proc == 0)
txq->next_desc_to_proc = txq->last_desc - 1;
else
txq->next_desc_to_proc--;
}
/* Set Tx descriptors fields relevant for CSUM calculation */
static u32 mvpp2_txq_desc_csum(int l3_offs, int l3_proto,
int ip_hdr_len, int l4_proto)
{
u32 command;
/* fields: L3_offset, IP_hdrlen, L3_type, G_IPv4_chk,
* G_L4_chk, L4_type required only for checksum calculation
*/
command = (l3_offs << MVPP2_TXD_L3_OFF_SHIFT);
command |= (ip_hdr_len << MVPP2_TXD_IP_HLEN_SHIFT);
command |= MVPP2_TXD_IP_CSUM_DISABLE;
if (l3_proto == swab16(ETH_P_IP)) {
command &= ~MVPP2_TXD_IP_CSUM_DISABLE; /* enable IPv4 csum */
command &= ~MVPP2_TXD_L3_IP6; /* enable IPv4 */
} else {
command |= MVPP2_TXD_L3_IP6; /* enable IPv6 */
}
if (l4_proto == IPPROTO_TCP) {
command &= ~MVPP2_TXD_L4_UDP; /* enable TCP */
command &= ~MVPP2_TXD_L4_CSUM_FRAG; /* generate L4 csum */
} else if (l4_proto == IPPROTO_UDP) {
command |= MVPP2_TXD_L4_UDP; /* enable UDP */
command &= ~MVPP2_TXD_L4_CSUM_FRAG; /* generate L4 csum */
} else {
command |= MVPP2_TXD_L4_CSUM_NOT;
}
return command;
}
/* Get number of sent descriptors and decrement counter.
* The number of sent descriptors is returned.
* Per-CPU access
*
* Called only from mvpp2_txq_done(), called from mvpp2_tx()
* (migration disabled) and from the TX completion tasklet (migration
* disabled) so using smp_processor_id() is OK.
*/
static inline int mvpp2_txq_sent_desc_proc(struct mvpp2_port *port,
struct mvpp2_tx_queue *txq)
{
u32 val;
/* Reading status reg resets transmitted descriptor counter */
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
val = mvpp2_percpu_read(port->priv, smp_processor_id(),
MVPP2_TXQ_SENT_REG(txq->id));
return (val & MVPP2_TRANSMITTED_COUNT_MASK) >>
MVPP2_TRANSMITTED_COUNT_OFFSET;
}
/* Called through on_each_cpu(), so runs on all CPUs, with migration
* disabled, therefore using smp_processor_id() is OK.
*/
static void mvpp2_txq_sent_counter_clear(void *arg)
{
struct mvpp2_port *port = arg;
int queue;
for (queue = 0; queue < port->ntxqs; queue++) {
int id = port->txqs[queue]->id;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_read(port->priv, smp_processor_id(),
MVPP2_TXQ_SENT_REG(id));
}
}
/* Set max sizes for Tx queues */
static void mvpp2_txp_max_tx_size_set(struct mvpp2_port *port)
{
u32 val, size, mtu;
int txq, tx_port_num;
mtu = port->pkt_size * 8;
if (mtu > MVPP2_TXP_MTU_MAX)
mtu = MVPP2_TXP_MTU_MAX;
/* WA for wrong Token bucket update: Set MTU value = 3*real MTU value */
mtu = 3 * mtu;
/* Indirect access to registers */
tx_port_num = mvpp2_egress_port(port);
mvpp2_write(port->priv, MVPP2_TXP_SCHED_PORT_INDEX_REG, tx_port_num);
/* Set MTU */
val = mvpp2_read(port->priv, MVPP2_TXP_SCHED_MTU_REG);
val &= ~MVPP2_TXP_MTU_MAX;
val |= mtu;
mvpp2_write(port->priv, MVPP2_TXP_SCHED_MTU_REG, val);
/* TXP token size and all TXQs token size must be larger that MTU */
val = mvpp2_read(port->priv, MVPP2_TXP_SCHED_TOKEN_SIZE_REG);
size = val & MVPP2_TXP_TOKEN_SIZE_MAX;
if (size < mtu) {
size = mtu;
val &= ~MVPP2_TXP_TOKEN_SIZE_MAX;
val |= size;
mvpp2_write(port->priv, MVPP2_TXP_SCHED_TOKEN_SIZE_REG, val);
}
for (txq = 0; txq < port->ntxqs; txq++) {
val = mvpp2_read(port->priv,
MVPP2_TXQ_SCHED_TOKEN_SIZE_REG(txq));
size = val & MVPP2_TXQ_TOKEN_SIZE_MAX;
if (size < mtu) {
size = mtu;
val &= ~MVPP2_TXQ_TOKEN_SIZE_MAX;
val |= size;
mvpp2_write(port->priv,
MVPP2_TXQ_SCHED_TOKEN_SIZE_REG(txq),
val);
}
}
}
/* Set the number of packets that will be received before Rx interrupt
* will be generated by HW.
*/
static void mvpp2_rx_pkts_coal_set(struct mvpp2_port *port,
struct mvpp2_rx_queue *rxq)
{
int cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
if (rxq->pkts_coal > MVPP2_OCCUPIED_THRESH_MASK)
rxq->pkts_coal = MVPP2_OCCUPIED_THRESH_MASK;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_NUM_REG, rxq->id);
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_THRESH_REG,
rxq->pkts_coal);
put_cpu();
}
/* For some reason in the LSP this is done on each CPU. Why ? */
static void mvpp2_tx_pkts_coal_set(struct mvpp2_port *port,
struct mvpp2_tx_queue *txq)
{
int cpu = get_cpu();
u32 val;
if (txq->done_pkts_coal > MVPP2_TXQ_THRESH_MASK)
txq->done_pkts_coal = MVPP2_TXQ_THRESH_MASK;
val = (txq->done_pkts_coal << MVPP2_TXQ_THRESH_OFFSET);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_NUM_REG, txq->id);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_THRESH_REG, val);
put_cpu();
}
static u32 mvpp2_usec_to_cycles(u32 usec, unsigned long clk_hz)
{
u64 tmp = (u64)clk_hz * usec;
do_div(tmp, USEC_PER_SEC);
return tmp > U32_MAX ? U32_MAX : tmp;
}
static u32 mvpp2_cycles_to_usec(u32 cycles, unsigned long clk_hz)
{
u64 tmp = (u64)cycles * USEC_PER_SEC;
do_div(tmp, clk_hz);
return tmp > U32_MAX ? U32_MAX : tmp;
}
/* Set the time delay in usec before Rx interrupt */
static void mvpp2_rx_time_coal_set(struct mvpp2_port *port,
struct mvpp2_rx_queue *rxq)
{
unsigned long freq = port->priv->tclk;
u32 val = mvpp2_usec_to_cycles(rxq->time_coal, freq);
if (val > MVPP2_MAX_ISR_RX_THRESHOLD) {
rxq->time_coal =
mvpp2_cycles_to_usec(MVPP2_MAX_ISR_RX_THRESHOLD, freq);
/* re-evaluate to get actual register value */
val = mvpp2_usec_to_cycles(rxq->time_coal, freq);
}
mvpp2_write(port->priv, MVPP2_ISR_RX_THRESHOLD_REG(rxq->id), val);
}
static void mvpp2_tx_time_coal_set(struct mvpp2_port *port)
{
unsigned long freq = port->priv->tclk;
u32 val = mvpp2_usec_to_cycles(port->tx_time_coal, freq);
if (val > MVPP2_MAX_ISR_TX_THRESHOLD) {
port->tx_time_coal =
mvpp2_cycles_to_usec(MVPP2_MAX_ISR_TX_THRESHOLD, freq);
/* re-evaluate to get actual register value */
val = mvpp2_usec_to_cycles(port->tx_time_coal, freq);
}
mvpp2_write(port->priv, MVPP2_ISR_TX_THRESHOLD_REG(port->id), val);
}
/* Free Tx queue skbuffs */
static void mvpp2_txq_bufs_free(struct mvpp2_port *port,
struct mvpp2_tx_queue *txq,
struct mvpp2_txq_pcpu *txq_pcpu, int num)
{
int i;
for (i = 0; i < num; i++) {
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
struct mvpp2_txq_pcpu_buf *tx_buf =
txq_pcpu->buffs + txq_pcpu->txq_get_index;
if (!IS_TSO_HEADER(txq_pcpu, tx_buf->dma))
dma_unmap_single(port->dev->dev.parent, tx_buf->dma,
tx_buf->size, DMA_TO_DEVICE);
if (tx_buf->skb)
dev_kfree_skb_any(tx_buf->skb);
mvpp2_txq_inc_get(txq_pcpu);
}
}
static inline struct mvpp2_rx_queue *mvpp2_get_rx_queue(struct mvpp2_port *port,
u32 cause)
{
int queue = fls(cause) - 1;
return port->rxqs[queue];
}
static inline struct mvpp2_tx_queue *mvpp2_get_tx_queue(struct mvpp2_port *port,
u32 cause)
{
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
int queue = fls(cause) - 1;
return port->txqs[queue];
}
/* Handle end of transmission */
static void mvpp2_txq_done(struct mvpp2_port *port, struct mvpp2_tx_queue *txq,
struct mvpp2_txq_pcpu *txq_pcpu)
{
struct netdev_queue *nq = netdev_get_tx_queue(port->dev, txq->log_id);
int tx_done;
if (txq_pcpu->cpu != smp_processor_id())
netdev_err(port->dev, "wrong cpu on the end of Tx processing\n");
tx_done = mvpp2_txq_sent_desc_proc(port, txq);
if (!tx_done)
return;
mvpp2_txq_bufs_free(port, txq, txq_pcpu, tx_done);
txq_pcpu->count -= tx_done;
if (netif_tx_queue_stopped(nq))
if (txq_pcpu->count <= txq_pcpu->wake_threshold)
netif_tx_wake_queue(nq);
}
static unsigned int mvpp2_tx_done(struct mvpp2_port *port, u32 cause,
int cpu)
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
{
struct mvpp2_tx_queue *txq;
struct mvpp2_txq_pcpu *txq_pcpu;
unsigned int tx_todo = 0;
while (cause) {
txq = mvpp2_get_tx_queue(port, cause);
if (!txq)
break;
txq_pcpu = per_cpu_ptr(txq->pcpu, cpu);
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
if (txq_pcpu->count) {
mvpp2_txq_done(port, txq, txq_pcpu);
tx_todo += txq_pcpu->count;
}
cause &= ~(1 << txq->log_id);
}
return tx_todo;
}
/* Rx/Tx queue initialization/cleanup methods */
/* Allocate and initialize descriptors for aggr TXQ */
static int mvpp2_aggr_txq_init(struct platform_device *pdev,
struct mvpp2_tx_queue *aggr_txq, int cpu,
struct mvpp2 *priv)
{
u32 txq_dma;
/* Allocate memory for TX descriptors */
aggr_txq->descs = dma_alloc_coherent(&pdev->dev,
MVPP2_AGGR_TXQ_SIZE * MVPP2_DESC_ALIGNED_SIZE,
&aggr_txq->descs_dma, GFP_KERNEL);
if (!aggr_txq->descs)
return -ENOMEM;
aggr_txq->last_desc = MVPP2_AGGR_TXQ_SIZE - 1;
/* Aggr TXQ no reset WA */
aggr_txq->next_desc_to_proc = mvpp2_read(priv,
MVPP2_AGGR_TXQ_INDEX_REG(cpu));
/* Set Tx descriptors queue starting address indirect
* access
*/
if (priv->hw_version == MVPP21)
txq_dma = aggr_txq->descs_dma;
else
txq_dma = aggr_txq->descs_dma >>
MVPP22_AGGR_TXQ_DESC_ADDR_OFFS;
mvpp2_write(priv, MVPP2_AGGR_TXQ_DESC_ADDR_REG(cpu), txq_dma);
mvpp2_write(priv, MVPP2_AGGR_TXQ_DESC_SIZE_REG(cpu),
MVPP2_AGGR_TXQ_SIZE);
return 0;
}
/* Create a specified Rx queue */
static int mvpp2_rxq_init(struct mvpp2_port *port,
struct mvpp2_rx_queue *rxq)
{
u32 rxq_dma;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
int cpu;
rxq->size = port->rx_ring_size;
/* Allocate memory for RX descriptors */
rxq->descs = dma_alloc_coherent(port->dev->dev.parent,
rxq->size * MVPP2_DESC_ALIGNED_SIZE,
&rxq->descs_dma, GFP_KERNEL);
if (!rxq->descs)
return -ENOMEM;
rxq->last_desc = rxq->size - 1;
/* Zero occupied and non-occupied counters - direct access */
mvpp2_write(port->priv, MVPP2_RXQ_STATUS_REG(rxq->id), 0);
/* Set Rx descriptors queue starting address - indirect access */
cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_NUM_REG, rxq->id);
if (port->priv->hw_version == MVPP21)
rxq_dma = rxq->descs_dma;
else
rxq_dma = rxq->descs_dma >> MVPP22_DESC_ADDR_OFFS;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_DESC_ADDR_REG, rxq_dma);
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_DESC_SIZE_REG, rxq->size);
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_INDEX_REG, 0);
put_cpu();
/* Set Offset */
mvpp2_rxq_offset_set(port, rxq->id, NET_SKB_PAD);
/* Set coalescing pkts and time */
mvpp2_rx_pkts_coal_set(port, rxq);
mvpp2_rx_time_coal_set(port, rxq);
/* Add number of descriptors ready for receiving packets */
mvpp2_rxq_status_update(port, rxq->id, 0, rxq->size);
return 0;
}
/* Push packets received by the RXQ to BM pool */
static void mvpp2_rxq_drop_pkts(struct mvpp2_port *port,
struct mvpp2_rx_queue *rxq)
{
int rx_received, i;
rx_received = mvpp2_rxq_received(port, rxq->id);
if (!rx_received)
return;
for (i = 0; i < rx_received; i++) {
struct mvpp2_rx_desc *rx_desc = mvpp2_rxq_next_desc_get(rxq);
u32 status = mvpp2_rxdesc_status_get(port, rx_desc);
int pool;
pool = (status & MVPP2_RXD_BM_POOL_ID_MASK) >>
MVPP2_RXD_BM_POOL_ID_OFFS;
mvpp2_bm_pool_put(port, pool,
mvpp2_rxdesc_dma_addr_get(port, rx_desc),
mvpp2_rxdesc_cookie_get(port, rx_desc));
}
mvpp2_rxq_status_update(port, rxq->id, rx_received, rx_received);
}
/* Cleanup Rx queue */
static void mvpp2_rxq_deinit(struct mvpp2_port *port,
struct mvpp2_rx_queue *rxq)
{
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
int cpu;
mvpp2_rxq_drop_pkts(port, rxq);
if (rxq->descs)
dma_free_coherent(port->dev->dev.parent,
rxq->size * MVPP2_DESC_ALIGNED_SIZE,
rxq->descs,
rxq->descs_dma);
rxq->descs = NULL;
rxq->last_desc = 0;
rxq->next_desc_to_proc = 0;
rxq->descs_dma = 0;
/* Clear Rx descriptors queue starting address and size;
* free descriptor number
*/
mvpp2_write(port->priv, MVPP2_RXQ_STATUS_REG(rxq->id), 0);
cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_NUM_REG, rxq->id);
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_DESC_ADDR_REG, 0);
mvpp2_percpu_write(port->priv, cpu, MVPP2_RXQ_DESC_SIZE_REG, 0);
put_cpu();
}
/* Create and initialize a Tx queue */
static int mvpp2_txq_init(struct mvpp2_port *port,
struct mvpp2_tx_queue *txq)
{
u32 val;
int cpu, desc, desc_per_txq, tx_port_num;
struct mvpp2_txq_pcpu *txq_pcpu;
txq->size = port->tx_ring_size;
/* Allocate memory for Tx descriptors */
txq->descs = dma_alloc_coherent(port->dev->dev.parent,
txq->size * MVPP2_DESC_ALIGNED_SIZE,
&txq->descs_dma, GFP_KERNEL);
if (!txq->descs)
return -ENOMEM;
txq->last_desc = txq->size - 1;
/* Set Tx descriptors queue starting address - indirect access */
cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_NUM_REG, txq->id);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_DESC_ADDR_REG,
txq->descs_dma);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_DESC_SIZE_REG,
txq->size & MVPP2_TXQ_DESC_SIZE_MASK);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_INDEX_REG, 0);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_RSVD_CLR_REG,
txq->id << MVPP2_TXQ_RSVD_CLR_OFFSET);
val = mvpp2_percpu_read(port->priv, cpu, MVPP2_TXQ_PENDING_REG);
val &= ~MVPP2_TXQ_PENDING_MASK;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_PENDING_REG, val);
/* Calculate base address in prefetch buffer. We reserve 16 descriptors
* for each existing TXQ.
