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linux/drivers/net/bnx2x_init.h
Eilon Greenstein ad8d394804 bnx2x: New init infrastructure 
This new initialization code supports the 57711 HW. It also supports
the emulation and FPGA for the 57711 and 57710 initializations values
(very small amount of code which is very helpful in the lab - less
than 30 lines).

The initialization is done via DMAE after the DMAE block is ready -
before it is ready, some of the initialization is done via PCI
configuration transactions (referred to as indirect write).  A mutex
to protect the DMAE from being overlapped was added.  There are few
new registers which needs to be initialized by SW - the full comment
for those registers is added to the register file.  A place holder for
the 57711 (referred to as E1H) microcode was added- the microcode
itself is too big and it is split over the following 4 patches

Signed-off-by: Eilon Greenstein <eilong@broadcom.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2008-06-23 20:29:02 -07:00

812 lines
26 KiB
C
Raw Blame History

/* bnx2x_init.h: Broadcom Everest network driver.
*
* Copyright (c) 2007-2008 Broadcom Corporation
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation.
*
* Maintained by: Eilon Greenstein <eilong@broadcom.com>
* Written by: Eliezer Tamir
*/
#ifndef BNX2X_INIT_H
#define BNX2X_INIT_H
#define COMMON 0x1
#define PORT0 0x2
#define PORT1 0x4
#define INIT_EMULATION 0x1
#define INIT_FPGA 0x2
#define INIT_ASIC 0x4
#define INIT_HARDWARE 0x7
#define STORM_INTMEM_SIZE_E1 (0x5800 / 4)
#define STORM_INTMEM_SIZE_E1H (0x10000 / 4)
#define TSTORM_INTMEM_ADDR 0x1a0000
#define CSTORM_INTMEM_ADDR 0x220000
#define XSTORM_INTMEM_ADDR 0x2a0000
#define USTORM_INTMEM_ADDR 0x320000
/* Init operation types and structures */
/* Common for both E1 and E1H */
#define OP_RD 0x1 /* read single register */
#define OP_WR 0x2 /* write single register */
#define OP_IW 0x3 /* write single register using mailbox */
#define OP_SW 0x4 /* copy a string to the device */
#define OP_SI 0x5 /* copy a string using mailbox */
#define OP_ZR 0x6 /* clear memory */
#define OP_ZP 0x7 /* unzip then copy with DMAE */
#define OP_WR_64 0x8 /* write 64 bit pattern */
#define OP_WB 0x9 /* copy a string using DMAE */
/* Operation specific for E1 */
#define OP_RD_E1 0xa /* read single register */
#define OP_WR_E1 0xb /* write single register */
#define OP_IW_E1 0xc /* write single register using mailbox */
#define OP_SW_E1 0xd /* copy a string to the device */
#define OP_SI_E1 0xe /* copy a string using mailbox */
#define OP_ZR_E1 0xf /* clear memory */
#define OP_ZP_E1 0x10 /* unzip then copy with DMAE */
#define OP_WR_64_E1 0x11 /* write 64 bit pattern on E1 */
#define OP_WB_E1 0x12 /* copy a string using DMAE */
/* Operation specific for E1H */
#define OP_RD_E1H 0x13 /* read single register */
#define OP_WR_E1H 0x14 /* write single register */
#define OP_IW_E1H 0x15 /* write single register using mailbox */
#define OP_SW_E1H 0x16 /* copy a string to the device */
#define OP_SI_E1H 0x17 /* copy a string using mailbox */
#define OP_ZR_E1H 0x18 /* clear memory */
#define OP_ZP_E1H 0x19 /* unzip then copy with DMAE */
