linux/drivers/memory/omap-gpmc.c

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/*
* GPMC support functions
*
* Copyright (C) 2005-2006 Nokia Corporation
*
* Author: Juha Yrjola
*
* Copyright (C) 2009 Texas Instruments
* Added OMAP4 support - Santosh Shilimkar <santosh.shilimkar@ti.com>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#include <linux/irq.h>
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/err.h>
#include <linux/clk.h>
#include <linux/ioport.h>
#include <linux/spinlock.h>
#include <linux/io.h>
#include <linux/module.h>
#include <linux/interrupt.h>
#include <linux/platform_device.h>
#include <linux/of.h>
#include <linux/of_address.h>
#include <linux/of_mtd.h>
#include <linux/of_device.h>
#include <linux/of_platform.h>
#include <linux/omap-gpmc.h>
#include <linux/mtd/nand.h>
#include <linux/pm_runtime.h>
#include <linux/platform_data/mtd-nand-omap2.h>
#include <linux/platform_data/mtd-onenand-omap2.h>
#include <asm/mach-types.h>
#define DEVICE_NAME "omap-gpmc"
/* GPMC register offsets */
#define GPMC_REVISION 0x00
#define GPMC_SYSCONFIG 0x10
#define GPMC_SYSSTATUS 0x14
#define GPMC_IRQSTATUS 0x18
#define GPMC_IRQENABLE 0x1c
#define GPMC_TIMEOUT_CONTROL 0x40
#define GPMC_ERR_ADDRESS 0x44
#define GPMC_ERR_TYPE 0x48
#define GPMC_CONFIG 0x50
#define GPMC_STATUS 0x54
#define GPMC_PREFETCH_CONFIG1 0x1e0
#define GPMC_PREFETCH_CONFIG2 0x1e4
#define GPMC_PREFETCH_CONTROL 0x1ec
#define GPMC_PREFETCH_STATUS 0x1f0
#define GPMC_ECC_CONFIG 0x1f4
#define GPMC_ECC_CONTROL 0x1f8
#define GPMC_ECC_SIZE_CONFIG 0x1fc
#define GPMC_ECC1_RESULT 0x200
#define GPMC_ECC_BCH_RESULT_0 0x240 /* not available on OMAP2 */
#define GPMC_ECC_BCH_RESULT_1 0x244 /* not available on OMAP2 */
#define GPMC_ECC_BCH_RESULT_2 0x248 /* not available on OMAP2 */
#define GPMC_ECC_BCH_RESULT_3 0x24c /* not available on OMAP2 */
#define GPMC_ECC_BCH_RESULT_4 0x300 /* not available on OMAP2 */
#define GPMC_ECC_BCH_RESULT_5 0x304 /* not available on OMAP2 */
#define GPMC_ECC_BCH_RESULT_6 0x308 /* not available on OMAP2 */
/* GPMC ECC control settings */
#define GPMC_ECC_CTRL_ECCCLEAR 0x100
#define GPMC_ECC_CTRL_ECCDISABLE 0x000
#define GPMC_ECC_CTRL_ECCREG1 0x001
#define GPMC_ECC_CTRL_ECCREG2 0x002
#define GPMC_ECC_CTRL_ECCREG3 0x003
#define GPMC_ECC_CTRL_ECCREG4 0x004
#define GPMC_ECC_CTRL_ECCREG5 0x005
#define GPMC_ECC_CTRL_ECCREG6 0x006
#define GPMC_ECC_CTRL_ECCREG7 0x007
#define GPMC_ECC_CTRL_ECCREG8 0x008
#define GPMC_ECC_CTRL_ECCREG9 0x009
#define GPMC_CONFIG_LIMITEDADDRESS BIT(1)
#define GPMC_CONFIG2_CSEXTRADELAY BIT(7)
#define GPMC_CONFIG3_ADVEXTRADELAY BIT(7)
#define GPMC_CONFIG4_OEEXTRADELAY BIT(7)
#define GPMC_CONFIG4_WEEXTRADELAY BIT(23)
#define GPMC_CONFIG6_CYCLE2CYCLEDIFFCSEN BIT(6)
#define GPMC_CONFIG6_CYCLE2CYCLESAMECSEN BIT(7)
#define GPMC_CS0_OFFSET 0x60
#define GPMC_CS_SIZE 0x30
#define GPMC_BCH_SIZE 0x10
#define GPMC_MEM_END 0x3FFFFFFF
#define GPMC_CHUNK_SHIFT 24 /* 16 MB */
#define GPMC_SECTION_SHIFT 28 /* 128 MB */
#define CS_NUM_SHIFT 24
#define ENABLE_PREFETCH (0x1 << 7)
#define DMA_MPU_MODE 2
#define GPMC_REVISION_MAJOR(l) ((l >> 4) & 0xf)
#define GPMC_REVISION_MINOR(l) (l & 0xf)
#define GPMC_HAS_WR_ACCESS 0x1
#define GPMC_HAS_WR_DATA_MUX_BUS 0x2
#define GPMC_HAS_MUX_AAD 0x4
#define GPMC_NR_WAITPINS 4
#define GPMC_CS_CONFIG1 0x00
#define GPMC_CS_CONFIG2 0x04
#define GPMC_CS_CONFIG3 0x08
#define GPMC_CS_CONFIG4 0x0c
#define GPMC_CS_CONFIG5 0x10
#define GPMC_CS_CONFIG6 0x14
#define GPMC_CS_CONFIG7 0x18
#define GPMC_CS_NAND_COMMAND 0x1c
#define GPMC_CS_NAND_ADDRESS 0x20
#define GPMC_CS_NAND_DATA 0x24
/* Control Commands */
#define GPMC_CONFIG_RDY_BSY 0x00000001
#define GPMC_CONFIG_DEV_SIZE 0x00000002
#define GPMC_CONFIG_DEV_TYPE 0x00000003
#define GPMC_SET_IRQ_STATUS 0x00000004
#define GPMC_CONFIG1_WRAPBURST_SUPP (1 << 31)
#define GPMC_CONFIG1_READMULTIPLE_SUPP (1 << 30)
#define GPMC_CONFIG1_READTYPE_ASYNC (0 << 29)
#define GPMC_CONFIG1_READTYPE_SYNC (1 << 29)
#define GPMC_CONFIG1_WRITEMULTIPLE_SUPP (1 << 28)
#define GPMC_CONFIG1_WRITETYPE_ASYNC (0 << 27)
#define GPMC_CONFIG1_WRITETYPE_SYNC (1 << 27)
#define GPMC_CONFIG1_CLKACTIVATIONTIME(val) ((val & 3) << 25)
/** CLKACTIVATIONTIME Max Ticks */
#define GPMC_CONFIG1_CLKACTIVATIONTIME_MAX 2
#define GPMC_CONFIG1_PAGE_LEN(val) ((val & 3) << 23)
/** ATTACHEDDEVICEPAGELENGTH Max Value */
#define GPMC_CONFIG1_ATTACHEDDEVICEPAGELENGTH_MAX 2
#define GPMC_CONFIG1_WAIT_READ_MON (1 << 22)
#define GPMC_CONFIG1_WAIT_WRITE_MON (1 << 21)
#define GPMC_CONFIG1_WAIT_MON_TIME(val) ((val & 3) << 18)
/** WAITMONITORINGTIME Max Ticks */
#define GPMC_CONFIG1_WAITMONITORINGTIME_MAX 2
#define GPMC_CONFIG1_WAIT_PIN_SEL(val) ((val & 3) << 16)
#define GPMC_CONFIG1_DEVICESIZE(val) ((val & 3) << 12)
#define GPMC_CONFIG1_DEVICESIZE_16 GPMC_CONFIG1_DEVICESIZE(1)
/** DEVICESIZE Max Value */
#define GPMC_CONFIG1_DEVICESIZE_MAX 1
#define GPMC_CONFIG1_DEVICETYPE(val) ((val & 3) << 10)
#define GPMC_CONFIG1_DEVICETYPE_NOR GPMC_CONFIG1_DEVICETYPE(0)
#define GPMC_CONFIG1_MUXTYPE(val) ((val & 3) << 8)
#define GPMC_CONFIG1_TIME_PARA_GRAN (1 << 4)
#define GPMC_CONFIG1_FCLK_DIV(val) (val & 3)
#define GPMC_CONFIG1_FCLK_DIV2 (GPMC_CONFIG1_FCLK_DIV(1))
#define GPMC_CONFIG1_FCLK_DIV3 (GPMC_CONFIG1_FCLK_DIV(2))
#define GPMC_CONFIG1_FCLK_DIV4 (GPMC_CONFIG1_FCLK_DIV(3))
#define GPMC_CONFIG7_CSVALID (1 << 6)
#define GPMC_CONFIG7_BASEADDRESS_MASK 0x3f
#define GPMC_CONFIG7_CSVALID_MASK BIT(6)
#define GPMC_CONFIG7_MASKADDRESS_OFFSET 8
#define GPMC_CONFIG7_MASKADDRESS_MASK (0xf << GPMC_CONFIG7_MASKADDRESS_OFFSET)
/* All CONFIG7 bits except reserved bits */
#define GPMC_CONFIG7_MASK (GPMC_CONFIG7_BASEADDRESS_MASK | \
GPMC_CONFIG7_CSVALID_MASK | \
GPMC_CONFIG7_MASKADDRESS_MASK)
#define GPMC_DEVICETYPE_NOR 0
#define GPMC_DEVICETYPE_NAND 2
#define GPMC_CONFIG_WRITEPROTECT 0x00000010
#define WR_RD_PIN_MONITORING 0x00600000
#define GPMC_ENABLE_IRQ 0x0000000d
/* ECC commands */
#define GPMC_ECC_READ 0 /* Reset Hardware ECC for read */
#define GPMC_ECC_WRITE 1 /* Reset Hardware ECC for write */
#define GPMC_ECC_READSYN 2 /* Reset before syndrom is read back */
/* XXX: Only NAND irq has been considered,currently these are the only ones used
*/
#define GPMC_NR_IRQ 2
enum gpmc_clk_domain {
GPMC_CD_FCLK,
GPMC_CD_CLK
};
struct gpmc_cs_data {
const char *name;
#define GPMC_CS_RESERVED (1 << 0)
u32 flags;
struct resource mem;
};
struct gpmc_client_irq {
unsigned irq;
u32 bitmask;
};
/* Structure to save gpmc cs context */
struct gpmc_cs_config {
u32 config1;
u32 config2;
u32 config3;
u32 config4;
u32 config5;
u32 config6;
u32 config7;
int is_valid;
};
/*
* Structure to save/restore gpmc context
* to support core off on OMAP3
*/
struct omap3_gpmc_regs {
u32 sysconfig;
u32 irqenable;
u32 timeout_ctrl;
u32 config;
u32 prefetch_config1;
u32 prefetch_config2;
u32 prefetch_control;
struct gpmc_cs_config cs_context[GPMC_CS_NUM];
};
static struct gpmc_client_irq gpmc_client_irq[GPMC_NR_IRQ];
static struct irq_chip gpmc_irq_chip;
static int gpmc_irq_start;
static struct resource gpmc_mem_root;
static struct gpmc_cs_data gpmc_cs[GPMC_CS_NUM];
static DEFINE_SPINLOCK(gpmc_mem_lock);
/* Define chip-selects as reserved by default until probe completes */
static unsigned int gpmc_cs_num = GPMC_CS_NUM;
static unsigned int gpmc_nr_waitpins;
static struct device *gpmc_dev;
static int gpmc_irq;
static resource_size_t phys_base, mem_size;
static unsigned gpmc_capability;
static void __iomem *gpmc_base;
static struct clk *gpmc_l3_clk;
static irqreturn_t gpmc_handle_irq(int irq, void *dev);
static void gpmc_write_reg(int idx, u32 val)
{
writel_relaxed(val, gpmc_base + idx);
}
static u32 gpmc_read_reg(int idx)
{
return readl_relaxed(gpmc_base + idx);
}
void gpmc_cs_write_reg(int cs, int idx, u32 val)
{
void __iomem *reg_addr;
reg_addr = gpmc_base + GPMC_CS0_OFFSET + (cs * GPMC_CS_SIZE) + idx;
writel_relaxed(val, reg_addr);
}
static u32 gpmc_cs_read_reg(int cs, int idx)
{
void __iomem *reg_addr;
reg_addr = gpmc_base + GPMC_CS0_OFFSET + (cs * GPMC_CS_SIZE) + idx;
return readl_relaxed(reg_addr);
}
/* TODO: Add support for gpmc_fck to clock framework and use it */
static unsigned long gpmc_get_fclk_period(void)
{
unsigned long rate = clk_get_rate(gpmc_l3_clk);
rate /= 1000;
rate = 1000000000 / rate; /* In picoseconds */
return rate;
}
/**
* gpmc_get_clk_period - get period of selected clock domain in ps
* @cs Chip Select Region.