* TCONTS for PON port must be continuous from 0 to MVPP2_MAX_TCONT
* GBE ports assumed to be continious from 0 to MVPP2_MAX_PORTS
*/
desc_per_txq = 16;
desc = (port->id * MVPP2_MAX_TXQ * desc_per_txq) +
(txq->log_id * desc_per_txq);
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_PREF_BUF_REG,
MVPP2_PREF_BUF_PTR(desc) | MVPP2_PREF_BUF_SIZE_16 |
MVPP2_PREF_BUF_THRESH(desc_per_txq / 2));
put_cpu();
/* WRR / EJP configuration - indirect access */
tx_port_num = mvpp2_egress_port(port);
mvpp2_write(port->priv, MVPP2_TXP_SCHED_PORT_INDEX_REG, tx_port_num);
val = mvpp2_read(port->priv, MVPP2_TXQ_SCHED_REFILL_REG(txq->log_id));
val &= ~MVPP2_TXQ_REFILL_PERIOD_ALL_MASK;
val |= MVPP2_TXQ_REFILL_PERIOD_MASK(1);
val |= MVPP2_TXQ_REFILL_TOKENS_ALL_MASK;
mvpp2_write(port->priv, MVPP2_TXQ_SCHED_REFILL_REG(txq->log_id), val);
val = MVPP2_TXQ_TOKEN_SIZE_MAX;
mvpp2_write(port->priv, MVPP2_TXQ_SCHED_TOKEN_SIZE_REG(txq->log_id),
val);
for_each_present_cpu(cpu) {
txq_pcpu = per_cpu_ptr(txq->pcpu, cpu);
txq_pcpu->size = txq->size;
txq_pcpu->buffs = kmalloc_array(txq_pcpu->size,
sizeof(*txq_pcpu->buffs),
GFP_KERNEL);
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
if (!txq_pcpu->buffs)
goto cleanup;
txq_pcpu->count = 0;
txq_pcpu->reserved_num = 0;
txq_pcpu->txq_put_index = 0;
txq_pcpu->txq_get_index = 0;
txq_pcpu->stop_threshold = txq->size - MVPP2_MAX_SKB_DESCS;
txq_pcpu->wake_threshold = txq_pcpu->stop_threshold / 2;
txq_pcpu->tso_headers =
dma_alloc_coherent(port->dev->dev.parent,
txq_pcpu->size * TSO_HEADER_SIZE,
&txq_pcpu->tso_headers_dma,
GFP_KERNEL);
if (!txq_pcpu->tso_headers)
goto cleanup;
}
return 0;
cleanup:
for_each_present_cpu(cpu) {
txq_pcpu = per_cpu_ptr(txq->pcpu, cpu);
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
kfree(txq_pcpu->buffs);
dma_free_coherent(port->dev->dev.parent,
txq_pcpu->size * TSO_HEADER_SIZE,
txq_pcpu->tso_headers,
txq_pcpu->tso_headers_dma);
}
dma_free_coherent(port->dev->dev.parent,
txq->size * MVPP2_DESC_ALIGNED_SIZE,
txq->descs, txq->descs_dma);
return -ENOMEM;
}
/* Free allocated TXQ resources */
static void mvpp2_txq_deinit(struct mvpp2_port *port,
struct mvpp2_tx_queue *txq)
{
struct mvpp2_txq_pcpu *txq_pcpu;
int cpu;
for_each_present_cpu(cpu) {
txq_pcpu = per_cpu_ptr(txq->pcpu, cpu);
net: mvpp2: fix dma unmapping of TX buffers for fragments Since commit 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping"), we are not correctly DMA unmapping TX buffers for fragments. Indeed, the mvpp2_txq_inc_put() function only stores in the txq_cpu->tx_buffs[] array the physical address of the buffer to be DMA-unmapped when skb != NULL. In addition, when DMA-unmapping, we use skb_headlen(skb) to get the size to be unmapped. Both of this works fine for TX descriptors that are associated directly to a SKB, but not the ones that are used for fragments, with a NULL pointer as skb: - We have a NULL physical address when calling DMA unmap - skb_headlen(skb) crashes because skb is NULL This causes random crashes when fragments are used. To solve this problem, we need to: - Store the physical address of the buffer to be unmapped unconditionally, regardless of whether it is tied to a SKB or not. - Store the length of the buffer to be unmapped, which requires a new field. Instead of adding a third array to store the length of the buffer to be unmapped, and as suggested by David Miller, this commit refactors the tx_buffs[] and tx_skb[] arrays of 'struct mvpp2_txq_pcpu' into a separate structure 'mvpp2_txq_pcpu_buf', to which a 'size' field is added. Therefore, instead of having three arrays to allocate/free, we have a single one, which also improve data locality, reducing the impact on the CPU cache. Fixes: 71ce391dfb784 ("net: mvpp2: enable proper per-CPU TX buffers unmapping") Reported-by: Raphael G <raphael.glon@corp.ovh.com> Cc: Raphael G <raphael.glon@corp.ovh.com> Cc: stable@vger.kernel.org Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2016-12-21 18:28:49 +08:00
kfree(txq_pcpu->buffs);
dma_free_coherent(port->dev->dev.parent,
txq_pcpu->size * TSO_HEADER_SIZE,
txq_pcpu->tso_headers,
txq_pcpu->tso_headers_dma);
}
if (txq->descs)
dma_free_coherent(port->dev->dev.parent,
txq->size * MVPP2_DESC_ALIGNED_SIZE,
txq->descs, txq->descs_dma);
txq->descs = NULL;
txq->last_desc = 0;
txq->next_desc_to_proc = 0;
txq->descs_dma = 0;
/* Set minimum bandwidth for disabled TXQs */
mvpp2_write(port->priv, MVPP2_TXQ_SCHED_TOKEN_CNTR_REG(txq->id), 0);
/* Set Tx descriptors queue starting address and size */
cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_NUM_REG, txq->id);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_DESC_ADDR_REG, 0);
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_DESC_SIZE_REG, 0);
put_cpu();
}
/* Cleanup Tx ports */
static void mvpp2_txq_clean(struct mvpp2_port *port, struct mvpp2_tx_queue *txq)
{
struct mvpp2_txq_pcpu *txq_pcpu;
int delay, pending, cpu;
u32 val;
cpu = get_cpu();
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_NUM_REG, txq->id);
val = mvpp2_percpu_read(port->priv, cpu, MVPP2_TXQ_PREF_BUF_REG);
val |= MVPP2_TXQ_DRAIN_EN_MASK;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_PREF_BUF_REG, val);
/* The napi queue has been stopped so wait for all packets
* to be transmitted.
*/
delay = 0;
do {
if (delay >= MVPP2_TX_PENDING_TIMEOUT_MSEC) {
netdev_warn(port->dev,
"port %d: cleaning queue %d timed out\n",
port->id, txq->log_id);
break;
}
mdelay(1);
delay++;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
pending = mvpp2_percpu_read(port->priv, cpu,
MVPP2_TXQ_PENDING_REG);
pending &= MVPP2_TXQ_PENDING_MASK;
} while (pending);
val &= ~MVPP2_TXQ_DRAIN_EN_MASK;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu, MVPP2_TXQ_PREF_BUF_REG, val);
put_cpu();
for_each_present_cpu(cpu) {
txq_pcpu = per_cpu_ptr(txq->pcpu, cpu);
/* Release all packets */
mvpp2_txq_bufs_free(port, txq, txq_pcpu, txq_pcpu->count);
/* Reset queue */
txq_pcpu->count = 0;
txq_pcpu->txq_put_index = 0;
txq_pcpu->txq_get_index = 0;
}
}
/* Cleanup all Tx queues */
static void mvpp2_cleanup_txqs(struct mvpp2_port *port)
{
struct mvpp2_tx_queue *txq;
int queue;
u32 val;
val = mvpp2_read(port->priv, MVPP2_TX_PORT_FLUSH_REG);
/* Reset Tx ports and delete Tx queues */
val |= MVPP2_TX_PORT_FLUSH_MASK(port->id);
mvpp2_write(port->priv, MVPP2_TX_PORT_FLUSH_REG, val);
for (queue = 0; queue < port->ntxqs; queue++) {
txq = port->txqs[queue];
mvpp2_txq_clean(port, txq);
mvpp2_txq_deinit(port, txq);
}
on_each_cpu(mvpp2_txq_sent_counter_clear, port, 1);
val &= ~MVPP2_TX_PORT_FLUSH_MASK(port->id);
mvpp2_write(port->priv, MVPP2_TX_PORT_FLUSH_REG, val);
}
/* Cleanup all Rx queues */
static void mvpp2_cleanup_rxqs(struct mvpp2_port *port)
{
int queue;
for (queue = 0; queue < port->nrxqs; queue++)
mvpp2_rxq_deinit(port, port->rxqs[queue]);
}
/* Init all Rx queues for port */
static int mvpp2_setup_rxqs(struct mvpp2_port *port)
{
int queue, err;
for (queue = 0; queue < port->nrxqs; queue++) {
err = mvpp2_rxq_init(port, port->rxqs[queue]);
if (err)
goto err_cleanup;
}
return 0;
err_cleanup:
mvpp2_cleanup_rxqs(port);
return err;
}
/* Init all tx queues for port */
static int mvpp2_setup_txqs(struct mvpp2_port *port)
{
struct mvpp2_tx_queue *txq;
int queue, err;
for (queue = 0; queue < port->ntxqs; queue++) {
txq = port->txqs[queue];
err = mvpp2_txq_init(port, txq);
if (err)
goto err_cleanup;
}
if (port->has_tx_irqs) {
mvpp2_tx_time_coal_set(port);
for (queue = 0; queue < port->ntxqs; queue++) {
txq = port->txqs[queue];
mvpp2_tx_pkts_coal_set(port, txq);
}
}
on_each_cpu(mvpp2_txq_sent_counter_clear, port, 1);
return 0;
err_cleanup:
mvpp2_cleanup_txqs(port);
return err;
}
/* The callback for per-port interrupt */
static irqreturn_t mvpp2_isr(int irq, void *dev_id)
{
struct mvpp2_queue_vector *qv = dev_id;
mvpp2_qvec_interrupt_disable(qv);
napi_schedule(&qv->napi);
return IRQ_HANDLED;
}
/* Per-port interrupt for link status changes */
static irqreturn_t mvpp2_link_status_isr(int irq, void *dev_id)
{
struct mvpp2_port *port = (struct mvpp2_port *)dev_id;
struct net_device *dev = port->dev;
bool event = false, link = false;
u32 val;
mvpp22_gop_mask_irq(port);
if (port->gop_id == 0 &&
port->phy_interface == PHY_INTERFACE_MODE_10GKR) {
val = readl(port->base + MVPP22_XLG_INT_STAT);
if (val & MVPP22_XLG_INT_STAT_LINK) {
event = true;
val = readl(port->base + MVPP22_XLG_STATUS);
if (val & MVPP22_XLG_STATUS_LINK_UP)
link = true;
}
} else if (phy_interface_mode_is_rgmii(port->phy_interface) ||
port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
val = readl(port->base + MVPP22_GMAC_INT_STAT);
if (val & MVPP22_GMAC_INT_STAT_LINK) {
event = true;
val = readl(port->base + MVPP2_GMAC_STATUS0);
if (val & MVPP2_GMAC_STATUS0_LINK_UP)
link = true;
}
}
if (!netif_running(dev) || !event)
goto handled;
if (link) {
mvpp2_interrupts_enable(port);
mvpp2_egress_enable(port);
mvpp2_ingress_enable(port);
netif_carrier_on(dev);
netif_tx_wake_all_queues(dev);
} else {
netif_tx_stop_all_queues(dev);
netif_carrier_off(dev);
mvpp2_ingress_disable(port);
mvpp2_egress_disable(port);
mvpp2_interrupts_disable(port);
}
handled:
mvpp22_gop_unmask_irq(port);
return IRQ_HANDLED;
}
static void mvpp2_gmac_set_autoneg(struct mvpp2_port *port,
struct phy_device *phydev)
{
u32 val;