#define OP_WR_64_E1H 0x1a /* write 64 bit pattern on E1H */
#define OP_WB_E1H 0x1b /* copy a string using DMAE */
/* FPGA and EMUL specific operations */
#define OP_WR_EMUL_E1H 0x1c /* write single register on E1H Emul */
#define OP_WR_EMUL 0x1d /* write single register on Emulation */
#define OP_WR_FPGA 0x1e /* write single register on FPGA */
#define OP_WR_ASIC 0x1f /* write single register on ASIC */
struct raw_op {
u32 op :8;
u32 offset :24;
u32 raw_data;
};
struct op_read {
u32 op :8;
u32 offset :24;
u32 pad;
};
struct op_write {
u32 op :8;
u32 offset :24;
u32 val;
};
struct op_string_write {
u32 op :8;
u32 offset :24;
#ifdef __LITTLE_ENDIAN
u16 data_off;
u16 data_len;
#else /* __BIG_ENDIAN */
u16 data_len;
u16 data_off;
#endif
};
struct op_zero {
u32 op :8;
u32 offset :24;
u32 len;
};
union init_op {
struct op_read read;
struct op_write write;
struct op_string_write str_wr;
struct op_zero zero;
struct raw_op raw;
};
#include "bnx2x_init_values.h"
static void bnx2x_reg_wr_ind(struct bnx2x *bp, u32 addr, u32 val);
static int bnx2x_gunzip(struct bnx2x *bp, u8 *zbuf, int len);
static void bnx2x_init_str_wr(struct bnx2x *bp, u32 addr, const u32 *data,
u32 len)
{
int i;
for (i = 0; i < len; i++) {
REG_WR(bp, addr + i*4, data[i]);
if (!(i % 10000)) {
touch_softlockup_watchdog();
cpu_relax();
}
}
}
static void bnx2x_init_ind_wr(struct bnx2x *bp, u32 addr, const u32 *data,
u16 len)
{
int i;
for (i = 0; i < len; i++) {
REG_WR_IND(bp, addr + i*4, data[i]);
if (!(i % 10000)) {
touch_softlockup_watchdog();
cpu_relax();
}
}
}
static void bnx2x_write_big_buf(struct bnx2x *bp, u32 addr, u32 len)
{
#ifdef USE_DMAE
int offset = 0;
if (bp->dmae_ready) {
while (len > DMAE_LEN32_WR_MAX) {
bnx2x_write_dmae(bp, bp->gunzip_mapping + offset,
addr + offset, DMAE_LEN32_WR_MAX);
offset += DMAE_LEN32_WR_MAX * 4;
len -= DMAE_LEN32_WR_MAX;
}
bnx2x_write_dmae(bp, bp->gunzip_mapping + offset,
addr + offset, len);
} else
bnx2x_init_str_wr(bp, addr, bp->gunzip_buf, len);
#else
bnx2x_init_str_wr(bp, addr, bp->gunzip_buf, len);
#endif
}
static void bnx2x_init_fill(struct bnx2x *bp, u32 addr, int fill, u32 len)
{
if ((len * 4) > FW_BUF_SIZE) {
BNX2X_ERR("LARGE DMAE OPERATION ! addr 0x%x len 0x%x\n",
addr, len*4);
return;
}
memset(bp->gunzip_buf, fill, len * 4);
bnx2x_write_big_buf(bp, addr, len);
}
static void bnx2x_init_wr_64(struct bnx2x *bp, u32 addr, const u32 *data,
u32 len64)
{
u32 buf_len32 = FW_BUF_SIZE/4;
u32 len = len64*2;
u64 data64 = 0;
int i;
/* 64 bit value is in a blob: first low DWORD, then high DWORD */
data64 = HILO_U64((*(data + 1)), (*data));
len64 = min((u32)(FW_BUF_SIZE/8), len64);
for (i = 0; i < len64; i++) {
u64 *pdata = ((u64 *)(bp->gunzip_buf)) + i;
*pdata = data64;
}
for (i = 0; i < len; i += buf_len32) {
u32 cur_len = min(buf_len32, len - i);
bnx2x_write_big_buf(bp, addr + i * 4, cur_len);
}
}
/*********************************************************
There are different blobs for each PRAM section.
In addition, each blob write operation is divided into a few operations
in order to decrease the amount of phys. contigious buffer needed.
Thus, when we select a blob the address may be with some offset
from the beginning of PRAM section.
The same holds for the INT_TABLE sections.