* @cd Clock Domain.
*
* GPMC_CS_CONFIG1 GPMCFCLKDIVIDER for cs has to be setup
* prior to calling this function with GPMC_CD_CLK.
*/
static unsigned long gpmc_get_clk_period(int cs, enum gpmc_clk_domain cd)
{
unsigned long tick_ps = gpmc_get_fclk_period();
u32 l;
int div;
switch (cd) {
case GPMC_CD_CLK:
/* get current clk divider */
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG1);
div = (l & 0x03) + 1;
/* get GPMC_CLK period */
tick_ps *= div;
break;
case GPMC_CD_FCLK:
/* FALL-THROUGH */
default:
break;
}
return tick_ps;
}
static unsigned int gpmc_ns_to_clk_ticks(unsigned int time_ns, int cs,
enum gpmc_clk_domain cd)
{
unsigned long tick_ps;
/* Calculate in picosecs to yield more exact results */
tick_ps = gpmc_get_clk_period(cs, cd);
return (time_ns * 1000 + tick_ps - 1) / tick_ps;
}
static unsigned int gpmc_ns_to_ticks(unsigned int time_ns)
{
return gpmc_ns_to_clk_ticks(time_ns, /* any CS */ 0, GPMC_CD_FCLK);
}
static unsigned int gpmc_ps_to_ticks(unsigned int time_ps)
{
unsigned long tick_ps;
/* Calculate in picosecs to yield more exact results */
tick_ps = gpmc_get_fclk_period();
return (time_ps + tick_ps - 1) / tick_ps;
}
unsigned int gpmc_clk_ticks_to_ns(unsigned ticks, int cs,
enum gpmc_clk_domain cd)
{
return ticks * gpmc_get_clk_period(cs, cd) / 1000;
}
unsigned int gpmc_ticks_to_ns(unsigned int ticks)
{
return gpmc_clk_ticks_to_ns(ticks, /* any CS */ 0, GPMC_CD_FCLK);
}
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
static unsigned int gpmc_ticks_to_ps(unsigned int ticks)
{
return ticks * gpmc_get_fclk_period();
}
static unsigned int gpmc_round_ps_to_ticks(unsigned int time_ps)
{
unsigned long ticks = gpmc_ps_to_ticks(time_ps);
return ticks * gpmc_get_fclk_period();
}
static inline void gpmc_cs_modify_reg(int cs, int reg, u32 mask, bool value)
{
u32 l;
l = gpmc_cs_read_reg(cs, reg);
if (value)
l |= mask;
else
l &= ~mask;
gpmc_cs_write_reg(cs, reg, l);
}
static void gpmc_cs_bool_timings(int cs, const struct gpmc_bool_timings *p)
{
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG1,
GPMC_CONFIG1_TIME_PARA_GRAN,
p->time_para_granularity);
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG2,
GPMC_CONFIG2_CSEXTRADELAY, p->cs_extra_delay);
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG3,
GPMC_CONFIG3_ADVEXTRADELAY, p->adv_extra_delay);
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG4,
GPMC_CONFIG4_OEEXTRADELAY, p->oe_extra_delay);
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG4,
GPMC_CONFIG4_OEEXTRADELAY, p->we_extra_delay);
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG6,
GPMC_CONFIG6_CYCLE2CYCLESAMECSEN,
p->cycle2cyclesamecsen);
gpmc_cs_modify_reg(cs, GPMC_CS_CONFIG6,
GPMC_CONFIG6_CYCLE2CYCLEDIFFCSEN,
p->cycle2cyclediffcsen);
}
#ifdef DEBUG
/**
* get_gpmc_timing_reg - read a timing parameter and print DTS settings for it.
* @cs: Chip Select Region
* @reg: GPMC_CS_CONFIGn register offset.
* @st_bit: Start Bit
* @end_bit: End Bit. Must be >= @st_bit.
* @ma:x Maximum parameter value (before optional @shift).
* If 0, maximum is as high as @st_bit and @end_bit allow.
* @name: DTS node name, w/o "gpmc,"
* @cd: Clock Domain of timing parameter.
* @shift: Parameter value left shifts @shift, which is then printed instead of value.
* @raw: Raw Format Option.
* raw format: gpmc,name = <value>
* tick format: gpmc,name = <value> /&zwj;* x ns -- y ns; x ticks *&zwj;/
* Where x ns -- y ns result in the same tick value.
* When @max is exceeded, "invalid" is printed inside comment.
* @noval: Parameter values equal to 0 are not printed.
* @return: Specified timing parameter (after optional @shift).
*
*/
static int get_gpmc_timing_reg(
/* timing specifiers */
int cs, int reg, int st_bit, int end_bit, int max,
const char *name, const enum gpmc_clk_domain cd,
/* value transform */
int shift,
/* format specifiers */
bool raw, bool noval)
{
u32 l;
int nr_bits;
int mask;
bool invalid;
l = gpmc_cs_read_reg(cs, reg);
nr_bits = end_bit - st_bit + 1;
mask = (1 << nr_bits) - 1;
l = (l >> st_bit) & mask;
if (!max)
max = mask;
invalid = l > max;
if (shift)
l = (shift << l);
if (noval && (l == 0))
return 0;
if (!raw) {
/* DTS tick format for timings in ns */
unsigned int time_ns;
unsigned int time_ns_min = 0;
if (l)
time_ns_min = gpmc_clk_ticks_to_ns(l - 1, cs, cd) + 1;
time_ns = gpmc_clk_ticks_to_ns(l, cs, cd);
pr_info("gpmc,%s = <%u> /* %u ns - %u ns; %i ticks%s*/\n",
name, time_ns, time_ns_min, time_ns, l,
invalid ? "; invalid " : " ");
} else {
/* raw format */
pr_info("gpmc,%s = <%u>%s\n", name, l,
invalid ? " /* invalid */" : "");
}
return l;
}
#define GPMC_PRINT_CONFIG(cs, config) \
pr_info("cs%i %s: 0x%08x\n", cs, #config, \
gpmc_cs_read_reg(cs, config))
#define GPMC_GET_RAW(reg, st, end, field) \
get_gpmc_timing_reg(cs, (reg), (st), (end), 0, field, GPMC_CD_FCLK, 0, 1, 0)
#define GPMC_GET_RAW_MAX(reg, st, end, max, field) \
get_gpmc_timing_reg(cs, (reg), (st), (end), (max), field, GPMC_CD_FCLK, 0, 1, 0)
#define GPMC_GET_RAW_BOOL(reg, st, end, field) \
get_gpmc_timing_reg(cs, (reg), (st), (end), 0, field, GPMC_CD_FCLK, 0, 1, 1)
#define GPMC_GET_RAW_SHIFT_MAX(reg, st, end, shift, max, field) \
get_gpmc_timing_reg(cs, (reg), (st), (end), (max), field, GPMC_CD_FCLK, (shift), 1, 1)
#define GPMC_GET_TICKS(reg, st, end, field) \
get_gpmc_timing_reg(cs, (reg), (st), (end), 0, field, GPMC_CD_FCLK, 0, 0, 0)
#define GPMC_GET_TICKS_CD(reg, st, end, field, cd) \
get_gpmc_timing_reg(cs, (reg), (st), (end), 0, field, (cd), 0, 0, 0)
#define GPMC_GET_TICKS_CD_MAX(reg, st, end, max, field, cd) \
get_gpmc_timing_reg(cs, (reg), (st), (end), (max), field, (cd), 0, 0, 0)
static void gpmc_show_regs(int cs, const char *desc)
{
pr_info("gpmc cs%i %s:\n", cs, desc);
GPMC_PRINT_CONFIG(cs, GPMC_CS_CONFIG1);
GPMC_PRINT_CONFIG(cs, GPMC_CS_CONFIG2);
GPMC_PRINT_CONFIG(cs, GPMC_CS_CONFIG3);
GPMC_PRINT_CONFIG(cs, GPMC_CS_CONFIG4);
GPMC_PRINT_CONFIG(cs, GPMC_CS_CONFIG5);
GPMC_PRINT_CONFIG(cs, GPMC_CS_CONFIG6);
}
/*
* Note that gpmc,wait-pin handing wrongly assumes bit 8 is available,
* see commit c9fb809.
*/
static void gpmc_cs_show_timings(int cs, const char *desc)
{
gpmc_show_regs(cs, desc);
pr_info("gpmc cs%i access configuration:\n", cs);
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 4, 4, "time-para-granularity");
GPMC_GET_RAW(GPMC_CS_CONFIG1, 8, 9, "mux-add-data");
GPMC_GET_RAW_MAX(GPMC_CS_CONFIG1, 12, 13,
GPMC_CONFIG1_DEVICESIZE_MAX, "device-width");
GPMC_GET_RAW(GPMC_CS_CONFIG1, 16, 17, "wait-pin");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 21, 21, "wait-on-write");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 22, 22, "wait-on-read");
GPMC_GET_RAW_SHIFT_MAX(GPMC_CS_CONFIG1, 23, 24, 4,
GPMC_CONFIG1_ATTACHEDDEVICEPAGELENGTH_MAX,
"burst-length");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 27, 27, "sync-write");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 28, 28, "burst-write");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 29, 29, "gpmc,sync-read");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 30, 30, "burst-read");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG1, 31, 31, "burst-wrap");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG2, 7, 7, "cs-extra-delay");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG3, 7, 7, "adv-extra-delay");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG4, 23, 23, "we-extra-delay");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG4, 7, 7, "oe-extra-delay");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG6, 7, 7, "cycle2cycle-samecsen");
GPMC_GET_RAW_BOOL(GPMC_CS_CONFIG6, 6, 6, "cycle2cycle-diffcsen");
pr_info("gpmc cs%i timings configuration:\n", cs);
GPMC_GET_TICKS(GPMC_CS_CONFIG2, 0, 3, "cs-on-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG2, 8, 12, "cs-rd-off-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG2, 16, 20, "cs-wr-off-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG3, 0, 3, "adv-on-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG3, 8, 12, "adv-rd-off-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG3, 16, 20, "adv-wr-off-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG4, 0, 3, "oe-on-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG4, 8, 12, "oe-off-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG4, 16, 19, "we-on-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG4, 24, 28, "we-off-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG5, 0, 4, "rd-cycle-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG5, 8, 12, "wr-cycle-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG5, 16, 20, "access-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG5, 24, 27, "page-burst-access-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG6, 0, 3, "bus-turnaround-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG6, 8, 11, "cycle2cycle-delay-ns");
GPMC_GET_TICKS_CD_MAX(GPMC_CS_CONFIG1, 18, 19,
GPMC_CONFIG1_WAITMONITORINGTIME_MAX,
"wait-monitoring-ns", GPMC_CD_CLK);
GPMC_GET_TICKS_CD_MAX(GPMC_CS_CONFIG1, 25, 26,
GPMC_CONFIG1_CLKACTIVATIONTIME_MAX,
"clk-activation-ns", GPMC_CD_FCLK);
GPMC_GET_TICKS(GPMC_CS_CONFIG6, 16, 19, "wr-data-mux-bus-ns");
GPMC_GET_TICKS(GPMC_CS_CONFIG6, 24, 28, "wr-access-ns");
}
#else
static inline void gpmc_cs_show_timings(int cs, const char *desc)
{
}
#endif
/**
* set_gpmc_timing_reg - set a single timing parameter for Chip Select Region.
* Caller is expected to have initialized CONFIG1 GPMCFCLKDIVIDER
* prior to calling this function with @cd equal to GPMC_CD_CLK.
*
* @cs: Chip Select Region.
* @reg: GPMC_CS_CONFIGn register offset.
* @st_bit: Start Bit
* @end_bit: End Bit. Must be >= @st_bit.
* @max: Maximum parameter value.
* If 0, maximum is as high as @st_bit and @end_bit allow.
* @time: Timing parameter in ns.
* @cd: Timing parameter clock domain.
* @name: Timing parameter name.