if (port->phy_interface != PHY_INTERFACE_MODE_RGMII &&
port->phy_interface != PHY_INTERFACE_MODE_RGMII_ID &&
port->phy_interface != PHY_INTERFACE_MODE_RGMII_RXID &&
port->phy_interface != PHY_INTERFACE_MODE_RGMII_TXID &&
port->phy_interface != PHY_INTERFACE_MODE_SGMII)
return;
val = readl(port->base + MVPP2_GMAC_AUTONEG_CONFIG);
val &= ~(MVPP2_GMAC_CONFIG_MII_SPEED |
MVPP2_GMAC_CONFIG_GMII_SPEED |
MVPP2_GMAC_CONFIG_FULL_DUPLEX |
MVPP2_GMAC_AN_SPEED_EN |
MVPP2_GMAC_AN_DUPLEX_EN);
if (phydev->duplex)
val |= MVPP2_GMAC_CONFIG_FULL_DUPLEX;
if (phydev->speed == SPEED_1000)
val |= MVPP2_GMAC_CONFIG_GMII_SPEED;
else if (phydev->speed == SPEED_100)
val |= MVPP2_GMAC_CONFIG_MII_SPEED;
writel(val, port->base + MVPP2_GMAC_AUTONEG_CONFIG);
}
/* Adjust link */
static void mvpp2_link_event(struct net_device *dev)
{
struct mvpp2_port *port = netdev_priv(dev);
struct phy_device *phydev = dev->phydev;
bool link_reconfigured = false;
u32 val;
if (phydev->link) {
if (port->phy_interface != phydev->interface && port->comphy) {
/* disable current port for reconfiguration */
mvpp2_interrupts_disable(port);
netif_carrier_off(port->dev);
mvpp2_port_disable(port);
phy_power_off(port->comphy);
/* comphy reconfiguration */
port->phy_interface = phydev->interface;
mvpp22_comphy_init(port);
/* gop/mac reconfiguration */
mvpp22_gop_init(port);
mvpp2_port_mii_set(port);
link_reconfigured = true;
}
if ((port->speed != phydev->speed) ||
(port->duplex != phydev->duplex)) {
mvpp2_gmac_set_autoneg(port, phydev);
port->duplex = phydev->duplex;
port->speed = phydev->speed;
}
}
if (phydev->link != port->link || link_reconfigured) {
port->link = phydev->link;
if (phydev->link) {
if (port->phy_interface == PHY_INTERFACE_MODE_RGMII ||
port->phy_interface == PHY_INTERFACE_MODE_RGMII_ID ||
port->phy_interface == PHY_INTERFACE_MODE_RGMII_RXID ||
port->phy_interface == PHY_INTERFACE_MODE_RGMII_TXID ||
port->phy_interface == PHY_INTERFACE_MODE_SGMII) {
val = readl(port->base + MVPP2_GMAC_AUTONEG_CONFIG);
val |= (MVPP2_GMAC_FORCE_LINK_PASS |
MVPP2_GMAC_FORCE_LINK_DOWN);
writel(val, port->base + MVPP2_GMAC_AUTONEG_CONFIG);
}
mvpp2_interrupts_enable(port);
mvpp2_port_enable(port);
mvpp2_egress_enable(port);
mvpp2_ingress_enable(port);
netif_carrier_on(dev);
netif_tx_wake_all_queues(dev);
} else {
port->duplex = -1;
port->speed = 0;
netif_tx_stop_all_queues(dev);
netif_carrier_off(dev);
mvpp2_ingress_disable(port);
mvpp2_egress_disable(port);
mvpp2_port_disable(port);
mvpp2_interrupts_disable(port);
}
phy_print_status(phydev);
}
}
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
static void mvpp2_timer_set(struct mvpp2_port_pcpu *port_pcpu)
{
ktime_t interval;
if (!port_pcpu->timer_scheduled) {
port_pcpu->timer_scheduled = true;
interval = MVPP2_TXDONE_HRTIMER_PERIOD_NS;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
hrtimer_start(&port_pcpu->tx_done_timer, interval,
HRTIMER_MODE_REL_PINNED);
}
}
static void mvpp2_tx_proc_cb(unsigned long data)
{
struct net_device *dev = (struct net_device *)data;
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2_port_pcpu *port_pcpu = this_cpu_ptr(port->pcpu);
unsigned int tx_todo, cause;
if (!netif_running(dev))
return;
port_pcpu->timer_scheduled = false;
/* Process all the Tx queues */
cause = (1 << port->ntxqs) - 1;
tx_todo = mvpp2_tx_done(port, cause, smp_processor_id());
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
/* Set the timer in case not all the packets were processed */
if (tx_todo)
mvpp2_timer_set(port_pcpu);
}
static enum hrtimer_restart mvpp2_hr_timer_cb(struct hrtimer *timer)
{
struct mvpp2_port_pcpu *port_pcpu = container_of(timer,
struct mvpp2_port_pcpu,
tx_done_timer);
tasklet_schedule(&port_pcpu->tx_done_tasklet);
return HRTIMER_NORESTART;
}
/* Main RX/TX processing routines */
/* Display more error info */
static void mvpp2_rx_error(struct mvpp2_port *port,
struct mvpp2_rx_desc *rx_desc)
{
u32 status = mvpp2_rxdesc_status_get(port, rx_desc);
size_t sz = mvpp2_rxdesc_size_get(port, rx_desc);
switch (status & MVPP2_RXD_ERR_CODE_MASK) {
case MVPP2_RXD_ERR_CRC:
netdev_err(port->dev, "bad rx status %08x (crc error), size=%zu\n",
status, sz);
break;
case MVPP2_RXD_ERR_OVERRUN:
netdev_err(port->dev, "bad rx status %08x (overrun error), size=%zu\n",
status, sz);
break;
case MVPP2_RXD_ERR_RESOURCE:
netdev_err(port->dev, "bad rx status %08x (resource error), size=%zu\n",
status, sz);
break;
}
}
/* Handle RX checksum offload */
static void mvpp2_rx_csum(struct mvpp2_port *port, u32 status,
struct sk_buff *skb)
{
if (((status & MVPP2_RXD_L3_IP4) &&
!(status & MVPP2_RXD_IP4_HEADER_ERR)) ||
(status & MVPP2_RXD_L3_IP6))
if (((status & MVPP2_RXD_L4_UDP) ||
(status & MVPP2_RXD_L4_TCP)) &&
(status & MVPP2_RXD_L4_CSUM_OK)) {
skb->csum = 0;
skb->ip_summed = CHECKSUM_UNNECESSARY;
return;
}
skb->ip_summed = CHECKSUM_NONE;
}
/* Reuse skb if possible, or allocate a new skb and add it to BM pool */
static int mvpp2_rx_refill(struct mvpp2_port *port,
struct mvpp2_bm_pool *bm_pool, int pool)
{
dma_addr_t dma_addr;
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
phys_addr_t phys_addr;
void *buf;
/* No recycle or too many buffers are in use, so allocate a new skb */
net: mvpp2: store physical address of buffer in rx_desc->buf_cookie The RX descriptors of the PPv2 hardware allow to store several information, amongst which: - the DMA address of the buffer in which the data has been received - a "cookie" field, left to the use of the driver, and not used by the hardware In the current implementation, the "cookie" field is used to store the virtual address of the buffer, so that in the receive completion path, we can easily get the virtual address of the buffer that corresponds to a completed RX descriptors. On PPv2.1, used on 32-bit platforms, those two fields are 32-bit wide, which is enough to store a DMA address in the first field, and a virtual address in the second field. On PPv2.2, used on 64-bit platforms, these two fields have been extended to 40 bits. While 40 bits is enough to store a DMA address (as long as the DMA mask is 40 bits or lower), it is not enough to store a virtual address. Therefore, the "cookie" field can no longer be used to store the virtual address of the buffer. However, as Russell King pointed out, the RX buffers are always allocated in the kernel linear mapping, and therefore using phys_to_virt() on the physical address of the RX buffer is possible and correct. Therefore, this commit changes the driver to use the "cookie" field to store the physical address instead of the virtual address. phys_to_virt() is used in the receive completion path to retrieve the virtual address from the physical address. It is obviously important to realize that the DMA address and physical address are two different things, which is why we store both in the RX descriptors. While those addresses may be identical in some situations, it remains two distinct concepts, and both addresses should be handled separately. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:04 +08:00
buf = mvpp2_buf_alloc(port, bm_pool, &dma_addr, &phys_addr,
GFP_ATOMIC);
if (!buf)
return -ENOMEM;
mvpp2_bm_pool_put(port, pool, dma_addr, phys_addr);
return 0;
}
/* Handle tx checksum */
static u32 mvpp2_skb_tx_csum(struct mvpp2_port *port, struct sk_buff *skb)
{
if (skb->ip_summed == CHECKSUM_PARTIAL) {
int ip_hdr_len = 0;
u8 l4_proto;
if (skb->protocol == htons(ETH_P_IP)) {
struct iphdr *ip4h = ip_hdr(skb);
/* Calculate IPv4 checksum and L4 checksum */
ip_hdr_len = ip4h->ihl;
l4_proto = ip4h->protocol;
} else if (skb->protocol == htons(ETH_P_IPV6)) {
struct ipv6hdr *ip6h = ipv6_hdr(skb);
/* Read l4_protocol from one of IPv6 extra headers */
if (skb_network_header_len(skb) > 0)
ip_hdr_len = (skb_network_header_len(skb) >> 2);
l4_proto = ip6h->nexthdr;
} else {
return MVPP2_TXD_L4_CSUM_NOT;
}
return mvpp2_txq_desc_csum(skb_network_offset(skb),
skb->protocol, ip_hdr_len, l4_proto);
}
return MVPP2_TXD_L4_CSUM_NOT | MVPP2_TXD_IP_CSUM_DISABLE;
}
/* Main rx processing */
static int mvpp2_rx(struct mvpp2_port *port, struct napi_struct *napi,
int rx_todo, struct mvpp2_rx_queue *rxq)
{
struct net_device *dev = port->dev;
int rx_received;
int rx_done = 0;
u32 rcvd_pkts = 0;
u32 rcvd_bytes = 0;
/* Get number of received packets and clamp the to-do */
rx_received = mvpp2_rxq_received(port, rxq->id);
if (rx_todo > rx_received)
rx_todo = rx_received;
while (rx_done < rx_todo) {
struct mvpp2_rx_desc *rx_desc = mvpp2_rxq_next_desc_get(rxq);
struct mvpp2_bm_pool *bm_pool;
struct sk_buff *skb;
unsigned int frag_size;
dma_addr_t dma_addr;
phys_addr_t phys_addr;
u32 rx_status;
int pool, rx_bytes, err;
void *data;
rx_done++;
rx_status = mvpp2_rxdesc_status_get(port, rx_desc);
rx_bytes = mvpp2_rxdesc_size_get(port, rx_desc);
rx_bytes -= MVPP2_MH_SIZE;
dma_addr = mvpp2_rxdesc_dma_addr_get(port, rx_desc);
phys_addr = mvpp2_rxdesc_cookie_get(port, rx_desc);
data = (void *)phys_to_virt(phys_addr);
pool = (rx_status & MVPP2_RXD_BM_POOL_ID_MASK) >>
MVPP2_RXD_BM_POOL_ID_OFFS;
bm_pool = &port->priv->bm_pools[pool];
/* In case of an error, release the requested buffer pointer
* to the Buffer Manager. This request process is controlled
* by the hardware, and the information about the buffer is
* comprised by the RX descriptor.