**********************************************************/
#define IF_IS_INT_TABLE_ADDR(base, addr) \
if (((base) <= (addr)) && ((base) + 0x400 >= (addr)))
#define IF_IS_PRAM_ADDR(base, addr) \
if (((base) <= (addr)) && ((base) + 0x40000 >= (addr)))
static const u32 *bnx2x_sel_blob(u32 addr, const u32 *data, int is_e1)
{
IF_IS_INT_TABLE_ADDR(TSEM_REG_INT_TABLE, addr)
data = is_e1 ? tsem_int_table_data_e1 :
tsem_int_table_data_e1h;
else
IF_IS_INT_TABLE_ADDR(CSEM_REG_INT_TABLE, addr)
data = is_e1 ? csem_int_table_data_e1 :
csem_int_table_data_e1h;
else
IF_IS_INT_TABLE_ADDR(USEM_REG_INT_TABLE, addr)
data = is_e1 ? usem_int_table_data_e1 :
usem_int_table_data_e1h;
else
IF_IS_INT_TABLE_ADDR(XSEM_REG_INT_TABLE, addr)
data = is_e1 ? xsem_int_table_data_e1 :
xsem_int_table_data_e1h;
else
IF_IS_PRAM_ADDR(TSEM_REG_PRAM, addr)
data = is_e1 ? tsem_pram_data_e1 : tsem_pram_data_e1h;
else
IF_IS_PRAM_ADDR(CSEM_REG_PRAM, addr)
data = is_e1 ? csem_pram_data_e1 : csem_pram_data_e1h;
else
IF_IS_PRAM_ADDR(USEM_REG_PRAM, addr)
data = is_e1 ? usem_pram_data_e1 : usem_pram_data_e1h;
else
IF_IS_PRAM_ADDR(XSEM_REG_PRAM, addr)
data = is_e1 ? xsem_pram_data_e1 : xsem_pram_data_e1h;
return data;
}
static void bnx2x_init_wr_wb(struct bnx2x *bp, u32 addr, const u32 *data,
u32 len, int gunzip, int is_e1, u32 blob_off)
{
int offset = 0;
data = bnx2x_sel_blob(addr, data, is_e1) + blob_off;
if (gunzip) {
int rc;
#ifdef __BIG_ENDIAN
int i, size;
u32 *temp;
temp = kmalloc(len, GFP_KERNEL);
size = (len / 4) + ((len % 4) ? 1 : 0);
for (i = 0; i < size; i++)
temp[i] = swab32(data[i]);
data = temp;
#endif
rc = bnx2x_gunzip(bp, (u8 *)data, len);
if (rc) {
BNX2X_ERR("gunzip failed ! rc %d\n", rc);
return;
}
len = bp->gunzip_outlen;
#ifdef __BIG_ENDIAN
kfree(temp);
for (i = 0; i < len; i++)
((u32 *)bp->gunzip_buf)[i] =
swab32(((u32 *)bp->gunzip_buf)[i]);
#endif
} else {
if ((len * 4) > FW_BUF_SIZE) {
BNX2X_ERR("LARGE DMAE OPERATION ! "
"addr 0x%x len 0x%x\n", addr, len*4);
return;
}
memcpy(bp->gunzip_buf, data, len * 4);
}
if (bp->dmae_ready) {
while (len > DMAE_LEN32_WR_MAX) {
bnx2x_write_dmae(bp, bp->gunzip_mapping + offset,
addr + offset, DMAE_LEN32_WR_MAX);
offset += DMAE_LEN32_WR_MAX * 4;
len -= DMAE_LEN32_WR_MAX;
}
bnx2x_write_dmae(bp, bp->gunzip_mapping + offset,
addr + offset, len);
} else
bnx2x_init_ind_wr(bp, addr, bp->gunzip_buf, len);
}
static void bnx2x_init_block(struct bnx2x *bp, u32 op_start, u32 op_end)
{
int is_e1 = CHIP_IS_E1(bp);
int is_e1h = CHIP_IS_E1H(bp);
int is_emul_e1h = (CHIP_REV_IS_EMUL(bp) && is_e1h);
int hw_wr, i;
union init_op *op;
u32 op_type, addr, len;
const u32 *data, *data_base;
if (CHIP_REV_IS_FPGA(bp))
hw_wr = OP_WR_FPGA;
else if (CHIP_REV_IS_EMUL(bp))
hw_wr = OP_WR_EMUL;
else
hw_wr = OP_WR_ASIC;
if (is_e1)
data_base = init_data_e1;
else /* CHIP_IS_E1H(bp) */
data_base = init_data_e1h;
for (i = op_start; i < op_end; i++) {
op = (union init_op *)&(init_ops[i]);
op_type = op->str_wr.op;
addr = op->str_wr.offset;
len = op->str_wr.data_len;
data = data_base + op->str_wr.data_off;
/* carefull! it must be in order */
if (unlikely(op_type > OP_WB)) {
/* If E1 only */
if (op_type <= OP_WB_E1) {
if (is_e1)
op_type -= (OP_RD_E1 - OP_RD);
/* If E1H only */
} else if (op_type <= OP_WB_E1H) {
if (is_e1h)
op_type -= (OP_RD_E1H - OP_RD);
}
/* HW/EMUL specific */
if (op_type == hw_wr)
op_type = OP_WR;
/* EMUL on E1H is special */
if ((op_type == OP_WR_EMUL_E1H) && is_emul_e1h)
op_type = OP_WR;
}
switch (op_type) {
case OP_RD:
REG_RD(bp, addr);
break;
case OP_WR:
REG_WR(bp, addr, op->write.val);
break;
case OP_SW:
bnx2x_init_str_wr(bp, addr, data, len);
break;
case OP_WB:
bnx2x_init_wr_wb(bp, addr, data, len, 0, is_e1, 0);
break;
case OP_SI:
bnx2x_init_ind_wr(bp, addr, data, len);
break;
case OP_ZR:
bnx2x_init_fill(bp, addr, 0, op->zero.len);
break;
case OP_ZP:
bnx2x_init_wr_wb(bp, addr, data, len, 1, is_e1,
op->str_wr.data_off);
break;
case OP_WR_64:
bnx2x_init_wr_64(bp, addr, data, len);
break;
default:
/* happens whenever an op is of a diff HW */
#if 0
DP(NETIF_MSG_HW, "skipping init operation "
"index %d[%d:%d]: type %d addr 0x%x "
"len %d(0x%x)\n",
i, op_start, op_end, op_type, addr, len, len);
#endif
break;
}
}
}
/****************************************************************************
* PXP
****************************************************************************/
/*
* This code configures the PCI read/write arbiter
* which implements a weighted round robin
* between the virtual queues in the chip.