* @return: 0 on success, -1 on error.
*/
static int set_gpmc_timing_reg(int cs, int reg, int st_bit, int end_bit, int max,
int time, enum gpmc_clk_domain cd, const char *name)
{
u32 l;
int ticks, mask, nr_bits;
if (time == 0)
ticks = 0;
else
ticks = gpmc_ns_to_clk_ticks(time, cs, cd);
nr_bits = end_bit - st_bit + 1;
mask = (1 << nr_bits) - 1;
if (!max)
max = mask;
if (ticks > max) {
pr_err("%s: GPMC CS%d: %s %d ns, %d ticks > %d ticks\n",
__func__, cs, name, time, ticks, max);
return -1;
}
l = gpmc_cs_read_reg(cs, reg);
#ifdef DEBUG
pr_info(
"GPMC CS%d: %-17s: %3d ticks, %3lu ns (was %3i ticks) %3d ns\n",
cs, name, ticks, gpmc_get_clk_period(cs, cd) * ticks / 1000,
(l >> st_bit) & mask, time);
#endif
l &= ~(mask << st_bit);
l |= ticks << st_bit;
gpmc_cs_write_reg(cs, reg, l);
return 0;
}
#define GPMC_SET_ONE_CD_MAX(reg, st, end, max, field, cd) \
if (set_gpmc_timing_reg(cs, (reg), (st), (end), (max), \
t->field, (cd), #field) < 0) \
return -1
#define GPMC_SET_ONE(reg, st, end, field) \
GPMC_SET_ONE_CD_MAX(reg, st, end, 0, field, GPMC_CD_FCLK)
/**
* gpmc_calc_waitmonitoring_divider - calculate proper GPMCFCLKDIVIDER based on WAITMONITORINGTIME
* WAITMONITORINGTIME will be _at least_ as long as desired, i.e.
* read --> don't sample bus too early
* write --> data is longer on bus
*
* Formula:
* gpmc_clk_div + 1 = ceil(ceil(waitmonitoringtime_ns / gpmc_fclk_ns)
* / waitmonitoring_ticks)
* WAITMONITORINGTIME resulting in 0 or 1 tick with div = 1 are caught by
* div <= 0 check.
*
* @wait_monitoring: WAITMONITORINGTIME in ns.
* @return: -1 on failure to scale, else proper divider > 0.
*/
static int gpmc_calc_waitmonitoring_divider(unsigned int wait_monitoring)
{
int div = gpmc_ns_to_ticks(wait_monitoring);
div += GPMC_CONFIG1_WAITMONITORINGTIME_MAX - 1;
div /= GPMC_CONFIG1_WAITMONITORINGTIME_MAX;
if (div > 4)
return -1;
if (div <= 0)
div = 1;
return div;
}
/**
* gpmc_calc_divider - calculate GPMC_FCLK divider for sync_clk GPMC_CLK period.
* @sync_clk: GPMC_CLK period in ps.
* @return: Returns at least 1 if GPMC_FCLK can be divided to GPMC_CLK.
* Else, returns -1.
*/
int gpmc_calc_divider(unsigned int sync_clk)
{
int div = gpmc_ps_to_ticks(sync_clk);
if (div > 4)
return -1;
if (div <= 0)
div = 1;
return div;
}
/**
* gpmc_cs_set_timings - program timing parameters for Chip Select Region.
* @cs: Chip Select Region.
* @t: GPMC timing parameters.
* @s: GPMC timing settings.
* @return: 0 on success, -1 on error.
*/
int gpmc_cs_set_timings(int cs, const struct gpmc_timings *t,
const struct gpmc_settings *s)
{
int div;
u32 l;
gpmc_cs_show_timings(cs, "before gpmc_cs_set_timings");
div = gpmc_calc_divider(t->sync_clk);
if (div < 0)
ARM: OMAP: clean up some smatch warnings, fix some printk(KERN_ERR ... Resolve the following warnings from smatch: arch/arm/mach-omap2/gpmc.c:282 gpmc_cs_set_timings() info: why not propagate 'div' from gpmc_cs_calc_divider() instead of -1? arch/arm/mach-omap2/serial.c:328 omap_serial_init_port() error: 'pdev' dereferencing possible ERR_PTR() arch/arm/mach-omap2/timer.c:213 omap2_gp_clockevent_init() Error invalid range 4096 to -1 arch/arm/mach-omap2/gpio.c:63 omap2_gpio_dev_init() warn: possible memory leak of 'pdata' arch/arm/mach-omap2/omap_hwmod.c:1478 _assert_hardreset() warn: assigning -22 to unsigned variable 'ret' arch/arm/mach-omap2/omap_hwmod.c:1487 _assert_hardreset() warn: 4294963201 is more than 255 (max '(ret)' can be) so this is always the same. arch/arm/mach-omap2/omap_hwmod.c:1545 _read_hardreset() warn: assigning -22 to unsigned variable 'ret' arch/arm/mach-omap2/omap_hwmod.c:1554 _read_hardreset() warn: 4294963201 is more than 255 (max '(ret)' can be) so this is always the same. arch/arm/mach-omap2/dpll3xxx.c:629 omap3_clkoutx2_recalc() error: we previously assumed 'pclk' could be null (see line 627) arch/arm/mach-omap2/board-n8x0.c:422 n8x0_mmc_late_init() Error invalid range 14 to 13 arch/arm/mach-omap1/leds-h2p2-debug.c:71 h2p2_dbg_leds_event() error: potentially derefencing uninitialized 'fpga'. arch/arm/plat-omap/mux.c:79 omap_cfg_reg() Error invalid range 4096 to -1 Thanks to Tony Lindgren <tony@atomide.com> for pointing out that BUG() can be disabled. The changes in the first version that removed the subsequent return() after BUG() states have been dropped. Signed-off-by: Paul Walmsley <paul@pwsan.com> Cc: Tony Lindgren <tony@atomide.com>
2012-08-03 23:21:10 +08:00
return div;
/*
* See if we need to change the divider for waitmonitoringtime.
*
* Calculate GPMCFCLKDIVIDER independent of gpmc,sync-clk-ps in DT for
* pure asynchronous accesses, i.e. both read and write asynchronous.
* However, only do so if WAITMONITORINGTIME is actually used, i.e.
* either WAITREADMONITORING or WAITWRITEMONITORING is set.
*
* This statement must not change div to scale async WAITMONITORINGTIME
* to protect mixed synchronous and asynchronous accesses.
*
* We raise an error later if WAITMONITORINGTIME does not fit.
*/
if (!s->sync_read && !s->sync_write &&
(s->wait_on_read || s->wait_on_write)
) {
div = gpmc_calc_waitmonitoring_divider(t->wait_monitoring);
if (div < 0) {
pr_err("%s: waitmonitoringtime %3d ns too large for greatest gpmcfclkdivider.\n",
__func__,
t->wait_monitoring
);
return -1;
}
}
GPMC_SET_ONE(GPMC_CS_CONFIG2, 0, 3, cs_on);
GPMC_SET_ONE(GPMC_CS_CONFIG2, 8, 12, cs_rd_off);
GPMC_SET_ONE(GPMC_CS_CONFIG2, 16, 20, cs_wr_off);
GPMC_SET_ONE(GPMC_CS_CONFIG3, 0, 3, adv_on);
GPMC_SET_ONE(GPMC_CS_CONFIG3, 8, 12, adv_rd_off);
GPMC_SET_ONE(GPMC_CS_CONFIG3, 16, 20, adv_wr_off);
GPMC_SET_ONE(GPMC_CS_CONFIG4, 0, 3, oe_on);
GPMC_SET_ONE(GPMC_CS_CONFIG4, 8, 12, oe_off);
GPMC_SET_ONE(GPMC_CS_CONFIG4, 16, 19, we_on);
GPMC_SET_ONE(GPMC_CS_CONFIG4, 24, 28, we_off);
GPMC_SET_ONE(GPMC_CS_CONFIG5, 0, 4, rd_cycle);
GPMC_SET_ONE(GPMC_CS_CONFIG5, 8, 12, wr_cycle);
GPMC_SET_ONE(GPMC_CS_CONFIG5, 16, 20, access);
GPMC_SET_ONE(GPMC_CS_CONFIG5, 24, 27, page_burst_access);
GPMC_SET_ONE(GPMC_CS_CONFIG6, 0, 3, bus_turnaround);
GPMC_SET_ONE(GPMC_CS_CONFIG6, 8, 11, cycle2cycle_delay);
if (gpmc_capability & GPMC_HAS_WR_DATA_MUX_BUS)
GPMC_SET_ONE(GPMC_CS_CONFIG6, 16, 19, wr_data_mux_bus);
if (gpmc_capability & GPMC_HAS_WR_ACCESS)
GPMC_SET_ONE(GPMC_CS_CONFIG6, 24, 28, wr_access);
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG1);
l &= ~0x03;
l |= (div - 1);
gpmc_cs_write_reg(cs, GPMC_CS_CONFIG1, l);
GPMC_SET_ONE_CD_MAX(GPMC_CS_CONFIG1, 18, 19,
GPMC_CONFIG1_WAITMONITORINGTIME_MAX,
wait_monitoring, GPMC_CD_CLK);
GPMC_SET_ONE_CD_MAX(GPMC_CS_CONFIG1, 25, 26,
GPMC_CONFIG1_CLKACTIVATIONTIME_MAX,
clk_activation, GPMC_CD_FCLK);
#ifdef DEBUG
pr_info("GPMC CS%d CLK period is %lu ns (div %d)\n",
cs, (div * gpmc_get_fclk_period()) / 1000, div);
#endif
gpmc_cs_bool_timings(cs, &t->bool_timings);
gpmc_cs_show_timings(cs, "after gpmc_cs_set_timings");
return 0;
}
static int gpmc_cs_set_memconf(int cs, u32 base, u32 size)
{
u32 l;
u32 mask;
/*
* Ensure that base address is aligned on a
* boundary equal to or greater than size.
*/
if (base & (size - 1))
return -EINVAL;
base >>= GPMC_CHUNK_SHIFT;
mask = (1 << GPMC_SECTION_SHIFT) - size;
mask >>= GPMC_CHUNK_SHIFT;
mask <<= GPMC_CONFIG7_MASKADDRESS_OFFSET;
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG7);
l &= ~GPMC_CONFIG7_MASK;
l |= base & GPMC_CONFIG7_BASEADDRESS_MASK;
l |= mask & GPMC_CONFIG7_MASKADDRESS_MASK;
l |= GPMC_CONFIG7_CSVALID;
gpmc_cs_write_reg(cs, GPMC_CS_CONFIG7, l);
return 0;
}
static void gpmc_cs_enable_mem(int cs)
{
u32 l;
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG7);
l |= GPMC_CONFIG7_CSVALID;
gpmc_cs_write_reg(cs, GPMC_CS_CONFIG7, l);
}
static void gpmc_cs_disable_mem(int cs)
{
u32 l;
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG7);
l &= ~GPMC_CONFIG7_CSVALID;
gpmc_cs_write_reg(cs, GPMC_CS_CONFIG7, l);
}
static void gpmc_cs_get_memconf(int cs, u32 *base, u32 *size)
{
u32 l;
u32 mask;
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG7);
*base = (l & 0x3f) << GPMC_CHUNK_SHIFT;
mask = (l >> 8) & 0x0f;
*size = (1 << GPMC_SECTION_SHIFT) - (mask << GPMC_CHUNK_SHIFT);
}
static int gpmc_cs_mem_enabled(int cs)
{
u32 l;
l = gpmc_cs_read_reg(cs, GPMC_CS_CONFIG7);
return l & GPMC_CONFIG7_CSVALID;
}
static void gpmc_cs_set_reserved(int cs, int reserved)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
gpmc->flags |= GPMC_CS_RESERVED;
}
static bool gpmc_cs_reserved(int cs)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
return gpmc->flags & GPMC_CS_RESERVED;
}
static void gpmc_cs_set_name(int cs, const char *name)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
gpmc->name = name;
}
static const char *gpmc_cs_get_name(int cs)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
return gpmc->name;
}
static unsigned long gpmc_mem_align(unsigned long size)
{
int order;
size = (size - 1) >> (GPMC_CHUNK_SHIFT - 1);
order = GPMC_CHUNK_SHIFT - 1;
do {
size >>= 1;
order++;
} while (size);
size = 1 << order;
return size;
}
static int gpmc_cs_insert_mem(int cs, unsigned long base, unsigned long size)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
struct resource *res = &gpmc->mem;
int r;
size = gpmc_mem_align(size);
spin_lock(&gpmc_mem_lock);
res->start = base;
res->end = base + size - 1;
r = request_resource(&gpmc_mem_root, res);
spin_unlock(&gpmc_mem_lock);
return r;
}
static int gpmc_cs_delete_mem(int cs)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
struct resource *res = &gpmc->mem;
int r;
spin_lock(&gpmc_mem_lock);
r = release_resource(res);
res->start = 0;
res->end = 0;
spin_unlock(&gpmc_mem_lock);
return r;
}
/**
* gpmc_cs_remap - remaps a chip-select physical base address
* @cs: chip-select to remap
* @base: physical base address to re-map chip-select to
*
* Re-maps a chip-select to a new physical base address specified by
* "base". Returns 0 on success and appropriate negative error code
* on failure.