*/
if (rx_status & MVPP2_RXD_ERR_SUMMARY) {
err_drop_frame:
dev->stats.rx_errors++;
mvpp2_rx_error(port, rx_desc);
/* Return the buffer to the pool */
mvpp2_bm_pool_put(port, pool, dma_addr, phys_addr);
continue;
}
if (bm_pool->frag_size > PAGE_SIZE)
frag_size = 0;
else
frag_size = bm_pool->frag_size;
skb = build_skb(data, frag_size);
if (!skb) {
netdev_warn(port->dev, "skb build failed\n");
goto err_drop_frame;
}
err = mvpp2_rx_refill(port, bm_pool, pool);
if (err) {
netdev_err(port->dev, "failed to refill BM pools\n");
goto err_drop_frame;
}
dma_unmap_single(dev->dev.parent, dma_addr,
bm_pool->buf_size, DMA_FROM_DEVICE);
rcvd_pkts++;
rcvd_bytes += rx_bytes;
skb_reserve(skb, MVPP2_MH_SIZE + NET_SKB_PAD);
skb_put(skb, rx_bytes);
skb->protocol = eth_type_trans(skb, dev);
mvpp2_rx_csum(port, rx_status, skb);
napi_gro_receive(napi, skb);
}
if (rcvd_pkts) {
struct mvpp2_pcpu_stats *stats = this_cpu_ptr(port->stats);
u64_stats_update_begin(&stats->syncp);
stats->rx_packets += rcvd_pkts;
stats->rx_bytes += rcvd_bytes;
u64_stats_update_end(&stats->syncp);
}
/* Update Rx queue management counters */
wmb();
mvpp2_rxq_status_update(port, rxq->id, rx_done, rx_done);
return rx_todo;
}
static inline void
tx_desc_unmap_put(struct mvpp2_port *port, struct mvpp2_tx_queue *txq,
struct mvpp2_tx_desc *desc)
{
struct mvpp2_txq_pcpu *txq_pcpu = this_cpu_ptr(txq->pcpu);
dma_addr_t buf_dma_addr =
mvpp2_txdesc_dma_addr_get(port, desc);
size_t buf_sz =
mvpp2_txdesc_size_get(port, desc);
if (!IS_TSO_HEADER(txq_pcpu, buf_dma_addr))
dma_unmap_single(port->dev->dev.parent, buf_dma_addr,
buf_sz, DMA_TO_DEVICE);
mvpp2_txq_desc_put(txq);
}
/* Handle tx fragmentation processing */
static int mvpp2_tx_frag_process(struct mvpp2_port *port, struct sk_buff *skb,
struct mvpp2_tx_queue *aggr_txq,
struct mvpp2_tx_queue *txq)
{
struct mvpp2_txq_pcpu *txq_pcpu = this_cpu_ptr(txq->pcpu);
struct mvpp2_tx_desc *tx_desc;
int i;
dma_addr_t buf_dma_addr;
for (i = 0; i < skb_shinfo(skb)->nr_frags; i++) {
skb_frag_t *frag = &skb_shinfo(skb)->frags[i];
void *addr = page_address(frag->page.p) + frag->page_offset;
tx_desc = mvpp2_txq_next_desc_get(aggr_txq);
mvpp2_txdesc_txq_set(port, tx_desc, txq->id);
mvpp2_txdesc_size_set(port, tx_desc, frag->size);
buf_dma_addr = dma_map_single(port->dev->dev.parent, addr,
frag->size,
DMA_TO_DEVICE);
if (dma_mapping_error(port->dev->dev.parent, buf_dma_addr)) {
mvpp2_txq_desc_put(txq);
goto cleanup;
}
mvpp2_txdesc_dma_addr_set(port, tx_desc, buf_dma_addr);
if (i == (skb_shinfo(skb)->nr_frags - 1)) {
/* Last descriptor */
mvpp2_txdesc_cmd_set(port, tx_desc,
MVPP2_TXD_L_DESC);
mvpp2_txq_inc_put(port, txq_pcpu, skb, tx_desc);
} else {
/* Descriptor in the middle: Not First, Not Last */
mvpp2_txdesc_cmd_set(port, tx_desc, 0);
mvpp2_txq_inc_put(port, txq_pcpu, NULL, tx_desc);
}
}
return 0;
cleanup:
/* Release all descriptors that were used to map fragments of
* this packet, as well as the corresponding DMA mappings
*/
for (i = i - 1; i >= 0; i--) {
tx_desc = txq->descs + i;
tx_desc_unmap_put(port, txq, tx_desc);
}
return -ENOMEM;
}
static inline void mvpp2_tso_put_hdr(struct sk_buff *skb,
struct net_device *dev,
struct mvpp2_tx_queue *txq,
struct mvpp2_tx_queue *aggr_txq,
struct mvpp2_txq_pcpu *txq_pcpu,
int hdr_sz)
{
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2_tx_desc *tx_desc = mvpp2_txq_next_desc_get(aggr_txq);
dma_addr_t addr;
mvpp2_txdesc_txq_set(port, tx_desc, txq->id);
mvpp2_txdesc_size_set(port, tx_desc, hdr_sz);
addr = txq_pcpu->tso_headers_dma +
txq_pcpu->txq_put_index * TSO_HEADER_SIZE;
mvpp2_txdesc_dma_addr_set(port, tx_desc, addr);
mvpp2_txdesc_cmd_set(port, tx_desc, mvpp2_skb_tx_csum(port, skb) |
MVPP2_TXD_F_DESC |
MVPP2_TXD_PADDING_DISABLE);
mvpp2_txq_inc_put(port, txq_pcpu, NULL, tx_desc);
}
static inline int mvpp2_tso_put_data(struct sk_buff *skb,
struct net_device *dev, struct tso_t *tso,
struct mvpp2_tx_queue *txq,
struct mvpp2_tx_queue *aggr_txq,
struct mvpp2_txq_pcpu *txq_pcpu,
int sz, bool left, bool last)
{
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2_tx_desc *tx_desc = mvpp2_txq_next_desc_get(aggr_txq);
dma_addr_t buf_dma_addr;
mvpp2_txdesc_txq_set(port, tx_desc, txq->id);
mvpp2_txdesc_size_set(port, tx_desc, sz);
buf_dma_addr = dma_map_single(dev->dev.parent, tso->data, sz,
DMA_TO_DEVICE);
if (unlikely(dma_mapping_error(dev->dev.parent, buf_dma_addr))) {
mvpp2_txq_desc_put(txq);
return -ENOMEM;
}
mvpp2_txdesc_dma_addr_set(port, tx_desc, buf_dma_addr);
if (!left) {
mvpp2_txdesc_cmd_set(port, tx_desc, MVPP2_TXD_L_DESC);
if (last) {
mvpp2_txq_inc_put(port, txq_pcpu, skb, tx_desc);
return 0;
}
} else {
mvpp2_txdesc_cmd_set(port, tx_desc, 0);
}
mvpp2_txq_inc_put(port, txq_pcpu, NULL, tx_desc);
return 0;
}
static int mvpp2_tx_tso(struct sk_buff *skb, struct net_device *dev,
struct mvpp2_tx_queue *txq,
struct mvpp2_tx_queue *aggr_txq,
struct mvpp2_txq_pcpu *txq_pcpu)
{
struct mvpp2_port *port = netdev_priv(dev);
struct tso_t tso;
int hdr_sz = skb_transport_offset(skb) + tcp_hdrlen(skb);
int i, len, descs = 0;
/* Check number of available descriptors */
if (mvpp2_aggr_desc_num_check(port->priv, aggr_txq,
tso_count_descs(skb)) ||
mvpp2_txq_reserved_desc_num_proc(port->priv, txq, txq_pcpu,
tso_count_descs(skb)))
return 0;
tso_start(skb, &tso);
len = skb->len - hdr_sz;
while (len > 0) {
int left = min_t(int, skb_shinfo(skb)->gso_size, len);
char *hdr = txq_pcpu->tso_headers +
txq_pcpu->txq_put_index * TSO_HEADER_SIZE;
len -= left;
descs++;
tso_build_hdr(skb, hdr, &tso, left, len == 0);
mvpp2_tso_put_hdr(skb, dev, txq, aggr_txq, txq_pcpu, hdr_sz);
while (left > 0) {
int sz = min_t(int, tso.size, left);
left -= sz;
descs++;
if (mvpp2_tso_put_data(skb, dev, &tso, txq, aggr_txq,
txq_pcpu, sz, left, len == 0))
goto release;
tso_build_data(skb, &tso, sz);
}
}
return descs;
release:
for (i = descs - 1; i >= 0; i--) {
struct mvpp2_tx_desc *tx_desc = txq->descs + i;
tx_desc_unmap_put(port, txq, tx_desc);
}
return 0;
}
/* Main tx processing */
static int mvpp2_tx(struct sk_buff *skb, struct net_device *dev)
{
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2_tx_queue *txq, *aggr_txq;
struct mvpp2_txq_pcpu *txq_pcpu;
struct mvpp2_tx_desc *tx_desc;
dma_addr_t buf_dma_addr;
int frags = 0;
u16 txq_id;
u32 tx_cmd;
txq_id = skb_get_queue_mapping(skb);
txq = port->txqs[txq_id];
txq_pcpu = this_cpu_ptr(txq->pcpu);
aggr_txq = &port->priv->aggr_txqs[smp_processor_id()];
if (skb_is_gso(skb)) {
frags = mvpp2_tx_tso(skb, dev, txq, aggr_txq, txq_pcpu);
goto out;
}
frags = skb_shinfo(skb)->nr_frags + 1;
/* Check number of available descriptors */
if (mvpp2_aggr_desc_num_check(port->priv, aggr_txq, frags) ||
mvpp2_txq_reserved_desc_num_proc(port->priv, txq,
txq_pcpu, frags)) {
frags = 0;
goto out;
}
/* Get a descriptor for the first part of the packet */
tx_desc = mvpp2_txq_next_desc_get(aggr_txq);
mvpp2_txdesc_txq_set(port, tx_desc, txq->id);
mvpp2_txdesc_size_set(port, tx_desc, skb_headlen(skb));
buf_dma_addr = dma_map_single(dev->dev.parent, skb->data,
skb_headlen(skb), DMA_TO_DEVICE);
if (unlikely(dma_mapping_error(dev->dev.parent, buf_dma_addr))) {
mvpp2_txq_desc_put(txq);
frags = 0;
goto out;
}
mvpp2_txdesc_dma_addr_set(port, tx_desc, buf_dma_addr);
tx_cmd = mvpp2_skb_tx_csum(port, skb);
if (frags == 1) {
/* First and Last descriptor */
tx_cmd |= MVPP2_TXD_F_DESC | MVPP2_TXD_L_DESC;
mvpp2_txdesc_cmd_set(port, tx_desc, tx_cmd);
mvpp2_txq_inc_put(port, txq_pcpu, skb, tx_desc);
} else {
/* First but not Last */
tx_cmd |= MVPP2_TXD_F_DESC | MVPP2_TXD_PADDING_DISABLE;
mvpp2_txdesc_cmd_set(port, tx_desc, tx_cmd);
mvpp2_txq_inc_put(port, txq_pcpu, NULL, tx_desc);
/* Continue with other skb fragments */
if (mvpp2_tx_frag_process(port, skb, aggr_txq, txq)) {
tx_desc_unmap_put(port, txq, tx_desc);
frags = 0;
}
}
out:
if (frags > 0) {
struct mvpp2_pcpu_stats *stats = this_cpu_ptr(port->stats);
struct netdev_queue *nq = netdev_get_tx_queue(dev, txq_id);
txq_pcpu->reserved_num -= frags;
txq_pcpu->count += frags;
aggr_txq->count += frags;
/* Enable transmit */
wmb();
mvpp2_aggr_txq_pend_desc_add(port, frags);
if (txq_pcpu->count >= txq_pcpu->stop_threshold)
netif_tx_stop_queue(nq);
u64_stats_update_begin(&stats->syncp);
stats->tx_packets++;
stats->tx_bytes += skb->len;
u64_stats_update_end(&stats->syncp);
} else {
dev->stats.tx_dropped++;
dev_kfree_skb_any(skb);
}
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
/* Finalize TX processing */
if (!port->has_tx_irqs && txq_pcpu->count >= txq->done_pkts_coal)
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
mvpp2_txq_done(port, txq, txq_pcpu);
/* Set the timer in case not all frags were processed */
if (!port->has_tx_irqs && txq_pcpu->count <= frags &&
txq_pcpu->count > 0) {
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
struct mvpp2_port_pcpu *port_pcpu = this_cpu_ptr(port->pcpu);
mvpp2_timer_set(port_pcpu);
}
return NETDEV_TX_OK;
}
static inline void mvpp2_cause_error(struct net_device *dev, int cause)
{
if (cause & MVPP2_CAUSE_FCS_ERR_MASK)
netdev_err(dev, "FCS error\n");
if (cause & MVPP2_CAUSE_RX_FIFO_OVERRUN_MASK)
netdev_err(dev, "rx fifo overrun error\n");
if (cause & MVPP2_CAUSE_TX_FIFO_UNDERRUN_MASK)
netdev_err(dev, "tx fifo underrun error\n");
}
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
static int mvpp2_poll(struct napi_struct *napi, int budget)
{
u32 cause_rx_tx, cause_rx, cause_tx, cause_misc;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
int rx_done = 0;
struct mvpp2_port *port = netdev_priv(napi->dev);
struct mvpp2_queue_vector *qv;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
int cpu = smp_processor_id();
qv = container_of(napi, struct mvpp2_queue_vector, napi);
/* Rx/Tx cause register
*
* Bits 0-15: each bit indicates received packets on the Rx queue
* (bit 0 is for Rx queue 0).
*
* Bits 16-23: each bit indicates transmitted packets on the Tx queue
* (bit 16 is for Tx queue 0).
*
* Each CPU has its own Rx/Tx cause register
*/
cause_rx_tx = mvpp2_percpu_read(port->priv, qv->sw_thread_id,
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
MVPP2_ISR_RX_TX_CAUSE_REG(port->id));
cause_misc = cause_rx_tx & MVPP2_CAUSE_MISC_SUM_MASK;
if (cause_misc) {
mvpp2_cause_error(port->dev, cause_misc);
/* Clear the cause register */
mvpp2_write(port->priv, MVPP2_ISR_MISC_CAUSE_REG, 0);
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
mvpp2_percpu_write(port->priv, cpu,
MVPP2_ISR_RX_TX_CAUSE_REG(port->id),
cause_rx_tx & ~MVPP2_CAUSE_MISC_SUM_MASK);
}
cause_tx = cause_rx_tx & MVPP2_CAUSE_TXQ_OCCUP_DESC_ALL_MASK;
if (cause_tx) {
cause_tx >>= MVPP2_CAUSE_TXQ_OCCUP_DESC_ALL_OFFSET;
mvpp2_tx_done(port, cause_tx, qv->sw_thread_id);
}
/* Process RX packets */
cause_rx = cause_rx_tx & MVPP2_CAUSE_RXQ_OCCUP_DESC_ALL_MASK;
cause_rx <<= qv->first_rxq;
cause_rx |= qv->pending_cause_rx;
while (cause_rx && budget > 0) {
int count;
struct mvpp2_rx_queue *rxq;
rxq = mvpp2_get_rx_queue(port, cause_rx);
if (!rxq)
break;
count = mvpp2_rx(port, napi, budget, rxq);
rx_done += count;
budget -= count;
if (budget > 0) {
/* Clear the bit associated to this Rx queue
* so that next iteration will continue from
* the next Rx queue.
*/
cause_rx &= ~(1 << rxq->logic_rxq);
}
}
if (budget > 0) {
cause_rx = 0;
napi_complete_done(napi, rx_done);
mvpp2_qvec_interrupt_enable(qv);
}
qv->pending_cause_rx = cause_rx;
return rx_done;
}
/* Set hw internals when starting port */
static void mvpp2_start_dev(struct mvpp2_port *port)
{
struct net_device *ndev = port->dev;
int i;
if (port->gop_id == 0 &&
(port->phy_interface == PHY_INTERFACE_MODE_XAUI ||
port->phy_interface == PHY_INTERFACE_MODE_10GKR))
mvpp2_xlg_max_rx_size_set(port);
else
mvpp2_gmac_max_rx_size_set(port);
mvpp2_txp_max_tx_size_set(port);
for (i = 0; i < port->nqvecs; i++)
napi_enable(&port->qvecs[i].napi);
/* Enable interrupts on all CPUs */
mvpp2_interrupts_enable(port);
if (port->priv->hw_version == MVPP22) {
mvpp22_comphy_init(port);
mvpp22_gop_init(port);
}
mvpp2_port_mii_set(port);
mvpp2_port_enable(port);
if (ndev->phydev)
phy_start(ndev->phydev);
netif_tx_start_all_queues(port->dev);
}
/* Set hw internals when stopping port */
static void mvpp2_stop_dev(struct mvpp2_port *port)
{
struct net_device *ndev = port->dev;
int i;
/* Stop new packets from arriving to RXQs */
mvpp2_ingress_disable(port);
mdelay(10);
/* Disable interrupts on all CPUs */
mvpp2_interrupts_disable(port);
for (i = 0; i < port->nqvecs; i++)
napi_disable(&port->qvecs[i].napi);
netif_carrier_off(port->dev);
netif_tx_stop_all_queues(port->dev);
mvpp2_egress_disable(port);
mvpp2_port_disable(port);
if (ndev->phydev)
phy_stop(ndev->phydev);
phy_power_off(port->comphy);
}
static int mvpp2_check_ringparam_valid(struct net_device *dev,
struct ethtool_ringparam *ring)
{
u16 new_rx_pending = ring->rx_pending;
u16 new_tx_pending = ring->tx_pending;
if (ring->rx_pending == 0 || ring->tx_pending == 0)
return -EINVAL;
if (ring->rx_pending > MVPP2_MAX_RXD)
new_rx_pending = MVPP2_MAX_RXD;
else if (!IS_ALIGNED(ring->rx_pending, 16))
new_rx_pending = ALIGN(ring->rx_pending, 16);
if (ring->tx_pending > MVPP2_MAX_TXD)
new_tx_pending = MVPP2_MAX_TXD;
else if (!IS_ALIGNED(ring->tx_pending, 32))
new_tx_pending = ALIGN(ring->tx_pending, 32);
if (ring->rx_pending != new_rx_pending) {
netdev_info(dev, "illegal Rx ring size value %d, round to %d\n",
ring->rx_pending, new_rx_pending);
ring->rx_pending = new_rx_pending;
}
if (ring->tx_pending != new_tx_pending) {
netdev_info(dev, "illegal Tx ring size value %d, round to %d\n",
ring->tx_pending, new_tx_pending);
ring->tx_pending = new_tx_pending;
}
return 0;
}
static void mvpp21_get_mac_address(struct mvpp2_port *port, unsigned char *addr)
{
u32 mac_addr_l, mac_addr_m, mac_addr_h;
mac_addr_l = readl(port->base + MVPP2_GMAC_CTRL_1_REG);
mac_addr_m = readl(port->priv->lms_base + MVPP2_SRC_ADDR_MIDDLE);
mac_addr_h = readl(port->priv->lms_base + MVPP2_SRC_ADDR_HIGH);
addr[0] = (mac_addr_h >> 24) & 0xFF;
addr[1] = (mac_addr_h >> 16) & 0xFF;
addr[2] = (mac_addr_h >> 8) & 0xFF;
addr[3] = mac_addr_h & 0xFF;
addr[4] = mac_addr_m & 0xFF;
addr[5] = (mac_addr_l >> MVPP2_GMAC_SA_LOW_OFFS) & 0xFF;
}
static int mvpp2_phy_connect(struct mvpp2_port *port)
{
struct phy_device *phy_dev;
/* No PHY is attached */
if (!port->phy_node)
return 0;
phy_dev = of_phy_connect(port->dev, port->phy_node, mvpp2_link_event, 0,
port->phy_interface);
if (!phy_dev) {
netdev_err(port->dev, "cannot connect to phy\n");
return -ENODEV;
}
phy_dev->supported &= PHY_GBIT_FEATURES;
phy_dev->advertising = phy_dev->supported;
port->link = 0;
port->duplex = 0;
port->speed = 0;
return 0;
}
static void mvpp2_phy_disconnect(struct mvpp2_port *port)
{
struct net_device *ndev = port->dev;
if (!ndev->phydev)
return;
phy_disconnect(ndev->phydev);
}
static int mvpp2_irqs_init(struct mvpp2_port *port)
{
int err, i;
for (i = 0; i < port->nqvecs; i++) {
struct mvpp2_queue_vector *qv = port->qvecs + i;
if (qv->type == MVPP2_QUEUE_VECTOR_PRIVATE)
irq_set_status_flags(qv->irq, IRQ_NO_BALANCING);
err = request_irq(qv->irq, mvpp2_isr, 0, port->dev->name, qv);
if (err)
goto err;
if (qv->type == MVPP2_QUEUE_VECTOR_PRIVATE)
irq_set_affinity_hint(qv->irq,
cpumask_of(qv->sw_thread_id));
}
return 0;
err:
for (i = 0; i < port->nqvecs; i++) {
struct mvpp2_queue_vector *qv = port->qvecs + i;
irq_set_affinity_hint(qv->irq, NULL);
free_irq(qv->irq, qv);
}
return err;
}
static void mvpp2_irqs_deinit(struct mvpp2_port *port)
{
int i;
for (i = 0; i < port->nqvecs; i++) {
struct mvpp2_queue_vector *qv = port->qvecs + i;
irq_set_affinity_hint(qv->irq, NULL);
irq_clear_status_flags(qv->irq, IRQ_NO_BALANCING);
free_irq(qv->irq, qv);
}
}
static void mvpp22_init_rss(struct mvpp2_port *port)
{
struct mvpp2 *priv = port->priv;
int i;
/* Set the table width: replace the whole classifier Rx queue number
* with the ones configured in RSS table entries.
*/
mvpp2_write(priv, MVPP22_RSS_INDEX, MVPP22_RSS_INDEX_TABLE(0));
mvpp2_write(priv, MVPP22_RSS_WIDTH, 8);
/* Loop through the classifier Rx Queues and map them to a RSS table.
* Map them all to the first table (0) by default.
*/
for (i = 0; i < MVPP2_CLS_RX_QUEUES; i++) {
mvpp2_write(priv, MVPP22_RSS_INDEX, MVPP22_RSS_INDEX_QUEUE(i));
mvpp2_write(priv, MVPP22_RSS_TABLE,
MVPP22_RSS_TABLE_POINTER(0));
}
/* Configure the first table to evenly distribute the packets across
* real Rx Queues. The table entries map a hash to an port Rx Queue.
*/
for (i = 0; i < MVPP22_RSS_TABLE_ENTRIES; i++) {
u32 sel = MVPP22_RSS_INDEX_TABLE(0) |
MVPP22_RSS_INDEX_TABLE_ENTRY(i);
mvpp2_write(priv, MVPP22_RSS_INDEX, sel);
mvpp2_write(priv, MVPP22_RSS_TABLE_ENTRY, i % port->nrxqs);
}
}
static int mvpp2_open(struct net_device *dev)
{
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2 *priv = port->priv;
unsigned char mac_bcast[ETH_ALEN] = {
0xff, 0xff, 0xff, 0xff, 0xff, 0xff };
int err;
err = mvpp2_prs_mac_da_accept(port->priv, port->id, mac_bcast, true);
if (err) {
netdev_err(dev, "mvpp2_prs_mac_da_accept BC failed\n");
return err;
}
err = mvpp2_prs_mac_da_accept(port->priv, port->id,
dev->dev_addr, true);
if (err) {
netdev_err(dev, "mvpp2_prs_mac_da_accept MC failed\n");
return err;
}
err = mvpp2_prs_tag_mode_set(port->priv, port->id, MVPP2_TAG_TYPE_MH);
if (err) {
netdev_err(dev, "mvpp2_prs_tag_mode_set failed\n");
return err;
}
err = mvpp2_prs_def_flow(port);
if (err) {
netdev_err(dev, "mvpp2_prs_def_flow failed\n");
return err;
}
/* Allocate the Rx/Tx queues */
err = mvpp2_setup_rxqs(port);
if (err) {
netdev_err(port->dev, "cannot allocate Rx queues\n");
return err;
}
err = mvpp2_setup_txqs(port);
if (err) {
netdev_err(port->dev, "cannot allocate Tx queues\n");
goto err_cleanup_rxqs;
}
err = mvpp2_irqs_init(port);
if (err) {
netdev_err(port->dev, "cannot init IRQs\n");
goto err_cleanup_txqs;
}
if (priv->hw_version == MVPP22 && !port->phy_node && port->link_irq) {
err = request_irq(port->link_irq, mvpp2_link_status_isr, 0,
dev->name, port);
if (err) {
netdev_err(port->dev, "cannot request link IRQ %d\n",
port->link_irq);
goto err_free_irq;
}
mvpp22_gop_setup_irq(port);
}
/* In default link is down */
netif_carrier_off(port->dev);
err = mvpp2_phy_connect(port);
if (err < 0)
goto err_free_link_irq;
/* Unmask interrupts on all CPUs */
on_each_cpu(mvpp2_interrupts_unmask, port, 1);
mvpp2_shared_interrupt_mask_unmask(port, false);
mvpp2_start_dev(port);
if (priv->hw_version == MVPP22)
mvpp22_init_rss(port);
/* Start hardware statistics gathering */
queue_delayed_work(priv->stats_queue, &port->stats_work,
MVPP2_MIB_COUNTERS_STATS_DELAY);
return 0;
err_free_link_irq:
if (priv->hw_version == MVPP22 && !port->phy_node && port->link_irq)
free_irq(port->link_irq, port);
err_free_irq:
mvpp2_irqs_deinit(port);
err_cleanup_txqs:
mvpp2_cleanup_txqs(port);
err_cleanup_rxqs:
mvpp2_cleanup_rxqs(port);
return err;
}
static int mvpp2_stop(struct net_device *dev)
{
struct mvpp2_port *port = netdev_priv(dev);
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
struct mvpp2_port_pcpu *port_pcpu;
struct mvpp2 *priv = port->priv;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
int cpu;
mvpp2_stop_dev(port);
mvpp2_phy_disconnect(port);
/* Mask interrupts on all CPUs */
on_each_cpu(mvpp2_interrupts_mask, port, 1);
mvpp2_shared_interrupt_mask_unmask(port, true);
if (priv->hw_version == MVPP22 && !port->phy_node && port->link_irq)
free_irq(port->link_irq, port);
mvpp2_irqs_deinit(port);
if (!port->has_tx_irqs) {
for_each_present_cpu(cpu) {
port_pcpu = per_cpu_ptr(port->pcpu, cpu);
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
hrtimer_cancel(&port_pcpu->tx_done_timer);
port_pcpu->timer_scheduled = false;
tasklet_kill(&port_pcpu->tx_done_tasklet);
}
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
}
mvpp2_cleanup_rxqs(port);
mvpp2_cleanup_txqs(port);
cancel_delayed_work_sync(&port->stats_work);
return 0;
}
static void mvpp2_set_rx_mode(struct net_device *dev)
{
struct mvpp2_port *port = netdev_priv(dev);
struct mvpp2 *priv = port->priv;
struct netdev_hw_addr *ha;
int id = port->id;
bool allmulti = dev->flags & IFF_ALLMULTI;
mvpp2_prs_mac_promisc_set(priv, id, dev->flags & IFF_PROMISC);
mvpp2_prs_mac_multi_set(priv, id, MVPP2_PE_MAC_MC_ALL, allmulti);
mvpp2_prs_mac_multi_set(priv, id, MVPP2_PE_MAC_MC_IP6, allmulti);
/* Remove all port->id's mcast enries */
mvpp2_prs_mcast_del_all(priv, id);
if (allmulti && !netdev_mc_empty(dev)) {
netdev_for_each_mc_addr(ha, dev)
mvpp2_prs_mac_da_accept(priv, id, ha->addr, true);
}
}
static int mvpp2_set_mac_address(struct net_device *dev, void *p)
{
struct mvpp2_port *port = netdev_priv(dev);
const struct sockaddr *addr = p;
int err;
if (!is_valid_ether_addr(addr->sa_data)) {
err = -EADDRNOTAVAIL;
goto log_error;
}
if (!netif_running(dev)) {
err = mvpp2_prs_update_mac_da(dev, addr->sa_data);
if (!err)
return 0;
/* Reconfigure parser to accept the original MAC address */
err = mvpp2_prs_update_mac_da(dev, dev->dev_addr);
if (err)
goto log_error;
}
mvpp2_stop_dev(port);
err = mvpp2_prs_update_mac_da(dev, addr->sa_data);
if (!err)
goto out_start;
/* Reconfigure parser accept the original MAC address */
err = mvpp2_prs_update_mac_da(dev, dev->dev_addr);
if (err)
goto log_error;
out_start:
mvpp2_start_dev(port);
mvpp2_egress_enable(port);
mvpp2_ingress_enable(port);
return 0;
log_error:
netdev_err(dev, "failed to change MAC address\n");
return err;
}
static int mvpp2_change_mtu(struct net_device *dev, int mtu)
{
struct mvpp2_port *port = netdev_priv(dev);
int err;
if (!IS_ALIGNED(MVPP2_RX_PKT_SIZE(mtu), 8)) {
netdev_info(dev, "illegal MTU value %d, round to %d\n", mtu,
ALIGN(MVPP2_RX_PKT_SIZE(mtu), 8));
mtu = ALIGN(MVPP2_RX_PKT_SIZE(mtu), 8);
}
if (!netif_running(dev)) {
err = mvpp2_bm_update_mtu(dev, mtu);
if (!err) {
port->pkt_size = MVPP2_RX_PKT_SIZE(mtu);
return 0;
}
/* Reconfigure BM to the original MTU */
err = mvpp2_bm_update_mtu(dev, dev->mtu);
if (err)
goto log_error;
}
mvpp2_stop_dev(port);
err = mvpp2_bm_update_mtu(dev, mtu);
if (!err) {
port->pkt_size = MVPP2_RX_PKT_SIZE(mtu);
goto out_start;
}
/* Reconfigure BM to the original MTU */
err = mvpp2_bm_update_mtu(dev, dev->mtu);
if (err)