*/
static int gpmc_cs_remap(int cs, u32 base)
{
int ret;
u32 old_base, size;
if (cs > gpmc_cs_num) {
pr_err("%s: requested chip-select is disabled\n", __func__);
return -ENODEV;
}
/*
* Make sure we ignore any device offsets from the GPMC partition
* allocated for the chip select and that the new base confirms
* to the GPMC 16MB minimum granularity.
*/
base &= ~(SZ_16M - 1);
gpmc_cs_get_memconf(cs, &old_base, &size);
if (base == old_base)
return 0;
ret = gpmc_cs_delete_mem(cs);
if (ret < 0)
return ret;
ret = gpmc_cs_insert_mem(cs, base, size);
if (ret < 0)
return ret;
ret = gpmc_cs_set_memconf(cs, base, size);
return ret;
}
int gpmc_cs_request(int cs, unsigned long size, unsigned long *base)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
struct resource *res = &gpmc->mem;
int r = -1;
if (cs > gpmc_cs_num) {
pr_err("%s: requested chip-select is disabled\n", __func__);
return -ENODEV;
}
size = gpmc_mem_align(size);
if (size > (1 << GPMC_SECTION_SHIFT))
return -ENOMEM;
spin_lock(&gpmc_mem_lock);
if (gpmc_cs_reserved(cs)) {
r = -EBUSY;
goto out;
}
if (gpmc_cs_mem_enabled(cs))
r = adjust_resource(res, res->start & ~(size - 1), size);
if (r < 0)
r = allocate_resource(&gpmc_mem_root, res, size, 0, ~0,
size, NULL, NULL);
if (r < 0)
goto out;
/* Disable CS while changing base address and size mask */
gpmc_cs_disable_mem(cs);
r = gpmc_cs_set_memconf(cs, res->start, resource_size(res));
if (r < 0) {
release_resource(res);
goto out;
}
/* Enable CS */
gpmc_cs_enable_mem(cs);
*base = res->start;
gpmc_cs_set_reserved(cs, 1);
out:
spin_unlock(&gpmc_mem_lock);
return r;
}
EXPORT_SYMBOL(gpmc_cs_request);
void gpmc_cs_free(int cs)
{
struct gpmc_cs_data *gpmc = &gpmc_cs[cs];
struct resource *res = &gpmc->mem;
spin_lock(&gpmc_mem_lock);
if (cs >= gpmc_cs_num || cs < 0 || !gpmc_cs_reserved(cs)) {
printk(KERN_ERR "Trying to free non-reserved GPMC CS%d\n", cs);
BUG();
spin_unlock(&gpmc_mem_lock);
return;
}
gpmc_cs_disable_mem(cs);
if (res->flags)
release_resource(res);
gpmc_cs_set_reserved(cs, 0);
spin_unlock(&gpmc_mem_lock);
}
EXPORT_SYMBOL(gpmc_cs_free);
/**
* gpmc_configure - write request to configure gpmc
* @cmd: command type
* @wval: value to write
* @return status of the operation
*/
int gpmc_configure(int cmd, int wval)
{
u32 regval;
switch (cmd) {
case GPMC_ENABLE_IRQ:
gpmc_write_reg(GPMC_IRQENABLE, wval);
break;
case GPMC_SET_IRQ_STATUS:
gpmc_write_reg(GPMC_IRQSTATUS, wval);
break;
case GPMC_CONFIG_WP:
regval = gpmc_read_reg(GPMC_CONFIG);
if (wval)
regval &= ~GPMC_CONFIG_WRITEPROTECT; /* WP is ON */
else
regval |= GPMC_CONFIG_WRITEPROTECT; /* WP is OFF */
gpmc_write_reg(GPMC_CONFIG, regval);
break;
default:
pr_err("%s: command not supported\n", __func__);
return -EINVAL;
}
return 0;
}
EXPORT_SYMBOL(gpmc_configure);
void gpmc_update_nand_reg(struct gpmc_nand_regs *reg, int cs)
{
int i;
reg->gpmc_status = gpmc_base + GPMC_STATUS;
reg->gpmc_nand_command = gpmc_base + GPMC_CS0_OFFSET +
GPMC_CS_NAND_COMMAND + GPMC_CS_SIZE * cs;
reg->gpmc_nand_address = gpmc_base + GPMC_CS0_OFFSET +
GPMC_CS_NAND_ADDRESS + GPMC_CS_SIZE * cs;
reg->gpmc_nand_data = gpmc_base + GPMC_CS0_OFFSET +
GPMC_CS_NAND_DATA + GPMC_CS_SIZE * cs;
reg->gpmc_prefetch_config1 = gpmc_base + GPMC_PREFETCH_CONFIG1;
reg->gpmc_prefetch_config2 = gpmc_base + GPMC_PREFETCH_CONFIG2;
reg->gpmc_prefetch_control = gpmc_base + GPMC_PREFETCH_CONTROL;
reg->gpmc_prefetch_status = gpmc_base + GPMC_PREFETCH_STATUS;
reg->gpmc_ecc_config = gpmc_base + GPMC_ECC_CONFIG;
reg->gpmc_ecc_control = gpmc_base + GPMC_ECC_CONTROL;
reg->gpmc_ecc_size_config = gpmc_base + GPMC_ECC_SIZE_CONFIG;
reg->gpmc_ecc1_result = gpmc_base + GPMC_ECC1_RESULT;
for (i = 0; i < GPMC_BCH_NUM_REMAINDER; i++) {
reg->gpmc_bch_result0[i] = gpmc_base + GPMC_ECC_BCH_RESULT_0 +
GPMC_BCH_SIZE * i;
reg->gpmc_bch_result1[i] = gpmc_base + GPMC_ECC_BCH_RESULT_1 +
GPMC_BCH_SIZE * i;
reg->gpmc_bch_result2[i] = gpmc_base + GPMC_ECC_BCH_RESULT_2 +
GPMC_BCH_SIZE * i;
reg->gpmc_bch_result3[i] = gpmc_base + GPMC_ECC_BCH_RESULT_3 +
GPMC_BCH_SIZE * i;
reg->gpmc_bch_result4[i] = gpmc_base + GPMC_ECC_BCH_RESULT_4 +
i * GPMC_BCH_SIZE;
reg->gpmc_bch_result5[i] = gpmc_base + GPMC_ECC_BCH_RESULT_5 +
i * GPMC_BCH_SIZE;
reg->gpmc_bch_result6[i] = gpmc_base + GPMC_ECC_BCH_RESULT_6 +
i * GPMC_BCH_SIZE;
}
}
int gpmc_get_client_irq(unsigned irq_config)
{
int i;
if (hweight32(irq_config) > 1)
return 0;
for (i = 0; i < GPMC_NR_IRQ; i++)
if (gpmc_client_irq[i].bitmask & irq_config)
return gpmc_client_irq[i].irq;
return 0;
}
static int gpmc_irq_endis(unsigned irq, bool endis)
{
int i;
u32 regval;
for (i = 0; i < GPMC_NR_IRQ; i++)
if (irq == gpmc_client_irq[i].irq) {
regval = gpmc_read_reg(GPMC_IRQENABLE);
if (endis)
regval |= gpmc_client_irq[i].bitmask;
else
regval &= ~gpmc_client_irq[i].bitmask;
gpmc_write_reg(GPMC_IRQENABLE, regval);
break;
}
return 0;
}
static void gpmc_irq_disable(struct irq_data *p)
{
gpmc_irq_endis(p->irq, false);
}
static void gpmc_irq_enable(struct irq_data *p)
{
gpmc_irq_endis(p->irq, true);
}
static void gpmc_irq_noop(struct irq_data *data) { }
static unsigned int gpmc_irq_noop_ret(struct irq_data *data) { return 0; }
static int gpmc_setup_irq(void)
{
int i;
u32 regval;
if (!gpmc_irq)
return -EINVAL;
gpmc_irq_start = irq_alloc_descs(-1, 0, GPMC_NR_IRQ, 0);
if (gpmc_irq_start < 0) {
pr_err("irq_alloc_descs failed\n");
return gpmc_irq_start;
}
gpmc_irq_chip.name = "gpmc";
gpmc_irq_chip.irq_startup = gpmc_irq_noop_ret;
gpmc_irq_chip.irq_enable = gpmc_irq_enable;
gpmc_irq_chip.irq_disable = gpmc_irq_disable;
gpmc_irq_chip.irq_shutdown = gpmc_irq_noop;
gpmc_irq_chip.irq_ack = gpmc_irq_noop;
gpmc_irq_chip.irq_mask = gpmc_irq_noop;
gpmc_irq_chip.irq_unmask = gpmc_irq_noop;
gpmc_client_irq[0].bitmask = GPMC_IRQ_FIFOEVENTENABLE;
gpmc_client_irq[1].bitmask = GPMC_IRQ_COUNT_EVENT;
for (i = 0; i < GPMC_NR_IRQ; i++) {
gpmc_client_irq[i].irq = gpmc_irq_start + i;
irq_set_chip_and_handler(gpmc_client_irq[i].irq,
&gpmc_irq_chip, handle_simple_irq);
set_irq_flags(gpmc_client_irq[i].irq,
IRQF_VALID | IRQF_NOAUTOEN);
}
/* Disable interrupts */
gpmc_write_reg(GPMC_IRQENABLE, 0);
/* clear interrupts */
regval = gpmc_read_reg(GPMC_IRQSTATUS);
gpmc_write_reg(GPMC_IRQSTATUS, regval);
return request_irq(gpmc_irq, gpmc_handle_irq, 0, "gpmc", NULL);
}
static int gpmc_free_irq(void)
{
int i;
if (gpmc_irq)
free_irq(gpmc_irq, NULL);
for (i = 0; i < GPMC_NR_IRQ; i++) {
irq_set_handler(gpmc_client_irq[i].irq, NULL);
irq_set_chip(gpmc_client_irq[i].irq, &no_irq_chip);
irq_modify_status(gpmc_client_irq[i].irq, 0, 0);
}
irq_free_descs(gpmc_irq_start, GPMC_NR_IRQ);
return 0;
}
static void gpmc_mem_exit(void)
{
int cs;
for (cs = 0; cs < gpmc_cs_num; cs++) {
if (!gpmc_cs_mem_enabled(cs))
continue;
gpmc_cs_delete_mem(cs);
}
}
static void gpmc_mem_init(void)
{
int cs;
/*
* The first 1MB of GPMC address space is typically mapped to
* the internal ROM. Never allocate the first page, to
* facilitate bug detection; even if we didn't boot from ROM.