goto log_error;
out_start:
mvpp2_start_dev(port);
mvpp2_egress_enable(port);
mvpp2_ingress_enable(port);
return 0;
log_error:
netdev_err(dev, "failed to change MTU\n");
return err;
}
static void
mvpp2_get_stats64(struct net_device *dev, struct rtnl_link_stats64 *stats)
{
struct mvpp2_port *port = netdev_priv(dev);
unsigned int start;
int cpu;
for_each_possible_cpu(cpu) {
struct mvpp2_pcpu_stats *cpu_stats;
u64 rx_packets;
u64 rx_bytes;
u64 tx_packets;
u64 tx_bytes;
cpu_stats = per_cpu_ptr(port->stats, cpu);
do {
start = u64_stats_fetch_begin_irq(&cpu_stats->syncp);
rx_packets = cpu_stats->rx_packets;
rx_bytes = cpu_stats->rx_bytes;
tx_packets = cpu_stats->tx_packets;
tx_bytes = cpu_stats->tx_bytes;
} while (u64_stats_fetch_retry_irq(&cpu_stats->syncp, start));
stats->rx_packets += rx_packets;
stats->rx_bytes += rx_bytes;
stats->tx_packets += tx_packets;
stats->tx_bytes += tx_bytes;
}
stats->rx_errors = dev->stats.rx_errors;
stats->rx_dropped = dev->stats.rx_dropped;
stats->tx_dropped = dev->stats.tx_dropped;
}
static int mvpp2_ioctl(struct net_device *dev, struct ifreq *ifr, int cmd)
{
int ret;
if (!dev->phydev)
return -ENOTSUPP;
ret = phy_mii_ioctl(dev->phydev, ifr, cmd);
if (!ret)
mvpp2_link_event(dev);
return ret;
}
/* Ethtool methods */
/* Set interrupt coalescing for ethtools */
static int mvpp2_ethtool_set_coalesce(struct net_device *dev,
struct ethtool_coalesce *c)
{
struct mvpp2_port *port = netdev_priv(dev);
int queue;
for (queue = 0; queue < port->nrxqs; queue++) {
struct mvpp2_rx_queue *rxq = port->rxqs[queue];
rxq->time_coal = c->rx_coalesce_usecs;
rxq->pkts_coal = c->rx_max_coalesced_frames;
mvpp2_rx_pkts_coal_set(port, rxq);
mvpp2_rx_time_coal_set(port, rxq);
}
if (port->has_tx_irqs) {
port->tx_time_coal = c->tx_coalesce_usecs;
mvpp2_tx_time_coal_set(port);
}
for (queue = 0; queue < port->ntxqs; queue++) {
struct mvpp2_tx_queue *txq = port->txqs[queue];
txq->done_pkts_coal = c->tx_max_coalesced_frames;
if (port->has_tx_irqs)
mvpp2_tx_pkts_coal_set(port, txq);
}
return 0;
}
/* get coalescing for ethtools */
static int mvpp2_ethtool_get_coalesce(struct net_device *dev,
struct ethtool_coalesce *c)
{
struct mvpp2_port *port = netdev_priv(dev);
c->rx_coalesce_usecs = port->rxqs[0]->time_coal;
c->rx_max_coalesced_frames = port->rxqs[0]->pkts_coal;
c->tx_max_coalesced_frames = port->txqs[0]->done_pkts_coal;
return 0;
}
static void mvpp2_ethtool_get_drvinfo(struct net_device *dev,
struct ethtool_drvinfo *drvinfo)
{
strlcpy(drvinfo->driver, MVPP2_DRIVER_NAME,
sizeof(drvinfo->driver));
strlcpy(drvinfo->version, MVPP2_DRIVER_VERSION,
sizeof(drvinfo->version));
strlcpy(drvinfo->bus_info, dev_name(&dev->dev),
sizeof(drvinfo->bus_info));
}
static void mvpp2_ethtool_get_ringparam(struct net_device *dev,
struct ethtool_ringparam *ring)
{
struct mvpp2_port *port = netdev_priv(dev);
ring->rx_max_pending = MVPP2_MAX_RXD;
ring->tx_max_pending = MVPP2_MAX_TXD;
ring->rx_pending = port->rx_ring_size;
ring->tx_pending = port->tx_ring_size;
}
static int mvpp2_ethtool_set_ringparam(struct net_device *dev,
struct ethtool_ringparam *ring)
{
struct mvpp2_port *port = netdev_priv(dev);
u16 prev_rx_ring_size = port->rx_ring_size;
u16 prev_tx_ring_size = port->tx_ring_size;
int err;
err = mvpp2_check_ringparam_valid(dev, ring);
if (err)
return err;
if (!netif_running(dev)) {
port->rx_ring_size = ring->rx_pending;
port->tx_ring_size = ring->tx_pending;
return 0;
}
/* The interface is running, so we have to force a
* reallocation of the queues
*/
mvpp2_stop_dev(port);
mvpp2_cleanup_rxqs(port);
mvpp2_cleanup_txqs(port);
port->rx_ring_size = ring->rx_pending;
port->tx_ring_size = ring->tx_pending;
err = mvpp2_setup_rxqs(port);
if (err) {
/* Reallocate Rx queues with the original ring size */
port->rx_ring_size = prev_rx_ring_size;
ring->rx_pending = prev_rx_ring_size;
err = mvpp2_setup_rxqs(port);
if (err)
goto err_out;
}
err = mvpp2_setup_txqs(port);
if (err) {
/* Reallocate Tx queues with the original ring size */
port->tx_ring_size = prev_tx_ring_size;
ring->tx_pending = prev_tx_ring_size;
err = mvpp2_setup_txqs(port);
if (err)
goto err_clean_rxqs;
}
mvpp2_start_dev(port);
mvpp2_egress_enable(port);
mvpp2_ingress_enable(port);
return 0;
err_clean_rxqs:
mvpp2_cleanup_rxqs(port);
err_out:
netdev_err(dev, "failed to change ring parameters");
return err;
}
/* Device ops */
static const struct net_device_ops mvpp2_netdev_ops = {
.ndo_open = mvpp2_open,
.ndo_stop = mvpp2_stop,
.ndo_start_xmit = mvpp2_tx,
.ndo_set_rx_mode = mvpp2_set_rx_mode,
.ndo_set_mac_address = mvpp2_set_mac_address,
.ndo_change_mtu = mvpp2_change_mtu,
.ndo_get_stats64 = mvpp2_get_stats64,
.ndo_do_ioctl = mvpp2_ioctl,
};
static const struct ethtool_ops mvpp2_eth_tool_ops = {
.nway_reset = phy_ethtool_nway_reset,
.get_link = ethtool_op_get_link,
.set_coalesce = mvpp2_ethtool_set_coalesce,
.get_coalesce = mvpp2_ethtool_get_coalesce,
.get_drvinfo = mvpp2_ethtool_get_drvinfo,
.get_ringparam = mvpp2_ethtool_get_ringparam,
.set_ringparam = mvpp2_ethtool_set_ringparam,
.get_strings = mvpp2_ethtool_get_strings,
.get_ethtool_stats = mvpp2_ethtool_get_stats,
.get_sset_count = mvpp2_ethtool_get_sset_count,
.get_link_ksettings = phy_ethtool_get_link_ksettings,
.set_link_ksettings = phy_ethtool_set_link_ksettings,
};
/* Used for PPv2.1, or PPv2.2 with the old Device Tree binding that
* had a single IRQ defined per-port.
*/
static int mvpp2_simple_queue_vectors_init(struct mvpp2_port *port,
struct device_node *port_node)
{
struct mvpp2_queue_vector *v = &port->qvecs[0];
v->first_rxq = 0;
v->nrxqs = port->nrxqs;
v->type = MVPP2_QUEUE_VECTOR_SHARED;
v->sw_thread_id = 0;
v->sw_thread_mask = *cpumask_bits(cpu_online_mask);
v->port = port;
v->irq = irq_of_parse_and_map(port_node, 0);
if (v->irq <= 0)
return -EINVAL;
netif_napi_add(port->dev, &v->napi, mvpp2_poll,
NAPI_POLL_WEIGHT);
port->nqvecs = 1;
return 0;
}
static int mvpp2_multi_queue_vectors_init(struct mvpp2_port *port,
struct device_node *port_node)
{
struct mvpp2_queue_vector *v;
int i, ret;
port->nqvecs = num_possible_cpus();
if (queue_mode == MVPP2_QDIST_SINGLE_MODE)
port->nqvecs += 1;
for (i = 0; i < port->nqvecs; i++) {
char irqname[16];
v = port->qvecs + i;
v->port = port;
v->type = MVPP2_QUEUE_VECTOR_PRIVATE;
v->sw_thread_id = i;
v->sw_thread_mask = BIT(i);
snprintf(irqname, sizeof(irqname), "tx-cpu%d", i);
if (queue_mode == MVPP2_QDIST_MULTI_MODE) {
v->first_rxq = i * MVPP2_DEFAULT_RXQ;
v->nrxqs = MVPP2_DEFAULT_RXQ;
} else if (queue_mode == MVPP2_QDIST_SINGLE_MODE &&
i == (port->nqvecs - 1)) {
v->first_rxq = 0;
v->nrxqs = port->nrxqs;
v->type = MVPP2_QUEUE_VECTOR_SHARED;
strncpy(irqname, "rx-shared", sizeof(irqname));
}
v->irq = of_irq_get_byname(port_node, irqname);
if (v->irq <= 0) {
ret = -EINVAL;
goto err;
}
netif_napi_add(port->dev, &v->napi, mvpp2_poll,
NAPI_POLL_WEIGHT);
}
return 0;
err:
for (i = 0; i < port->nqvecs; i++)
irq_dispose_mapping(port->qvecs[i].irq);
return ret;
}
static int mvpp2_queue_vectors_init(struct mvpp2_port *port,
struct device_node *port_node)
{
if (port->has_tx_irqs)
return mvpp2_multi_queue_vectors_init(port, port_node);
else
return mvpp2_simple_queue_vectors_init(port, port_node);
}
static void mvpp2_queue_vectors_deinit(struct mvpp2_port *port)
{
int i;
for (i = 0; i < port->nqvecs; i++)
irq_dispose_mapping(port->qvecs[i].irq);
}
/* Configure Rx queue group interrupt for this port */
static void mvpp2_rx_irqs_setup(struct mvpp2_port *port)
{
struct mvpp2 *priv = port->priv;
u32 val;
int i;
if (priv->hw_version == MVPP21) {
mvpp2_write(priv, MVPP21_ISR_RXQ_GROUP_REG(port->id),
port->nrxqs);
return;
}
/* Handle the more complicated PPv2.2 case */
for (i = 0; i < port->nqvecs; i++) {
struct mvpp2_queue_vector *qv = port->qvecs + i;
if (!qv->nrxqs)
continue;
val = qv->sw_thread_id;
val |= port->id << MVPP22_ISR_RXQ_GROUP_INDEX_GROUP_OFFSET;
mvpp2_write(priv, MVPP22_ISR_RXQ_GROUP_INDEX_REG, val);
val = qv->first_rxq;
val |= qv->nrxqs << MVPP22_ISR_RXQ_SUB_GROUP_SIZE_OFFSET;
mvpp2_write(priv, MVPP22_ISR_RXQ_SUB_GROUP_CONFIG_REG, val);
}
}
/* Initialize port HW */
static int mvpp2_port_init(struct mvpp2_port *port)
{
struct device *dev = port->dev->dev.parent;
struct mvpp2 *priv = port->priv;
struct mvpp2_txq_pcpu *txq_pcpu;
int queue, cpu, err;
/* Checks for hardware constraints */
if (port->first_rxq + port->nrxqs >
MVPP2_MAX_PORTS * priv->max_port_rxqs)
return -EINVAL;
if (port->nrxqs % 4 || (port->nrxqs > priv->max_port_rxqs) ||
(port->ntxqs > MVPP2_MAX_TXQ))
return -EINVAL;
/* Disable port */
mvpp2_egress_disable(port);
mvpp2_port_disable(port);
port->tx_time_coal = MVPP2_TXDONE_COAL_USEC;
port->txqs = devm_kcalloc(dev, port->ntxqs, sizeof(*port->txqs),
GFP_KERNEL);
if (!port->txqs)
return -ENOMEM;
/* Associate physical Tx queues to this port and initialize.
* The mapping is predefined.
*/
for (queue = 0; queue < port->ntxqs; queue++) {
int queue_phy_id = mvpp2_txq_phys(port->id, queue);
struct mvpp2_tx_queue *txq;
txq = devm_kzalloc(dev, sizeof(*txq), GFP_KERNEL);
if (!txq) {
err = -ENOMEM;
goto err_free_percpu;
}
txq->pcpu = alloc_percpu(struct mvpp2_txq_pcpu);
if (!txq->pcpu) {
err = -ENOMEM;
goto err_free_percpu;
}
txq->id = queue_phy_id;
txq->log_id = queue;
txq->done_pkts_coal = MVPP2_TXDONE_COAL_PKTS_THRESH;
for_each_present_cpu(cpu) {
txq_pcpu = per_cpu_ptr(txq->pcpu, cpu);
txq_pcpu->cpu = cpu;
}
port->txqs[queue] = txq;
}
port->rxqs = devm_kcalloc(dev, port->nrxqs, sizeof(*port->rxqs),
GFP_KERNEL);
if (!port->rxqs) {
err = -ENOMEM;
goto err_free_percpu;
}
/* Allocate and initialize Rx queue for this port */
for (queue = 0; queue < port->nrxqs; queue++) {
struct mvpp2_rx_queue *rxq;
/* Map physical Rx queue to port's logical Rx queue */
rxq = devm_kzalloc(dev, sizeof(*rxq), GFP_KERNEL);
if (!rxq) {
err = -ENOMEM;
goto err_free_percpu;
}
/* Map this Rx queue to a physical queue */
rxq->id = port->first_rxq + queue;
rxq->port = port->id;
rxq->logic_rxq = queue;
port->rxqs[queue] = rxq;
}
mvpp2_rx_irqs_setup(port);
/* Create Rx descriptor rings */
for (queue = 0; queue < port->nrxqs; queue++) {
struct mvpp2_rx_queue *rxq = port->rxqs[queue];
rxq->size = port->rx_ring_size;
rxq->pkts_coal = MVPP2_RX_COAL_PKTS;
rxq->time_coal = MVPP2_RX_COAL_USEC;
}
mvpp2_ingress_disable(port);
/* Port default configuration */
mvpp2_defaults_set(port);
/* Port's classifier configuration */
mvpp2_cls_oversize_rxq_set(port);
mvpp2_cls_port_config(port);
/* Provide an initial Rx packet size */
port->pkt_size = MVPP2_RX_PKT_SIZE(port->dev->mtu);
/* Initialize pools for swf */
err = mvpp2_swf_bm_pool_init(port);
if (err)
goto err_free_percpu;
return 0;
err_free_percpu:
for (queue = 0; queue < port->ntxqs; queue++) {
if (!port->txqs[queue])
continue;
free_percpu(port->txqs[queue]->pcpu);
}
return err;
}
/* Checks if the port DT description has the TX interrupts
* described. On PPv2.1, there are no such interrupts. On PPv2.2,
* there are available, but we need to keep support for old DTs.
*/
static bool mvpp2_port_has_tx_irqs(struct mvpp2 *priv,
struct device_node *port_node)
{
char *irqs[5] = { "rx-shared", "tx-cpu0", "tx-cpu1",
"tx-cpu2", "tx-cpu3" };
int ret, i;
if (priv->hw_version == MVPP21)
return false;
for (i = 0; i < 5; i++) {
ret = of_property_match_string(port_node, "interrupt-names",
irqs[i]);
if (ret < 0)
return false;
}
return true;
}
static void mvpp2_port_copy_mac_addr(struct net_device *dev, struct mvpp2 *priv,
struct device_node *port_node,
char **mac_from)
{
struct mvpp2_port *port = netdev_priv(dev);
char hw_mac_addr[ETH_ALEN] = {0};
const char *dt_mac_addr;
dt_mac_addr = of_get_mac_address(port_node);
if (dt_mac_addr && is_valid_ether_addr(dt_mac_addr)) {
*mac_from = "device tree";
ether_addr_copy(dev->dev_addr, dt_mac_addr);
return;
}
if (priv->hw_version == MVPP21) {
mvpp21_get_mac_address(port, hw_mac_addr);
if (is_valid_ether_addr(hw_mac_addr)) {
*mac_from = "hardware";
ether_addr_copy(dev->dev_addr, hw_mac_addr);
return;
}
}
*mac_from = "random";
eth_hw_addr_random(dev);
}
/* Ports initialization */
static int mvpp2_port_probe(struct platform_device *pdev,
struct device_node *port_node,
struct mvpp2 *priv, int index)
{
struct device_node *phy_node;
struct phy *comphy;
struct mvpp2_port *port;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
struct mvpp2_port_pcpu *port_pcpu;
struct net_device *dev;
struct resource *res;
char *mac_from = "";
unsigned int ntxqs, nrxqs;
bool has_tx_irqs;
u32 id;
int features;
int phy_mode;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
int err, i, cpu;
has_tx_irqs = mvpp2_port_has_tx_irqs(priv, port_node);
if (!has_tx_irqs)
queue_mode = MVPP2_QDIST_SINGLE_MODE;
ntxqs = MVPP2_MAX_TXQ;
if (priv->hw_version == MVPP22 && queue_mode == MVPP2_QDIST_MULTI_MODE)
nrxqs = MVPP2_DEFAULT_RXQ * num_possible_cpus();
else
nrxqs = MVPP2_DEFAULT_RXQ;
dev = alloc_etherdev_mqs(sizeof(*port), ntxqs, nrxqs);
if (!dev)
return -ENOMEM;
phy_node = of_parse_phandle(port_node, "phy", 0);
phy_mode = of_get_phy_mode(port_node);
if (phy_mode < 0) {
dev_err(&pdev->dev, "incorrect phy mode\n");
err = phy_mode;
goto err_free_netdev;
}
comphy = devm_of_phy_get(&pdev->dev, port_node, NULL);
if (IS_ERR(comphy)) {
if (PTR_ERR(comphy) == -EPROBE_DEFER) {
err = -EPROBE_DEFER;
goto err_free_netdev;
}
comphy = NULL;
}
if (of_property_read_u32(port_node, "port-id", &id)) {
err = -EINVAL;
dev_err(&pdev->dev, "missing port-id value\n");
goto err_free_netdev;
}
dev->tx_queue_len = MVPP2_MAX_TXD;
dev->watchdog_timeo = 5 * HZ;
dev->netdev_ops = &mvpp2_netdev_ops;
dev->ethtool_ops = &mvpp2_eth_tool_ops;
port = netdev_priv(dev);
port->dev = dev;
port->ntxqs = ntxqs;
port->nrxqs = nrxqs;
port->priv = priv;
port->has_tx_irqs = has_tx_irqs;
err = mvpp2_queue_vectors_init(port, port_node);
if (err)
goto err_free_netdev;
port->link_irq = of_irq_get_byname(port_node, "link");
if (port->link_irq == -EPROBE_DEFER) {
err = -EPROBE_DEFER;
goto err_deinit_qvecs;
}
if (port->link_irq <= 0)
/* the link irq is optional */
port->link_irq = 0;
if (of_property_read_bool(port_node, "marvell,loopback"))
port->flags |= MVPP2_F_LOOPBACK;
port->id = id;
if (priv->hw_version == MVPP21)
port->first_rxq = port->id * port->nrxqs;
else
port->first_rxq = port->id * priv->max_port_rxqs;
port->phy_node = phy_node;
port->phy_interface = phy_mode;
port->comphy = comphy;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
if (priv->hw_version == MVPP21) {
res = platform_get_resource(pdev, IORESOURCE_MEM, 2 + id);
port->base = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(port->base)) {
err = PTR_ERR(port->base);
goto err_free_irq;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
}
port->stats_base = port->priv->lms_base +
MVPP21_MIB_COUNTERS_OFFSET +
port->gop_id * MVPP21_MIB_COUNTERS_PORT_SZ;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
} else {
if (of_property_read_u32(port_node, "gop-port-id",
&port->gop_id)) {
err = -EINVAL;
dev_err(&pdev->dev, "missing gop-port-id value\n");
goto err_deinit_qvecs;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
}
port->base = priv->iface_base + MVPP22_GMAC_BASE(port->gop_id);
port->stats_base = port->priv->iface_base +
MVPP22_MIB_COUNTERS_OFFSET +
port->gop_id * MVPP22_MIB_COUNTERS_PORT_SZ;
}
/* Alloc per-cpu and ethtool stats */
port->stats = netdev_alloc_pcpu_stats(struct mvpp2_pcpu_stats);
if (!port->stats) {
err = -ENOMEM;
goto err_free_irq;
}
port->ethtool_stats = devm_kcalloc(&pdev->dev,
ARRAY_SIZE(mvpp2_ethtool_regs),
sizeof(u64), GFP_KERNEL);
if (!port->ethtool_stats) {
err = -ENOMEM;
goto err_free_stats;
}
mutex_init(&port->gather_stats_lock);
INIT_DELAYED_WORK(&port->stats_work, mvpp2_gather_hw_statistics);
mvpp2_port_copy_mac_addr(dev, priv, port_node, &mac_from);
port->tx_ring_size = MVPP2_MAX_TXD;
port->rx_ring_size = MVPP2_MAX_RXD;
SET_NETDEV_DEV(dev, &pdev->dev);
err = mvpp2_port_init(port);
if (err < 0) {
dev_err(&pdev->dev, "failed to init port %d\n", id);
goto err_free_stats;
}
mvpp2_port_periodic_xon_disable(port);
if (priv->hw_version == MVPP21)
mvpp2_port_fc_adv_enable(port);
mvpp2_port_reset(port);
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
port->pcpu = alloc_percpu(struct mvpp2_port_pcpu);
if (!port->pcpu) {
err = -ENOMEM;
goto err_free_txq_pcpu;
}
if (!port->has_tx_irqs) {
for_each_present_cpu(cpu) {
port_pcpu = per_cpu_ptr(port->pcpu, cpu);
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
hrtimer_init(&port_pcpu->tx_done_timer, CLOCK_MONOTONIC,
HRTIMER_MODE_REL_PINNED);
port_pcpu->tx_done_timer.function = mvpp2_hr_timer_cb;
port_pcpu->timer_scheduled = false;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
tasklet_init(&port_pcpu->tx_done_tasklet,
mvpp2_tx_proc_cb,
(unsigned long)dev);
}
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
}
features = NETIF_F_SG | NETIF_F_IP_CSUM | NETIF_F_TSO;
dev->features = features | NETIF_F_RXCSUM;
dev->hw_features |= features | NETIF_F_RXCSUM | NETIF_F_GRO;
dev->vlan_features |= features;
dev->gso_max_segs = MVPP2_MAX_TSO_SEGS;
/* MTU range: 68 - 9676 */
dev->min_mtu = ETH_MIN_MTU;
/* 9676 == 9700 - 20 and rounding to 8 */
dev->max_mtu = 9676;
err = register_netdev(dev);
if (err < 0) {
dev_err(&pdev->dev, "failed to register netdev\n");
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
goto err_free_port_pcpu;
}
netdev_info(dev, "Using %s mac address %pM\n", mac_from, dev->dev_addr);
priv->port_list[index] = port;
return 0;
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
err_free_port_pcpu:
free_percpu(port->pcpu);
err_free_txq_pcpu:
for (i = 0; i < port->ntxqs; i++)
free_percpu(port->txqs[i]->pcpu);
err_free_stats:
free_percpu(port->stats);
err_free_irq:
if (port->link_irq)
irq_dispose_mapping(port->link_irq);
err_deinit_qvecs:
mvpp2_queue_vectors_deinit(port);
err_free_netdev:
of_node_put(phy_node);
free_netdev(dev);
return err;
}
/* Ports removal routine */
static void mvpp2_port_remove(struct mvpp2_port *port)
{
int i;
unregister_netdev(port->dev);
of_node_put(port->phy_node);
net: mvpp2: replace TX coalescing interrupts with hrtimer The PP2 controller is capable of per-CPU TX processing, which means there are per-CPU banked register sets and queues. Current version of the driver supports TX packet coalescing - once on given CPU sent packets amount reaches a threshold value, an IRQ occurs. However, there is a single interrupt line responsible for CPU0/1 TX and RX events (the latter is not per-CPU, the hardware does not support RSS). When the top-half executes the interrupt cause is not known. This is why in NAPI poll function, along with RX processing, IRQ cause register on both CPU's is accessed in order to determine on which of them the TX coalescing threshold might have been reached. Thus the egress processing and releasing the buffers is able to take place on the corresponding CPU. Hitherto approach lead to an illegal usage of on_each_cpu function in softirq context. The problem is solved by resigning from TX coalescing interrupts and separating egress finalization from NAPI processing. For that purpose a method of using hrtimer is introduced. In main transmit function (mvpp2_tx) buffers are released once a software coalescing threshold is reached. In case not all the data is processed a timer is set on this CPU - in its interrupt context a tasklet is scheduled in which all queues are processed. At once only one timer per-CPU can be running, which is controlled by a dedicated flag. This commit removes TX processing from NAPI polling function, disables hardware coalescing and enables hrtimer with tasklet, using new per-CPU port structure (mvpp2_port_pcpu). Signed-off-by: Marcin Wojtas <mw@semihalf.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2015-08-07 01:00:30 +08:00
free_percpu(port->pcpu);
free_percpu(port->stats);
for (i = 0; i < port->ntxqs; i++)
free_percpu(port->txqs[i]->pcpu);
mvpp2_queue_vectors_deinit(port);
if (port->link_irq)
irq_dispose_mapping(port->link_irq);
free_netdev(port->dev);
}
/* Initialize decoding windows */
static void mvpp2_conf_mbus_windows(const struct mbus_dram_target_info *dram,
struct mvpp2 *priv)
{
u32 win_enable;
int i;
for (i = 0; i < 6; i++) {
mvpp2_write(priv, MVPP2_WIN_BASE(i), 0);
mvpp2_write(priv, MVPP2_WIN_SIZE(i), 0);
if (i < 4)
mvpp2_write(priv, MVPP2_WIN_REMAP(i), 0);
}
win_enable = 0;
for (i = 0; i < dram->num_cs; i++) {
const struct mbus_dram_window *cs = dram->cs + i;
mvpp2_write(priv, MVPP2_WIN_BASE(i),
(cs->base & 0xffff0000) | (cs->mbus_attr << 8) |
dram->mbus_dram_target_id);
mvpp2_write(priv, MVPP2_WIN_SIZE(i),
(cs->size - 1) & 0xffff0000);
win_enable |= (1 << i);
}
mvpp2_write(priv, MVPP2_BASE_ADDR_ENABLE, win_enable);
}
/* Initialize Rx FIFO's */
static void mvpp2_rx_fifo_init(struct mvpp2 *priv)
{
int port;
for (port = 0; port < MVPP2_MAX_PORTS; port++) {
mvpp2_write(priv, MVPP2_RX_DATA_FIFO_SIZE_REG(port),
MVPP2_RX_FIFO_PORT_DATA_SIZE_4KB);
mvpp2_write(priv, MVPP2_RX_ATTR_FIFO_SIZE_REG(port),
MVPP2_RX_FIFO_PORT_ATTR_SIZE_4KB);
}
mvpp2_write(priv, MVPP2_RX_MIN_PKT_SIZE_REG,
MVPP2_RX_FIFO_PORT_MIN_PKT);
mvpp2_write(priv, MVPP2_RX_FIFO_INIT_REG, 0x1);
}
static void mvpp22_rx_fifo_init(struct mvpp2 *priv)
{
int port;
/* The FIFO size parameters are set depending on the maximum speed a
* given port can handle:
* - Port 0: 10Gbps
* - Port 1: 2.5Gbps
* - Ports 2 and 3: 1Gbps
*/
mvpp2_write(priv, MVPP2_RX_DATA_FIFO_SIZE_REG(0),
MVPP2_RX_FIFO_PORT_DATA_SIZE_32KB);
mvpp2_write(priv, MVPP2_RX_ATTR_FIFO_SIZE_REG(0),
MVPP2_RX_FIFO_PORT_ATTR_SIZE_32KB);
mvpp2_write(priv, MVPP2_RX_DATA_FIFO_SIZE_REG(1),
MVPP2_RX_FIFO_PORT_DATA_SIZE_8KB);
mvpp2_write(priv, MVPP2_RX_ATTR_FIFO_SIZE_REG(1),
MVPP2_RX_FIFO_PORT_ATTR_SIZE_8KB);
for (port = 2; port < MVPP2_MAX_PORTS; port++) {
mvpp2_write(priv, MVPP2_RX_DATA_FIFO_SIZE_REG(port),
MVPP2_RX_FIFO_PORT_DATA_SIZE_4KB);
mvpp2_write(priv, MVPP2_RX_ATTR_FIFO_SIZE_REG(port),
MVPP2_RX_FIFO_PORT_ATTR_SIZE_4KB);
}
mvpp2_write(priv, MVPP2_RX_MIN_PKT_SIZE_REG,
MVPP2_RX_FIFO_PORT_MIN_PKT);
mvpp2_write(priv, MVPP2_RX_FIFO_INIT_REG, 0x1);
}
/* Initialize Tx FIFO's */
static void mvpp22_tx_fifo_init(struct mvpp2 *priv)
{
int port;
for (port = 0; port < MVPP2_MAX_PORTS; port++)
mvpp2_write(priv, MVPP22_TX_FIFO_SIZE_REG(port),
MVPP22_TX_FIFO_DATA_SIZE_3KB);
}
static void mvpp2_axi_init(struct mvpp2 *priv)
{
u32 val, rdval, wrval;
mvpp2_write(priv, MVPP22_BM_ADDR_HIGH_RLS_REG, 0x0);
/* AXI Bridge Configuration */
rdval = MVPP22_AXI_CODE_CACHE_RD_CACHE