*/
gpmc_mem_root.start = SZ_1M;
gpmc_mem_root.end = GPMC_MEM_END;
/* Reserve all regions that has been set up by bootloader */
for (cs = 0; cs < gpmc_cs_num; cs++) {
u32 base, size;
if (!gpmc_cs_mem_enabled(cs))
continue;
gpmc_cs_get_memconf(cs, &base, &size);
if (gpmc_cs_insert_mem(cs, base, size)) {
pr_warn("%s: disabling cs %d mapped at 0x%x-0x%x\n",
__func__, cs, base, base + size);
gpmc_cs_disable_mem(cs);
}
}
}
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
static u32 gpmc_round_ps_to_sync_clk(u32 time_ps, u32 sync_clk)
{
u32 temp;
int div;
div = gpmc_calc_divider(sync_clk);
temp = gpmc_ps_to_ticks(time_ps);
temp = (temp + div - 1) / div;
return gpmc_ticks_to_ps(temp * div);
}
/* XXX: can the cycles be avoided ? */
static int gpmc_calc_sync_read_timings(struct gpmc_timings *gpmc_t,
struct gpmc_device_timings *dev_t,
bool mux)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
{
u32 temp;
/* adv_rd_off */
temp = dev_t->t_avdp_r;
/* XXX: mux check required ? */
if (mux) {
/* XXX: t_avdp not to be required for sync, only added for tusb
* this indirectly necessitates requirement of t_avdp_r and
* t_avdp_w instead of having a single t_avdp
*/
temp = max_t(u32, temp, gpmc_t->clk_activation + dev_t->t_avdh);
temp = max_t(u32, gpmc_t->adv_on + gpmc_ticks_to_ps(1), temp);
}
gpmc_t->adv_rd_off = gpmc_round_ps_to_ticks(temp);
/* oe_on */
temp = dev_t->t_oeasu; /* XXX: remove this ? */
if (mux) {
temp = max_t(u32, temp, gpmc_t->clk_activation + dev_t->t_ach);
temp = max_t(u32, temp, gpmc_t->adv_rd_off +
gpmc_ticks_to_ps(dev_t->cyc_aavdh_oe));
}
gpmc_t->oe_on = gpmc_round_ps_to_ticks(temp);
/* access */
/* XXX: any scope for improvement ?, by combining oe_on
* and clk_activation, need to check whether
* access = clk_activation + round to sync clk ?
*/
temp = max_t(u32, dev_t->t_iaa, dev_t->cyc_iaa * gpmc_t->sync_clk);
temp += gpmc_t->clk_activation;
if (dev_t->cyc_oe)
temp = max_t(u32, temp, gpmc_t->oe_on +
gpmc_ticks_to_ps(dev_t->cyc_oe));
gpmc_t->access = gpmc_round_ps_to_ticks(temp);
gpmc_t->oe_off = gpmc_t->access + gpmc_ticks_to_ps(1);
gpmc_t->cs_rd_off = gpmc_t->oe_off;
/* rd_cycle */
temp = max_t(u32, dev_t->t_cez_r, dev_t->t_oez);
temp = gpmc_round_ps_to_sync_clk(temp, gpmc_t->sync_clk) +
gpmc_t->access;
/* XXX: barter t_ce_rdyz with t_cez_r ? */
if (dev_t->t_ce_rdyz)
temp = max_t(u32, temp, gpmc_t->cs_rd_off + dev_t->t_ce_rdyz);
gpmc_t->rd_cycle = gpmc_round_ps_to_ticks(temp);
return 0;
}
static int gpmc_calc_sync_write_timings(struct gpmc_timings *gpmc_t,
struct gpmc_device_timings *dev_t,
bool mux)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
{
u32 temp;
/* adv_wr_off */
temp = dev_t->t_avdp_w;
if (mux) {
temp = max_t(u32, temp,
gpmc_t->clk_activation + dev_t->t_avdh);
temp = max_t(u32, gpmc_t->adv_on + gpmc_ticks_to_ps(1), temp);
}
gpmc_t->adv_wr_off = gpmc_round_ps_to_ticks(temp);
/* wr_data_mux_bus */
temp = max_t(u32, dev_t->t_weasu,
gpmc_t->clk_activation + dev_t->t_rdyo);
/* XXX: shouldn't mux be kept as a whole for wr_data_mux_bus ?,
* and in that case remember to handle we_on properly
*/
if (mux) {
temp = max_t(u32, temp,
gpmc_t->adv_wr_off + dev_t->t_aavdh);
temp = max_t(u32, temp, gpmc_t->adv_wr_off +
gpmc_ticks_to_ps(dev_t->cyc_aavdh_we));
}
gpmc_t->wr_data_mux_bus = gpmc_round_ps_to_ticks(temp);
/* we_on */
if (gpmc_capability & GPMC_HAS_WR_DATA_MUX_BUS)
gpmc_t->we_on = gpmc_round_ps_to_ticks(dev_t->t_weasu);
else
gpmc_t->we_on = gpmc_t->wr_data_mux_bus;
/* wr_access */
/* XXX: gpmc_capability check reqd ? , even if not, will not harm */
gpmc_t->wr_access = gpmc_t->access;
/* we_off */
temp = gpmc_t->we_on + dev_t->t_wpl;
temp = max_t(u32, temp,
gpmc_t->wr_access + gpmc_ticks_to_ps(1));
temp = max_t(u32, temp,
gpmc_t->we_on + gpmc_ticks_to_ps(dev_t->cyc_wpl));
gpmc_t->we_off = gpmc_round_ps_to_ticks(temp);
gpmc_t->cs_wr_off = gpmc_round_ps_to_ticks(gpmc_t->we_off +
dev_t->t_wph);
/* wr_cycle */
temp = gpmc_round_ps_to_sync_clk(dev_t->t_cez_w, gpmc_t->sync_clk);
temp += gpmc_t->wr_access;
/* XXX: barter t_ce_rdyz with t_cez_w ? */
if (dev_t->t_ce_rdyz)
temp = max_t(u32, temp,
gpmc_t->cs_wr_off + dev_t->t_ce_rdyz);
gpmc_t->wr_cycle = gpmc_round_ps_to_ticks(temp);
return 0;
}
static int gpmc_calc_async_read_timings(struct gpmc_timings *gpmc_t,
struct gpmc_device_timings *dev_t,
bool mux)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
{
u32 temp;
/* adv_rd_off */
temp = dev_t->t_avdp_r;
if (mux)
temp = max_t(u32, gpmc_t->adv_on + gpmc_ticks_to_ps(1), temp);
gpmc_t->adv_rd_off = gpmc_round_ps_to_ticks(temp);
/* oe_on */
temp = dev_t->t_oeasu;
if (mux)
temp = max_t(u32, temp,
gpmc_t->adv_rd_off + dev_t->t_aavdh);
gpmc_t->oe_on = gpmc_round_ps_to_ticks(temp);
/* access */
temp = max_t(u32, dev_t->t_iaa, /* XXX: remove t_iaa in async ? */
gpmc_t->oe_on + dev_t->t_oe);
temp = max_t(u32, temp,
gpmc_t->cs_on + dev_t->t_ce);
temp = max_t(u32, temp,
gpmc_t->adv_on + dev_t->t_aa);
gpmc_t->access = gpmc_round_ps_to_ticks(temp);
gpmc_t->oe_off = gpmc_t->access + gpmc_ticks_to_ps(1);
gpmc_t->cs_rd_off = gpmc_t->oe_off;
/* rd_cycle */
temp = max_t(u32, dev_t->t_rd_cycle,
gpmc_t->cs_rd_off + dev_t->t_cez_r);
temp = max_t(u32, temp, gpmc_t->oe_off + dev_t->t_oez);
gpmc_t->rd_cycle = gpmc_round_ps_to_ticks(temp);
return 0;
}
static int gpmc_calc_async_write_timings(struct gpmc_timings *gpmc_t,
struct gpmc_device_timings *dev_t,
bool mux)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
{
u32 temp;
/* adv_wr_off */
temp = dev_t->t_avdp_w;
if (mux)
temp = max_t(u32, gpmc_t->adv_on + gpmc_ticks_to_ps(1), temp);
gpmc_t->adv_wr_off = gpmc_round_ps_to_ticks(temp);
/* wr_data_mux_bus */
temp = dev_t->t_weasu;
if (mux) {
temp = max_t(u32, temp, gpmc_t->adv_wr_off + dev_t->t_aavdh);
temp = max_t(u32, temp, gpmc_t->adv_wr_off +
gpmc_ticks_to_ps(dev_t->cyc_aavdh_we));
}
gpmc_t->wr_data_mux_bus = gpmc_round_ps_to_ticks(temp);
/* we_on */
if (gpmc_capability & GPMC_HAS_WR_DATA_MUX_BUS)
gpmc_t->we_on = gpmc_round_ps_to_ticks(dev_t->t_weasu);
else
gpmc_t->we_on = gpmc_t->wr_data_mux_bus;
/* we_off */
temp = gpmc_t->we_on + dev_t->t_wpl;
gpmc_t->we_off = gpmc_round_ps_to_ticks(temp);
gpmc_t->cs_wr_off = gpmc_round_ps_to_ticks(gpmc_t->we_off +
dev_t->t_wph);
/* wr_cycle */
temp = max_t(u32, dev_t->t_wr_cycle,
gpmc_t->cs_wr_off + dev_t->t_cez_w);
gpmc_t->wr_cycle = gpmc_round_ps_to_ticks(temp);
return 0;
}
static int gpmc_calc_sync_common_timings(struct gpmc_timings *gpmc_t,
struct gpmc_device_timings *dev_t)
{
u32 temp;
gpmc_t->sync_clk = gpmc_calc_divider(dev_t->clk) *
gpmc_get_fclk_period();
gpmc_t->page_burst_access = gpmc_round_ps_to_sync_clk(
dev_t->t_bacc,
gpmc_t->sync_clk);
temp = max_t(u32, dev_t->t_ces, dev_t->t_avds);
gpmc_t->clk_activation = gpmc_round_ps_to_ticks(temp);
if (gpmc_calc_divider(gpmc_t->sync_clk) != 1)
return 0;
if (dev_t->ce_xdelay)
gpmc_t->bool_timings.cs_extra_delay = true;
if (dev_t->avd_xdelay)
gpmc_t->bool_timings.adv_extra_delay = true;
if (dev_t->oe_xdelay)
gpmc_t->bool_timings.oe_extra_delay = true;
if (dev_t->we_xdelay)
gpmc_t->bool_timings.we_extra_delay = true;
return 0;
}
static int gpmc_calc_common_timings(struct gpmc_timings *gpmc_t,
struct gpmc_device_timings *dev_t,
bool sync)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
{
u32 temp;
/* cs_on */
gpmc_t->cs_on = gpmc_round_ps_to_ticks(dev_t->t_ceasu);
/* adv_on */
temp = dev_t->t_avdasu;
if (dev_t->t_ce_avd)
temp = max_t(u32, temp,
gpmc_t->cs_on + dev_t->t_ce_avd);
gpmc_t->adv_on = gpmc_round_ps_to_ticks(temp);
if (sync)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
gpmc_calc_sync_common_timings(gpmc_t, dev_t);
return 0;
}
/* TODO: remove this function once all peripherals are confirmed to
* work with generic timing. Simultaneously gpmc_cs_set_timings()
* has to be modified to handle timings in ps instead of ns
*/
static void gpmc_convert_ps_to_ns(struct gpmc_timings *t)
{
t->cs_on /= 1000;
t->cs_rd_off /= 1000;
t->cs_wr_off /= 1000;
t->adv_on /= 1000;
t->adv_rd_off /= 1000;
t->adv_wr_off /= 1000;
t->we_on /= 1000;
t->we_off /= 1000;
t->oe_on /= 1000;
t->oe_off /= 1000;
t->page_burst_access /= 1000;
t->access /= 1000;
t->rd_cycle /= 1000;
t->wr_cycle /= 1000;
t->bus_turnaround /= 1000;
t->cycle2cycle_delay /= 1000;
t->wait_monitoring /= 1000;
t->clk_activation /= 1000;
t->wr_access /= 1000;
t->wr_data_mux_bus /= 1000;
}
int gpmc_calc_timings(struct gpmc_timings *gpmc_t,
struct gpmc_settings *gpmc_s,
struct gpmc_device_timings *dev_t)
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
{
bool mux = false, sync = false;
if (gpmc_s) {
mux = gpmc_s->mux_add_data ? true : false;
sync = (gpmc_s->sync_read || gpmc_s->sync_write);
}
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
memset(gpmc_t, 0, sizeof(*gpmc_t));
gpmc_calc_common_timings(gpmc_t, dev_t, sync);
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
if (gpmc_s && gpmc_s->sync_read)
gpmc_calc_sync_read_timings(gpmc_t, dev_t, mux);
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
else
gpmc_calc_async_read_timings(gpmc_t, dev_t, mux);
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
if (gpmc_s && gpmc_s->sync_write)
gpmc_calc_sync_write_timings(gpmc_t, dev_t, mux);
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
else
gpmc_calc_async_write_timings(gpmc_t, dev_t, mux);
ARM: OMAP2+: gpmc: generic timing calculation Presently there are three peripherals that gets it timing by runtime calculation. Those peripherals can work with frequency scaling that affects gpmc clock. But timing calculation for them are in different ways. Here a generic runtime calculation method is proposed. Input to this function were selected so that they represent timing variables that are present in peripheral datasheets. Motive behind this was to achieve DT bindings for the inputs as is. Even though a few of the tusb6010 timings could not be made directly related to timings normally found on peripherals, expressions used were translated to those that could be justified. There are possibilities of improving the calculations, like calculating timing for read & write operations in a more similar way. Expressions derived here were tested for async onenand on omap3evm (as vanilla Kernel does not have omap3evm onenand support, local patch was used). Other peripherals, tusb6010, smc91x calculations were validated by simulating on omap3evm. Regarding "we_on" for onenand async, it was found that even for muxed address/data, it need not be greater than "adv_wr_off", but rather could be derived from write setup time for peripheral from start of access time, hence would more be in line with peripheral timings. With this method it was working fine. If it is required in some cases to have "we_on" same as "wr_data_mux_bus" (i.e. greater than "adv_wr_off"), another variable could be added to indicate it. But such a requirement is not expected though. It has been observed that "adv_rd_off" & "adv_wr_off" are currently calculated by adding an offset over "oe_on" and "we_on" respectively in the case of smc91x. But peripheral datasheet does not specify so and so "adv_rd(wr)_off" has been derived (to be specific, made ignorant of "oe_on" and "we_on") observing datasheet rather than adding an offset. Hence this generic routine is expected to work for smc91x (91C96 RX51 board). This was verified on smsc911x (9220 on OMAP3EVM) - a similar ethernet controller. Timings are calculated in ps to prevent rounding errors and converted to ns at final stage so that these values can be directly fed to gpmc_cs_set_timings(). gpmc_cs_set_timings() would be modified to take ps once all custom timing routines are replaced by the generic routine, at the same time generic timing routine would be modified to provide timings in ps. struct gpmc_timings field types are upgraded from u16 => u32 so that it can hold ps values. Whole of this exercise is being done to achieve driver and DT conversion. If timings could not be calculated in a peripheral agnostic way, either gpmc driver would have to be peripheral gnostic or a wrapper arrangement over gpmc driver would be required. Signed-off-by: Afzal Mohammed <afzal@ti.com>
2012-08-02 22:32:10 +08:00
/* TODO: remove, see function definition */
gpmc_convert_ps_to_ns(gpmc_t);
return 0;
}
/**
* gpmc_cs_program_settings - programs non-timing related settings
* @cs: GPMC chip-select to program
* @p: pointer to GPMC settings structure
*
* Programs non-timing related settings for a GPMC chip-select, such as
* bus-width, burst configuration, etc. Function should be called once
* for each chip-select that is being used and must be called before
* calling gpmc_cs_set_timings() as timing parameters in the CONFIG1
* register will be initialised to zero by this function. Returns 0 on
* success and appropriate negative error code on failure.