<< MVPP22_AXI_ATTR_CACHE_OFFS;
rdval |= MVPP22_AXI_CODE_DOMAIN_OUTER_DOM
<< MVPP22_AXI_ATTR_DOMAIN_OFFS;
wrval = MVPP22_AXI_CODE_CACHE_WR_CACHE
<< MVPP22_AXI_ATTR_CACHE_OFFS;
wrval |= MVPP22_AXI_CODE_DOMAIN_OUTER_DOM
<< MVPP22_AXI_ATTR_DOMAIN_OFFS;
/* BM */
mvpp2_write(priv, MVPP22_AXI_BM_WR_ATTR_REG, wrval);
mvpp2_write(priv, MVPP22_AXI_BM_RD_ATTR_REG, rdval);
/* Descriptors */
mvpp2_write(priv, MVPP22_AXI_AGGRQ_DESCR_RD_ATTR_REG, rdval);
mvpp2_write(priv, MVPP22_AXI_TXQ_DESCR_WR_ATTR_REG, wrval);
mvpp2_write(priv, MVPP22_AXI_TXQ_DESCR_RD_ATTR_REG, rdval);
mvpp2_write(priv, MVPP22_AXI_RXQ_DESCR_WR_ATTR_REG, wrval);
/* Buffer Data */
mvpp2_write(priv, MVPP22_AXI_TX_DATA_RD_ATTR_REG, rdval);
mvpp2_write(priv, MVPP22_AXI_RX_DATA_WR_ATTR_REG, wrval);
val = MVPP22_AXI_CODE_CACHE_NON_CACHE
<< MVPP22_AXI_CODE_CACHE_OFFS;
val |= MVPP22_AXI_CODE_DOMAIN_SYSTEM
<< MVPP22_AXI_CODE_DOMAIN_OFFS;
mvpp2_write(priv, MVPP22_AXI_RD_NORMAL_CODE_REG, val);
mvpp2_write(priv, MVPP22_AXI_WR_NORMAL_CODE_REG, val);
val = MVPP22_AXI_CODE_CACHE_RD_CACHE
<< MVPP22_AXI_CODE_CACHE_OFFS;
val |= MVPP22_AXI_CODE_DOMAIN_OUTER_DOM
<< MVPP22_AXI_CODE_DOMAIN_OFFS;
mvpp2_write(priv, MVPP22_AXI_RD_SNOOP_CODE_REG, val);
val = MVPP22_AXI_CODE_CACHE_WR_CACHE
<< MVPP22_AXI_CODE_CACHE_OFFS;
val |= MVPP22_AXI_CODE_DOMAIN_OUTER_DOM
<< MVPP22_AXI_CODE_DOMAIN_OFFS;
mvpp2_write(priv, MVPP22_AXI_WR_SNOOP_CODE_REG, val);
}
/* Initialize network controller common part HW */
static int mvpp2_init(struct platform_device *pdev, struct mvpp2 *priv)
{
const struct mbus_dram_target_info *dram_target_info;
int err, i;
u32 val;
/* MBUS windows configuration */
dram_target_info = mv_mbus_dram_info();
if (dram_target_info)
mvpp2_conf_mbus_windows(dram_target_info, priv);
if (priv->hw_version == MVPP22)
mvpp2_axi_init(priv);
/* Disable HW PHY polling */
if (priv->hw_version == MVPP21) {
val = readl(priv->lms_base + MVPP2_PHY_AN_CFG0_REG);
val |= MVPP2_PHY_AN_STOP_SMI0_MASK;
writel(val, priv->lms_base + MVPP2_PHY_AN_CFG0_REG);
} else {
val = readl(priv->iface_base + MVPP22_SMI_MISC_CFG_REG);
val &= ~MVPP22_SMI_POLLING_EN;
writel(val, priv->iface_base + MVPP22_SMI_MISC_CFG_REG);
}
/* Allocate and initialize aggregated TXQs */
priv->aggr_txqs = devm_kcalloc(&pdev->dev, num_present_cpus(),
sizeof(*priv->aggr_txqs),
GFP_KERNEL);
if (!priv->aggr_txqs)
return -ENOMEM;
for_each_present_cpu(i) {
priv->aggr_txqs[i].id = i;
priv->aggr_txqs[i].size = MVPP2_AGGR_TXQ_SIZE;
err = mvpp2_aggr_txq_init(pdev, &priv->aggr_txqs[i], i, priv);
if (err < 0)
return err;
}
/* Fifo Init */
if (priv->hw_version == MVPP21) {
mvpp2_rx_fifo_init(priv);
} else {
mvpp22_rx_fifo_init(priv);
mvpp22_tx_fifo_init(priv);
}
if (priv->hw_version == MVPP21)
writel(MVPP2_EXT_GLOBAL_CTRL_DEFAULT,
priv->lms_base + MVPP2_MNG_EXTENDED_GLOBAL_CTRL_REG);
/* Allow cache snoop when transmiting packets */
mvpp2_write(priv, MVPP2_TX_SNOOP_REG, 0x1);
/* Buffer Manager initialization */
err = mvpp2_bm_init(pdev, priv);
if (err < 0)
return err;
/* Parser default initialization */
err = mvpp2_prs_default_init(pdev, priv);
if (err < 0)
return err;
/* Classifier default initialization */
mvpp2_cls_init(priv);
return 0;
}
static int mvpp2_probe(struct platform_device *pdev)
{
struct device_node *dn = pdev->dev.of_node;
struct device_node *port_node;
struct mvpp2 *priv;
struct resource *res;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
void __iomem *base;
int i;
int err;
priv = devm_kzalloc(&pdev->dev, sizeof(*priv), GFP_KERNEL);
if (!priv)
return -ENOMEM;
priv->hw_version =
(unsigned long)of_device_get_match_data(&pdev->dev);
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
base = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(base))
return PTR_ERR(base);
if (priv->hw_version == MVPP21) {
res = platform_get_resource(pdev, IORESOURCE_MEM, 1);
priv->lms_base = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(priv->lms_base))
return PTR_ERR(priv->lms_base);
} else {
res = platform_get_resource(pdev, IORESOURCE_MEM, 1);
priv->iface_base = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(priv->iface_base))
return PTR_ERR(priv->iface_base);
priv->sysctrl_base =
syscon_regmap_lookup_by_phandle(pdev->dev.of_node,
"marvell,system-controller");
if (IS_ERR(priv->sysctrl_base))
/* The system controller regmap is optional for dt
* compatibility reasons. When not provided, the
* configuration of the GoP relies on the
* firmware/bootloader.
*/
priv->sysctrl_base = NULL;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
}
for (i = 0; i < MVPP2_MAX_THREADS; i++) {
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
u32 addr_space_sz;
addr_space_sz = (priv->hw_version == MVPP21 ?
MVPP21_ADDR_SPACE_SZ : MVPP22_ADDR_SPACE_SZ);
priv->swth_base[i] = base + i * addr_space_sz;
net: mvpp2: handle register mapping and access for PPv2.2 This commit adjusts the mvpp2 driver register mapping and access logic to support PPv2.2, to handle a number of differences. Due to how the registers are laid out in memory, the Device Tree binding for the "reg" property is different: - On PPv2.1, we had a first area for the packet processor registers (common to all ports), and then one area per port. - On PPv2.2, we have a first area for the packet processor registers (common to all ports), and a second area for numerous other registers, including a large number of per-port registers In addition, on PPv2.2, the area for the common registers is split into so-called "address spaces" of 64 KB each. They allow to access per-CPU registers, where each CPU has its own copy of some registers. A few other registers, which have a single copy, also need to be accessed from those per-CPU windows if they are related to a per-CPU register. For example: - Writing to MVPP2_TXQ_NUM_REG selects a TX queue. This register is a per-CPU register, it must be accessed from the current CPU register window. - Then a write to MVPP2_TXQ_PENDING_REG, MVPP2_TXQ_DESC_ADDR_REG (and a few others) will affect the TX queue that was selected by the write to MVPP2_TXQ_NUM_REG. It must be accessed from the same CPU window as the write to the TXQ_NUM_REG. Therefore, the ->base member of 'struct mvpp2' is replaced with a ->cpu_base[] array, each entry pointing to a mapping of the per-CPU area. Since PPv2.1 doesn't have this concept of per-CPU windows, all entries in ->cpu_base[] point to the same io-remapped area. The existing mvpp2_read() and mvpp2_write() accessors use cpu_base[0], they are used for registers for which the CPU window doesn't matter. mvpp2_percpu_read() and mvpp2_percpu_write() are new accessors added to access the registers for which the CPU window does matter, which is why they take a "cpu" as argument. The driver is then changed to use mvpp2_percpu_read() and mvpp2_percpu_write() where it matters. Signed-off-by: Thomas Petazzoni <thomas.petazzoni@free-electrons.com> Signed-off-by: David S. Miller <davem@davemloft.net>
2017-03-07 23:53:13 +08:00
}
if (priv->hw_version == MVPP21)
priv->max_port_rxqs = 8;
else
priv->max_port_rxqs = 32;
priv->pp_clk = devm_clk_get(&pdev->dev, "pp_clk");
if (IS_ERR(priv->pp_clk))
return PTR_ERR(priv->pp_clk);
err = clk_prepare_enable(priv->pp_clk);
if (err < 0)
return err;
priv->gop_clk = devm_clk_get(&pdev->dev, "gop_clk");
if (IS_ERR(priv->gop_clk)) {
err = PTR_ERR(priv->gop_clk);
goto err_pp_clk;
}
err = clk_prepare_enable(priv->gop_clk);
if (err < 0)
goto err_pp_clk;
if (priv->hw_version == MVPP22) {
priv->mg_clk = devm_clk_get(&pdev->dev, "mg_clk");
if (IS_ERR(priv->mg_clk)) {
err = PTR_ERR(priv->mg_clk);
goto err_gop_clk;
}
err = clk_prepare_enable(priv->mg_clk);
if (err < 0)
goto err_gop_clk;
priv->axi_clk = devm_clk_get(&pdev->dev, "axi_clk");
if (IS_ERR(priv->axi_clk)) {
err = PTR_ERR(priv->axi_clk);
if (err == -EPROBE_DEFER)
goto err_gop_clk;
priv->axi_clk = NULL;
} else {
err = clk_prepare_enable(priv->axi_clk);
if (err < 0)
goto err_gop_clk;
}
}
/* Get system's tclk rate */
priv->tclk = clk_get_rate(priv->pp_clk);
if (priv->hw_version == MVPP22) {
err = dma_set_mask(&pdev->dev, DMA_BIT_MASK(40));
if (err)
goto err_mg_clk;
/* Sadly, the BM pools all share the same register to
* store the high 32 bits of their address. So they
* must all have the same high 32 bits, which forces
* us to restrict coherent memory to DMA_BIT_MASK(32).
*/
err = dma_set_coherent_mask(&pdev->dev, DMA_BIT_MASK(32));
if (err)
goto err_mg_clk;
}
/* Initialize network controller */
err = mvpp2_init(pdev, priv);
if (err < 0) {
dev_err(&pdev->dev, "failed to initialize controller\n");
goto err_mg_clk;
}
priv->port_count = of_get_available_child_count(dn);
if (priv->port_count == 0) {
dev_err(&pdev->dev, "no ports enabled\n");
err = -ENODEV;
goto err_mg_clk;
}
priv->port_list = devm_kcalloc(&pdev->dev, priv->port_count,
sizeof(*priv->port_list),
GFP_KERNEL);
if (!priv->port_list) {
err = -ENOMEM;
goto err_mg_clk;
}
/* Initialize ports */
i = 0;
for_each_available_child_of_node(dn, port_node) {
err = mvpp2_port_probe(pdev, port_node, priv, i);
if (err < 0)
goto err_mg_clk;
i++;
}
/* Statistics must be gathered regularly because some of them (like
* packets counters) are 32-bit registers and could overflow quite
* quickly. For instance, a 10Gb link used at full bandwidth with the
* smallest packets (64B) will overflow a 32-bit counter in less than
* 30 seconds. Then, use a workqueue to fill 64-bit counters.
*/
snprintf(priv->queue_name, sizeof(priv->queue_name),
"stats-wq-%s%s", netdev_name(priv->port_list[0]->dev),
priv->port_count > 1 ? "+" : "");
priv->stats_queue = create_singlethread_workqueue(priv->queue_name);
if (!priv->stats_queue) {
err = -ENOMEM;
goto err_mg_clk;
}
platform_set_drvdata(pdev, priv);
return 0;
err_mg_clk:
clk_disable_unprepare(priv->axi_clk);
if (priv->hw_version == MVPP22)
clk_disable_unprepare(priv->mg_clk);
err_gop_clk:
clk_disable_unprepare(priv->gop_clk);
err_pp_clk:
clk_disable_unprepare(priv->pp_clk);
return err;
}
static int mvpp2_remove(struct platform_device *pdev)
{
struct mvpp2 *priv = platform_get_drvdata(pdev);
struct device_node *dn = pdev->dev.of_node;
struct device_node *port_node;
int i = 0;
flush_workqueue(priv->stats_queue);
destroy_workqueue(priv->stats_queue);
for_each_available_child_of_node(dn, port_node) {
if (priv->port_list[i]) {
mutex_destroy(&priv->port_list[i]->gather_stats_lock);
mvpp2_port_remove(priv->port_list[i]);
}
i++;
}
for (i = 0; i < MVPP2_BM_POOLS_NUM; i++) {
struct mvpp2_bm_pool *bm_pool = &priv->bm_pools[i];
mvpp2_bm_pool_destroy(pdev, priv, bm_pool);
}
for_each_present_cpu(i) {
struct mvpp2_tx_queue *aggr_txq = &priv->aggr_txqs[i];
dma_free_coherent(&pdev->dev,
MVPP2_AGGR_TXQ_SIZE * MVPP2_DESC_ALIGNED_SIZE,
aggr_txq->descs,
aggr_txq->descs_dma);
}
clk_disable_unprepare(priv->axi_clk);
clk_disable_unprepare(priv->mg_clk);
clk_disable_unprepare(priv->pp_clk);
clk_disable_unprepare(priv->gop_clk);
return 0;
}
static const struct of_device_id mvpp2_match[] = {
{
.compatible = "marvell,armada-375-pp2",
.data = (void *)MVPP21,
},
{
.compatible = "marvell,armada-7k-pp22",
.data = (void *)MVPP22,
},
{ }
};
MODULE_DEVICE_TABLE(of, mvpp2_match);
static struct platform_driver mvpp2_driver = {
.probe = mvpp2_probe,
.remove = mvpp2_remove,
.driver = {
.name = MVPP2_DRIVER_NAME,
.of_match_table = mvpp2_match,
},
};
module_platform_driver(mvpp2_driver);
MODULE_DESCRIPTION("Marvell PPv2 Ethernet Driver - www.marvell.com");
MODULE_AUTHOR("Marcin Wojtas <mw@semihalf.com>");
MODULE_LICENSE("GPL v2");