*/
int gpmc_cs_program_settings(int cs, struct gpmc_settings *p)
{
u32 config1;
if ((!p->device_width) || (p->device_width > GPMC_DEVWIDTH_16BIT)) {
pr_err("%s: invalid width %d!", __func__, p->device_width);
return -EINVAL;
}
/* Address-data multiplexing not supported for NAND devices */
if (p->device_nand && p->mux_add_data) {
pr_err("%s: invalid configuration!\n", __func__);
return -EINVAL;
}
if ((p->mux_add_data > GPMC_MUX_AD) ||
((p->mux_add_data == GPMC_MUX_AAD) &&
!(gpmc_capability & GPMC_HAS_MUX_AAD))) {
pr_err("%s: invalid multiplex configuration!\n", __func__);
return -EINVAL;
}
/* Page/burst mode supports lengths of 4, 8 and 16 bytes */
if (p->burst_read || p->burst_write) {
switch (p->burst_len) {
case GPMC_BURST_4:
case GPMC_BURST_8:
case GPMC_BURST_16:
break;
default:
pr_err("%s: invalid page/burst-length (%d)\n",
__func__, p->burst_len);
return -EINVAL;
}
}
if (p->wait_pin > gpmc_nr_waitpins) {
pr_err("%s: invalid wait-pin (%d)\n", __func__, p->wait_pin);
return -EINVAL;
}
config1 = GPMC_CONFIG1_DEVICESIZE((p->device_width - 1));
if (p->sync_read)
config1 |= GPMC_CONFIG1_READTYPE_SYNC;
if (p->sync_write)
config1 |= GPMC_CONFIG1_WRITETYPE_SYNC;
if (p->wait_on_read)
config1 |= GPMC_CONFIG1_WAIT_READ_MON;
if (p->wait_on_write)
config1 |= GPMC_CONFIG1_WAIT_WRITE_MON;
if (p->wait_on_read || p->wait_on_write)
config1 |= GPMC_CONFIG1_WAIT_PIN_SEL(p->wait_pin);
if (p->device_nand)
config1 |= GPMC_CONFIG1_DEVICETYPE(GPMC_DEVICETYPE_NAND);
if (p->mux_add_data)
config1 |= GPMC_CONFIG1_MUXTYPE(p->mux_add_data);
if (p->burst_read)
config1 |= GPMC_CONFIG1_READMULTIPLE_SUPP;
if (p->burst_write)
config1 |= GPMC_CONFIG1_WRITEMULTIPLE_SUPP;
if (p->burst_read || p->burst_write) {
config1 |= GPMC_CONFIG1_PAGE_LEN(p->burst_len >> 3);
config1 |= p->burst_wrap ? GPMC_CONFIG1_WRAPBURST_SUPP : 0;
}
gpmc_cs_write_reg(cs, GPMC_CS_CONFIG1, config1);
return 0;
}
#ifdef CONFIG_OF
static const struct of_device_id gpmc_dt_ids[] = {
{ .compatible = "ti,omap2420-gpmc" },
{ .compatible = "ti,omap2430-gpmc" },
{ .compatible = "ti,omap3430-gpmc" }, /* omap3430 & omap3630 */
{ .compatible = "ti,omap4430-gpmc" }, /* omap4430 & omap4460 & omap543x */
{ .compatible = "ti,am3352-gpmc" }, /* am335x devices */
{ }
};
MODULE_DEVICE_TABLE(of, gpmc_dt_ids);
/**
* gpmc_read_settings_dt - read gpmc settings from device-tree
* @np: pointer to device-tree node for a gpmc child device
* @p: pointer to gpmc settings structure
*
* Reads the GPMC settings for a GPMC child device from device-tree and
* stores them in the GPMC settings structure passed. The GPMC settings
* structure is initialised to zero by this function and so any
* previously stored settings will be cleared.
*/
void gpmc_read_settings_dt(struct device_node *np, struct gpmc_settings *p)
{
memset(p, 0, sizeof(struct gpmc_settings));
p->sync_read = of_property_read_bool(np, "gpmc,sync-read");
p->sync_write = of_property_read_bool(np, "gpmc,sync-write");
of_property_read_u32(np, "gpmc,device-width", &p->device_width);
of_property_read_u32(np, "gpmc,mux-add-data", &p->mux_add_data);
if (!of_property_read_u32(np, "gpmc,burst-length", &p->burst_len)) {
p->burst_wrap = of_property_read_bool(np, "gpmc,burst-wrap");
p->burst_read = of_property_read_bool(np, "gpmc,burst-read");
p->burst_write = of_property_read_bool(np, "gpmc,burst-write");
if (!p->burst_read && !p->burst_write)
pr_warn("%s: page/burst-length set but not used!\n",
__func__);
}
if (!of_property_read_u32(np, "gpmc,wait-pin", &p->wait_pin)) {
p->wait_on_read = of_property_read_bool(np,
"gpmc,wait-on-read");
p->wait_on_write = of_property_read_bool(np,
"gpmc,wait-on-write");
if (!p->wait_on_read && !p->wait_on_write)
pr_debug("%s: rd/wr wait monitoring not enabled!\n",
__func__);
}
}
static void __maybe_unused gpmc_read_timings_dt(struct device_node *np,
struct gpmc_timings *gpmc_t)
{
struct gpmc_bool_timings *p;
if (!np || !gpmc_t)
return;
memset(gpmc_t, 0, sizeof(*gpmc_t));
/* minimum clock period for syncronous mode */
of_property_read_u32(np, "gpmc,sync-clk-ps", &gpmc_t->sync_clk);
/* chip select timtings */
of_property_read_u32(np, "gpmc,cs-on-ns", &gpmc_t->cs_on);
of_property_read_u32(np, "gpmc,cs-rd-off-ns", &gpmc_t->cs_rd_off);
of_property_read_u32(np, "gpmc,cs-wr-off-ns", &gpmc_t->cs_wr_off);
/* ADV signal timings */
of_property_read_u32(np, "gpmc,adv-on-ns", &gpmc_t->adv_on);
of_property_read_u32(np, "gpmc,adv-rd-off-ns", &gpmc_t->adv_rd_off);
of_property_read_u32(np, "gpmc,adv-wr-off-ns", &gpmc_t->adv_wr_off);
/* WE signal timings */
of_property_read_u32(np, "gpmc,we-on-ns", &gpmc_t->we_on);
of_property_read_u32(np, "gpmc,we-off-ns", &gpmc_t->we_off);
/* OE signal timings */
of_property_read_u32(np, "gpmc,oe-on-ns", &gpmc_t->oe_on);
of_property_read_u32(np, "gpmc,oe-off-ns", &gpmc_t->oe_off);
/* access and cycle timings */
of_property_read_u32(np, "gpmc,page-burst-access-ns",
&gpmc_t->page_burst_access);
of_property_read_u32(np, "gpmc,access-ns", &gpmc_t->access);
of_property_read_u32(np, "gpmc,rd-cycle-ns", &gpmc_t->rd_cycle);
of_property_read_u32(np, "gpmc,wr-cycle-ns", &gpmc_t->wr_cycle);
of_property_read_u32(np, "gpmc,bus-turnaround-ns",
&gpmc_t->bus_turnaround);
of_property_read_u32(np, "gpmc,cycle2cycle-delay-ns",
&gpmc_t->cycle2cycle_delay);
of_property_read_u32(np, "gpmc,wait-monitoring-ns",
&gpmc_t->wait_monitoring);
of_property_read_u32(np, "gpmc,clk-activation-ns",
&gpmc_t->clk_activation);
/* only applicable to OMAP3+ */
of_property_read_u32(np, "gpmc,wr-access-ns", &gpmc_t->wr_access);
of_property_read_u32(np, "gpmc,wr-data-mux-bus-ns",
&gpmc_t->wr_data_mux_bus);
/* bool timing parameters */
p = &gpmc_t->bool_timings;
p->cycle2cyclediffcsen =
of_property_read_bool(np, "gpmc,cycle2cycle-diffcsen");
p->cycle2cyclesamecsen =
of_property_read_bool(np, "gpmc,cycle2cycle-samecsen");
p->we_extra_delay = of_property_read_bool(np, "gpmc,we-extra-delay");
p->oe_extra_delay = of_property_read_bool(np, "gpmc,oe-extra-delay");
p->adv_extra_delay = of_property_read_bool(np, "gpmc,adv-extra-delay");
p->cs_extra_delay = of_property_read_bool(np, "gpmc,cs-extra-delay");
p->time_para_granularity =
of_property_read_bool(np, "gpmc,time-para-granularity");
}
#if IS_ENABLED(CONFIG_MTD_NAND)
static const char * const nand_xfer_types[] = {
[NAND_OMAP_PREFETCH_POLLED] = "prefetch-polled",
[NAND_OMAP_POLLED] = "polled",
[NAND_OMAP_PREFETCH_DMA] = "prefetch-dma",
[NAND_OMAP_PREFETCH_IRQ] = "prefetch-irq",
};
static int gpmc_probe_nand_child(struct platform_device *pdev,
struct device_node *child)
{
u32 val;
const char *s;
struct gpmc_timings gpmc_t;
struct omap_nand_platform_data *gpmc_nand_data;
if (of_property_read_u32(child, "reg", &val) < 0) {
dev_err(&pdev->dev, "%s has no 'reg' property\n",
child->full_name);
return -ENODEV;
}
gpmc_nand_data = devm_kzalloc(&pdev->dev, sizeof(*gpmc_nand_data),
GFP_KERNEL);
if (!gpmc_nand_data)
return -ENOMEM;
gpmc_nand_data->cs = val;
gpmc_nand_data->of_node = child;
ARM: OMAP2+: cleaned-up DT support of various ECC schemes OMAP NAND driver support multiple ECC scheme, which can used in different flavours, depending on in-build Hardware engines present on SoC. This patch updates following in DT bindings related to sectionion of ecc-schemes - ti,elm-id: replaces elm_id (maintains backward compatibility) - ti,nand-ecc-opts: selection of h/w or s/w implementation of an ecc-scheme depends on ti,elm-id. (supported values ham1, bch4, and bch8) - maintain backward compatibility to deprecated DT bindings (sw, hw, hw-romcode) Below table shows different flavours of ecc-schemes supported by OMAP devices +---------------------------------------+---------------+---------------+ | ECC scheme |ECC calculation|Error detection| +---------------------------------------+---------------+---------------+ |OMAP_ECC_HAM1_CODE_HW |H/W (GPMC) |S/W | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW_DETECTION_SW |H/W (GPMC) |S/W | |(requires CONFIG_MTD_NAND_ECC_BCH) | | | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW |H/W (GPMC) |H/W (ELM) | |(requires CONFIG_MTD_NAND_OMAP_BCH && | | | | ti,elm-id in DT) | | | +---------------------------------------+---------------+---------------+ To optimize footprint of omap2-nand driver, selection of some ECC schemes also require enabling following Kconfigs, in addition to setting appropriate DT bindings - Kconfig:CONFIG_MTD_NAND_ECC_BCH error detection done in software - Kconfig:CONFIG_MTD_NAND_OMAP_BCH error detection done by h/w engine Signed-off-by: Pekon Gupta <pekon@ti.com> Reviewed-by: Felipe Balbi <balbi@ti.com> Acked-by: Tony Lindgren <tony@atomide.com> Tested-by: Ezequiel Garcia <ezequiel.garcia@free-electrons.com> Signed-off-by: Brian Norris <computersforpeace@gmail.com>
2013-10-24 20:50:17 +08:00
/* Detect availability of ELM module */
gpmc_nand_data->elm_of_node = of_parse_phandle(child, "ti,elm-id", 0);
if (gpmc_nand_data->elm_of_node == NULL)
gpmc_nand_data->elm_of_node =
of_parse_phandle(child, "elm_id", 0);
/* select ecc-scheme for NAND */
if (of_property_read_string(child, "ti,nand-ecc-opt", &s)) {
pr_err("%s: ti,nand-ecc-opt not found\n", __func__);
return -ENODEV;
}
if (!strcmp(s, "sw"))
gpmc_nand_data->ecc_opt = OMAP_ECC_HAM1_CODE_SW;
else if (!strcmp(s, "ham1") ||
!strcmp(s, "hw") || !strcmp(s, "hw-romcode"))
ARM: OMAP2+: cleaned-up DT support of various ECC schemes OMAP NAND driver support multiple ECC scheme, which can used in different flavours, depending on in-build Hardware engines present on SoC. This patch updates following in DT bindings related to sectionion of ecc-schemes - ti,elm-id: replaces elm_id (maintains backward compatibility) - ti,nand-ecc-opts: selection of h/w or s/w implementation of an ecc-scheme depends on ti,elm-id. (supported values ham1, bch4, and bch8) - maintain backward compatibility to deprecated DT bindings (sw, hw, hw-romcode) Below table shows different flavours of ecc-schemes supported by OMAP devices +---------------------------------------+---------------+---------------+ | ECC scheme |ECC calculation|Error detection| +---------------------------------------+---------------+---------------+ |OMAP_ECC_HAM1_CODE_HW |H/W (GPMC) |S/W | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW_DETECTION_SW |H/W (GPMC) |S/W | |(requires CONFIG_MTD_NAND_ECC_BCH) | | | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW |H/W (GPMC) |H/W (ELM) | |(requires CONFIG_MTD_NAND_OMAP_BCH && | | | | ti,elm-id in DT) | | | +---------------------------------------+---------------+---------------+ To optimize footprint of omap2-nand driver, selection of some ECC schemes also require enabling following Kconfigs, in addition to setting appropriate DT bindings - Kconfig:CONFIG_MTD_NAND_ECC_BCH error detection done in software - Kconfig:CONFIG_MTD_NAND_OMAP_BCH error detection done by h/w engine Signed-off-by: Pekon Gupta <pekon@ti.com> Reviewed-by: Felipe Balbi <balbi@ti.com> Acked-by: Tony Lindgren <tony@atomide.com> Tested-by: Ezequiel Garcia <ezequiel.garcia@free-electrons.com> Signed-off-by: Brian Norris <computersforpeace@gmail.com>
2013-10-24 20:50:17 +08:00
gpmc_nand_data->ecc_opt =
OMAP_ECC_HAM1_CODE_HW;
else if (!strcmp(s, "bch4"))
if (gpmc_nand_data->elm_of_node)
gpmc_nand_data->ecc_opt =
OMAP_ECC_BCH4_CODE_HW;
else
gpmc_nand_data->ecc_opt =
OMAP_ECC_BCH4_CODE_HW_DETECTION_SW;
else if (!strcmp(s, "bch8"))
if (gpmc_nand_data->elm_of_node)
gpmc_nand_data->ecc_opt =
OMAP_ECC_BCH8_CODE_HW;
else
gpmc_nand_data->ecc_opt =
OMAP_ECC_BCH8_CODE_HW_DETECTION_SW;
else if (!strcmp(s, "bch16"))
if (gpmc_nand_data->elm_of_node)
gpmc_nand_data->ecc_opt =
OMAP_ECC_BCH16_CODE_HW;
else
pr_err("%s: BCH16 requires ELM support\n", __func__);
ARM: OMAP2+: cleaned-up DT support of various ECC schemes OMAP NAND driver support multiple ECC scheme, which can used in different flavours, depending on in-build Hardware engines present on SoC. This patch updates following in DT bindings related to sectionion of ecc-schemes - ti,elm-id: replaces elm_id (maintains backward compatibility) - ti,nand-ecc-opts: selection of h/w or s/w implementation of an ecc-scheme depends on ti,elm-id. (supported values ham1, bch4, and bch8) - maintain backward compatibility to deprecated DT bindings (sw, hw, hw-romcode) Below table shows different flavours of ecc-schemes supported by OMAP devices +---------------------------------------+---------------+---------------+ | ECC scheme |ECC calculation|Error detection| +---------------------------------------+---------------+---------------+ |OMAP_ECC_HAM1_CODE_HW |H/W (GPMC) |S/W | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW_DETECTION_SW |H/W (GPMC) |S/W | |(requires CONFIG_MTD_NAND_ECC_BCH) | | | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW |H/W (GPMC) |H/W (ELM) | |(requires CONFIG_MTD_NAND_OMAP_BCH && | | | | ti,elm-id in DT) | | | +---------------------------------------+---------------+---------------+ To optimize footprint of omap2-nand driver, selection of some ECC schemes also require enabling following Kconfigs, in addition to setting appropriate DT bindings - Kconfig:CONFIG_MTD_NAND_ECC_BCH error detection done in software - Kconfig:CONFIG_MTD_NAND_OMAP_BCH error detection done by h/w engine Signed-off-by: Pekon Gupta <pekon@ti.com> Reviewed-by: Felipe Balbi <balbi@ti.com> Acked-by: Tony Lindgren <tony@atomide.com> Tested-by: Ezequiel Garcia <ezequiel.garcia@free-electrons.com> Signed-off-by: Brian Norris <computersforpeace@gmail.com>
2013-10-24 20:50:17 +08:00
else
pr_err("%s: ti,nand-ecc-opt invalid value\n", __func__);
ARM: OMAP2+: cleaned-up DT support of various ECC schemes OMAP NAND driver support multiple ECC scheme, which can used in different flavours, depending on in-build Hardware engines present on SoC. This patch updates following in DT bindings related to sectionion of ecc-schemes - ti,elm-id: replaces elm_id (maintains backward compatibility) - ti,nand-ecc-opts: selection of h/w or s/w implementation of an ecc-scheme depends on ti,elm-id. (supported values ham1, bch4, and bch8) - maintain backward compatibility to deprecated DT bindings (sw, hw, hw-romcode) Below table shows different flavours of ecc-schemes supported by OMAP devices +---------------------------------------+---------------+---------------+ | ECC scheme |ECC calculation|Error detection| +---------------------------------------+---------------+---------------+ |OMAP_ECC_HAM1_CODE_HW |H/W (GPMC) |S/W | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW_DETECTION_SW |H/W (GPMC) |S/W | |(requires CONFIG_MTD_NAND_ECC_BCH) | | | +---------------------------------------+---------------+---------------+ |OMAP_ECC_BCH8_CODE_HW |H/W (GPMC) |H/W (ELM) | |(requires CONFIG_MTD_NAND_OMAP_BCH && | | | | ti,elm-id in DT) | | | +---------------------------------------+---------------+---------------+ To optimize footprint of omap2-nand driver, selection of some ECC schemes also require enabling following Kconfigs, in addition to setting appropriate DT bindings - Kconfig:CONFIG_MTD_NAND_ECC_BCH error detection done in software - Kconfig:CONFIG_MTD_NAND_OMAP_BCH error detection done by h/w engine Signed-off-by: Pekon Gupta <pekon@ti.com> Reviewed-by: Felipe Balbi <balbi@ti.com> Acked-by: Tony Lindgren <tony@atomide.com> Tested-by: Ezequiel Garcia <ezequiel.garcia@free-electrons.com> Signed-off-by: Brian Norris <computersforpeace@gmail.com>
2013-10-24 20:50:17 +08:00
/* select data transfer mode for NAND controller */
if (!of_property_read_string(child, "ti,nand-xfer-type", &s))
for (val = 0; val < ARRAY_SIZE(nand_xfer_types); val++)
if (!strcasecmp(s, nand_xfer_types[val])) {
gpmc_nand_data->xfer_type = val;
break;
}
gpmc_nand_data->flash_bbt = of_get_nand_on_flash_bbt(child);
val = of_get_nand_bus_width(child);
if (val == 16)
gpmc_nand_data->devsize = NAND_BUSWIDTH_16;
gpmc_read_timings_dt(child, &gpmc_t);
gpmc_nand_init(gpmc_nand_data, &gpmc_t);
return 0;
}
#else
static int gpmc_probe_nand_child(struct platform_device *pdev,
struct device_node *child)
{
return 0;
}
#endif
#if IS_ENABLED(CONFIG_MTD_ONENAND)
static int gpmc_probe_onenand_child(struct platform_device *pdev,
struct device_node *child)
{
u32 val;
struct omap_onenand_platform_data *gpmc_onenand_data;
if (of_property_read_u32(child, "reg", &val) < 0) {
dev_err(&pdev->dev, "%s has no 'reg' property\n",
child->full_name);
return -ENODEV;
}
gpmc_onenand_data = devm_kzalloc(&pdev->dev, sizeof(*gpmc_onenand_data),
GFP_KERNEL);
if (!gpmc_onenand_data)
return -ENOMEM;
gpmc_onenand_data->cs = val;
gpmc_onenand_data->of_node = child;
gpmc_onenand_data->dma_channel = -1;
if (!of_property_read_u32(child, "dma-channel", &val))
gpmc_onenand_data->dma_channel = val;
gpmc_onenand_init(gpmc_onenand_data);
return 0;
}
#else
static int gpmc_probe_onenand_child(struct platform_device *pdev,
struct device_node *child)
{
return 0;
}
#endif
/**
* gpmc_probe_generic_child - configures the gpmc for a child device
* @pdev: pointer to gpmc platform device
* @child: pointer to device-tree node for child device
*
* Allocates and configures a GPMC chip-select for a child device.
* Returns 0 on success and appropriate negative error code on failure.
*/
static int gpmc_probe_generic_child(struct platform_device *pdev,
struct device_node *child)
{
struct gpmc_settings gpmc_s;
struct gpmc_timings gpmc_t;
struct resource res;
unsigned long base;
const char *name;
int ret, cs;
u32 val;
if (of_property_read_u32(child, "reg", &cs) < 0) {
dev_err(&pdev->dev, "%s has no 'reg' property\n",
child->full_name);
return -ENODEV;
}
if (of_address_to_resource(child, 0, &res) < 0) {
dev_err(&pdev->dev, "%s has malformed 'reg' property\n",
child->full_name);
return -ENODEV;
}
/*
* Check if we have multiple instances of the same device
* on a single chip select. If so, use the already initialized
* timings.
*/
name = gpmc_cs_get_name(cs);
if (name && child->name && of_node_cmp(child->name, name) == 0)
goto no_timings;
ret = gpmc_cs_request(cs, resource_size(&res), &base);
if (ret < 0) {
dev_err(&pdev->dev, "cannot request GPMC CS %d\n", cs);
return ret;
}
gpmc_cs_set_name(cs, child->name);
gpmc_read_settings_dt(child, &gpmc_s);
gpmc_read_timings_dt(child, &gpmc_t);
/*
* For some GPMC devices we still need to rely on the bootloader
* timings because the devices can be connected via FPGA.
* REVISIT: Add timing support from slls644g.pdf.
*/
if (!gpmc_t.cs_rd_off) {
WARN(1, "enable GPMC debug to configure .dts timings for CS%i\n",
cs);
gpmc_cs_show_timings(cs,
"please add GPMC bootloader timings to .dts");
goto no_timings;
}
/* CS must be disabled while making changes to gpmc configuration */
gpmc_cs_disable_mem(cs);
/*
* FIXME: gpmc_cs_request() will map the CS to an arbitary
* location in the gpmc address space. When booting with
* device-tree we want the NOR flash to be mapped to the
* location specified in the device-tree blob. So remap the
* CS to this location. Once DT migration is complete should
* just make gpmc_cs_request() map a specific address.
*/
ret = gpmc_cs_remap(cs, res.start);
if (ret < 0) {
dev_err(&pdev->dev, "cannot remap GPMC CS %d to %pa\n",
cs, &res.start);
goto err;
}
ret = of_property_read_u32(child, "bank-width", &gpmc_s.device_width);
if (ret < 0)
goto err;
ret = gpmc_cs_program_settings(cs, &gpmc_s);
if (ret < 0)
goto err;
ret = gpmc_cs_set_timings(cs, &gpmc_t, &gpmc_s);
if (ret) {
dev_err(&pdev->dev, "failed to set gpmc timings for: %s\n",
child->name);
goto err;
}
/* Clear limited address i.e. enable A26-A11 */
val = gpmc_read_reg(GPMC_CONFIG);
val &= ~GPMC_CONFIG_LIMITEDADDRESS;
gpmc_write_reg(GPMC_CONFIG, val);
/* Enable CS region */
gpmc_cs_enable_mem(cs);
no_timings:
/* create platform device, NULL on error or when disabled */
if (!of_platform_device_create(child, NULL, &pdev->dev))
goto err_child_fail;
/* is child a common bus? */
if (of_match_node(of_default_bus_match_table, child))
/* create children and other common bus children */
if (of_platform_populate(child, of_default_bus_match_table,
NULL, &pdev->dev))
goto err_child_fail;
return 0;
err_child_fail:
dev_err(&pdev->dev, "failed to create gpmc child %s\n", child->name);
ret = -ENODEV;
err:
gpmc_cs_free(cs);
return ret;
}
static int gpmc_probe_dt(struct platform_device *pdev)
{
int ret;
struct device_node *child;
const struct of_device_id *of_id =
of_match_device(gpmc_dt_ids, &pdev->dev);
if (!of_id)
return 0;
ret = of_property_read_u32(pdev->dev.of_node, "gpmc,num-cs",
&gpmc_cs_num);
if (ret < 0) {
pr_err("%s: number of chip-selects not defined\n", __func__);
return ret;
} else if (gpmc_cs_num < 1) {
pr_err("%s: all chip-selects are disabled\n", __func__);
return -EINVAL;
} else if (gpmc_cs_num > GPMC_CS_NUM) {
pr_err("%s: number of supported chip-selects cannot be > %d\n",
__func__, GPMC_CS_NUM);
return -EINVAL;
}
ret = of_property_read_u32(pdev->dev.of_node, "gpmc,num-waitpins",
&gpmc_nr_waitpins);
if (ret < 0) {
pr_err("%s: number of wait pins not found!\n", __func__);
return ret;
}
for_each_available_child_of_node(pdev->dev.of_node, child) {
if (!child->name)
continue;
if (of_node_cmp(child->name, "nand") == 0)
ret = gpmc_probe_nand_child(pdev, child);
else if (of_node_cmp(child->name, "onenand") == 0)
ret = gpmc_probe_onenand_child(pdev, child);
else if (of_node_cmp(child->name, "ethernet") == 0 ||
of_node_cmp(child->name, "nor") == 0 ||
of_node_cmp(child->name, "uart") == 0)
ret = gpmc_probe_generic_child(pdev, child);
if (WARN(ret < 0, "%s: probing gpmc child %s failed\n",
__func__, child->full_name))
of_node_put(child);
}
return 0;
}
#else
static int gpmc_probe_dt(struct platform_device *pdev)
{
return 0;
}
#endif
static int gpmc_probe(struct platform_device *pdev)
{
int rc;
u32 l;
struct resource *res;
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (res == NULL)
return -ENOENT;
phys_base = res->start;
mem_size = resource_size(res);
gpmc_base = devm_ioremap_resource(&pdev->dev, res);
if (IS_ERR(gpmc_base))
return PTR_ERR(gpmc_base);
res = platform_get_resource(pdev, IORESOURCE_IRQ, 0);
if (res == NULL)
dev_warn(&pdev->dev, "Failed to get resource: irq\n");
else
gpmc_irq = res->start;
gpmc_l3_clk = devm_clk_get(&pdev->dev, "fck");
if (IS_ERR(gpmc_l3_clk)) {
dev_err(&pdev->dev, "Failed to get GPMC fck\n");
gpmc_irq = 0;
return PTR_ERR(gpmc_l3_clk);
}
if (!clk_get_rate(gpmc_l3_clk)) {
dev_err(&pdev->dev, "Invalid GPMC fck clock rate\n");
return -EINVAL;
}
pm_runtime_enable(&pdev->dev);
pm_runtime_get_sync(&pdev->dev);
gpmc_dev = &pdev->dev;
l = gpmc_read_reg(GPMC_REVISION);
/*
* FIXME: Once device-tree migration is complete the below flags
* should be populated based upon the device-tree compatible
* string. For now just use the IP revision. OMAP3+ devices have
* the wr_access and wr_data_mux_bus register fields. OMAP4+
* devices support the addr-addr-data multiplex protocol.
*
* GPMC IP revisions:
* - OMAP24xx = 2.0
* - OMAP3xxx = 5.0
* - OMAP44xx/54xx/AM335x = 6.0
*/
if (GPMC_REVISION_MAJOR(l) > 0x4)
gpmc_capability = GPMC_HAS_WR_ACCESS | GPMC_HAS_WR_DATA_MUX_BUS;
if (GPMC_REVISION_MAJOR(l) > 0x5)
gpmc_capability |= GPMC_HAS_MUX_AAD;
dev_info(gpmc_dev, "GPMC revision %d.%d\n", GPMC_REVISION_MAJOR(l),
GPMC_REVISION_MINOR(l));
gpmc_mem_init();
if (gpmc_setup_irq() < 0)
dev_warn(gpmc_dev, "gpmc_setup_irq failed\n");
if (!pdev->dev.of_node) {
gpmc_cs_num = GPMC_CS_NUM;
gpmc_nr_waitpins = GPMC_NR_WAITPINS;
}
rc = gpmc_probe_dt(pdev);
if (rc < 0) {
pm_runtime_put_sync(&pdev->dev);
dev_err(gpmc_dev, "failed to probe DT parameters\n");
return rc;
}
return 0;
}
static int gpmc_remove(struct platform_device *pdev)
{
gpmc_free_irq();
gpmc_mem_exit();
pm_runtime_put_sync(&pdev->dev);
pm_runtime_disable(&pdev->dev);
gpmc_dev = NULL;
return 0;
}
#ifdef CONFIG_PM_SLEEP
static int gpmc_suspend(struct device *dev)
{
omap3_gpmc_save_context();
pm_runtime_put_sync(dev);
return 0;
}
static int gpmc_resume(struct device *dev)
{
pm_runtime_get_sync(dev);
omap3_gpmc_restore_context();
return 0;
}
#endif
static SIMPLE_DEV_PM_OPS(gpmc_pm_ops, gpmc_suspend, gpmc_resume);
static struct platform_driver gpmc_driver = {
.probe = gpmc_probe,
.remove = gpmc_remove,
.driver = {
.name = DEVICE_NAME,
.of_match_table = of_match_ptr(gpmc_dt_ids),
.pm = &gpmc_pm_ops,
},
};
static __init int gpmc_init(void)
{
return platform_driver_register(&gpmc_driver);
}
static __exit void gpmc_exit(void)
{
platform_driver_unregister(&gpmc_driver);
}
postcore_initcall(gpmc_init);
module_exit(gpmc_exit);
static irqreturn_t gpmc_handle_irq(int irq, void *dev)
{
int i;
u32 regval;
regval = gpmc_read_reg(GPMC_IRQSTATUS);
if (!regval)
return IRQ_NONE;
for (i = 0; i < GPMC_NR_IRQ; i++)
if (regval & gpmc_client_irq[i].bitmask)
generic_handle_irq(gpmc_client_irq[i].irq);
gpmc_write_reg(GPMC_IRQSTATUS, regval);
return IRQ_HANDLED;
}
static struct omap3_gpmc_regs gpmc_context;
void omap3_gpmc_save_context(void)
{
int i;
gpmc_context.sysconfig = gpmc_read_reg(GPMC_SYSCONFIG);
gpmc_context.irqenable = gpmc_read_reg(GPMC_IRQENABLE);
gpmc_context.timeout_ctrl = gpmc_read_reg(GPMC_TIMEOUT_CONTROL);
gpmc_context.config = gpmc_read_reg(GPMC_CONFIG);
gpmc_context.prefetch_config1 = gpmc_read_reg(GPMC_PREFETCH_CONFIG1);
gpmc_context.prefetch_config2 = gpmc_read_reg(GPMC_PREFETCH_CONFIG2);
gpmc_context.prefetch_control = gpmc_read_reg(GPMC_PREFETCH_CONTROL);
for (i = 0; i < gpmc_cs_num; i++) {
gpmc_context.cs_context[i].is_valid = gpmc_cs_mem_enabled(i);
if (gpmc_context.cs_context[i].is_valid) {
gpmc_context.cs_context[i].config1 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG1);
gpmc_context.cs_context[i].config2 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG2);
gpmc_context.cs_context[i].config3 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG3);
gpmc_context.cs_context[i].config4 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG4);
gpmc_context.cs_context[i].config5 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG5);
gpmc_context.cs_context[i].config6 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG6);
gpmc_context.cs_context[i].config7 =
gpmc_cs_read_reg(i, GPMC_CS_CONFIG7);
}
}
}
void omap3_gpmc_restore_context(void)
{
int i;
gpmc_write_reg(GPMC_SYSCONFIG, gpmc_context.sysconfig);
gpmc_write_reg(GPMC_IRQENABLE, gpmc_context.irqenable);
gpmc_write_reg(GPMC_TIMEOUT_CONTROL, gpmc_context.timeout_ctrl);
gpmc_write_reg(GPMC_CONFIG, gpmc_context.config);
gpmc_write_reg(GPMC_PREFETCH_CONFIG1, gpmc_context.prefetch_config1);
gpmc_write_reg(GPMC_PREFETCH_CONFIG2, gpmc_context.prefetch_config2);
gpmc_write_reg(GPMC_PREFETCH_CONTROL, gpmc_context.prefetch_control);
for (i = 0; i < gpmc_cs_num; i++) {
if (gpmc_context.cs_context[i].is_valid) {
gpmc_cs_write_reg(i, GPMC_CS_CONFIG1,
gpmc_context.cs_context[i].config1);
gpmc_cs_write_reg(i, GPMC_CS_CONFIG2,
gpmc_context.cs_context[i].config2);
gpmc_cs_write_reg(i, GPMC_CS_CONFIG3,
gpmc_context.cs_context[i].config3);
gpmc_cs_write_reg(i, GPMC_CS_CONFIG4,
gpmc_context.cs_context[i].config4);
gpmc_cs_write_reg(i, GPMC_CS_CONFIG5,
gpmc_context.cs_context[i].config5);
gpmc_cs_write_reg(i, GPMC_CS_CONFIG6,
gpmc_context.cs_context[i].config6);
gpmc_cs_write_reg(i, GPMC_CS_CONFIG7,
gpmc_context.cs_context[i].config7);
}
}
}