*
* The values were derived for each PCI max payload and max request size.
* since max payload and max request size are only known at run time,
* this is done as a separate init stage.
*/
#define NUM_WR_Q 13
#define NUM_RD_Q 29
#define MAX_RD_ORD 3
#define MAX_WR_ORD 2
/* configuration for one arbiter queue */
struct arb_line {
int l;
int add;
int ubound;
};
/* derived configuration for each read queue for each max request size */
static const struct arb_line read_arb_data[NUM_RD_Q][MAX_RD_ORD + 1] = {
{{8 , 64 , 25}, {16 , 64 , 25}, {32 , 64 , 25}, {64 , 64 , 41} },
{{4 , 8 , 4}, {4 , 8 , 4}, {4 , 8 , 4}, {4 , 8 , 4} },
{{4 , 3 , 3}, {4 , 3 , 3}, {4 , 3 , 3}, {4 , 3 , 3} },
{{8 , 3 , 6}, {16 , 3 , 11}, {16 , 3 , 11}, {16 , 3 , 11} },
{{8 , 64 , 25}, {16 , 64 , 25}, {32 , 64 , 25}, {64 , 64 , 41} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {64 , 3 , 41} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {64 , 3 , 41} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {64 , 3 , 41} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {64 , 3 , 41} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 3 , 6}, {16 , 3 , 11}, {32 , 3 , 21}, {32 , 3 , 21} },
{{8 , 64 , 25}, {16 , 64 , 41}, {32 , 64 , 81}, {64 , 64 , 120} }
};
/* derived configuration for each write queue for each max request size */
static const struct arb_line write_arb_data[NUM_WR_Q][MAX_WR_ORD + 1] = {
{{4 , 6 , 3}, {4 , 6 , 3}, {4 , 6 , 3} },
{{4 , 2 , 3}, {4 , 2 , 3}, {4 , 2 , 3} },
{{8 , 2 , 6}, {16 , 2 , 11}, {16 , 2 , 11} },
{{8 , 2 , 6}, {16 , 2 , 11}, {32 , 2 , 21} },
{{8 , 2 , 6}, {16 , 2 , 11}, {32 , 2 , 21} },
{{8 , 2 , 6}, {16 , 2 , 11}, {32 , 2 , 21} },
{{8 , 64 , 25}, {16 , 64 , 25}, {32 , 64 , 25} },
{{8 , 2 , 6}, {16 , 2 , 11}, {16 , 2 , 11} },
{{8 , 2 , 6}, {16 , 2 , 11}, {16 , 2 , 11} },
{{8 , 9 , 6}, {16 , 9 , 11}, {32 , 9 , 21} },
{{8 , 47 , 19}, {16 , 47 , 19}, {32 , 47 , 21} },
{{8 , 9 , 6}, {16 , 9 , 11}, {16 , 9 , 11} },
{{8 , 64 , 25}, {16 , 64 , 41}, {32 , 64 , 81} }
};
/* register addresses for read queues */
static const struct arb_line read_arb_addr[NUM_RD_Q-1] = {
{PXP2_REG_RQ_BW_RD_L0, PXP2_REG_RQ_BW_RD_ADD0,
PXP2_REG_RQ_BW_RD_UBOUND0},
{PXP2_REG_PSWRQ_BW_L1, PXP2_REG_PSWRQ_BW_ADD1,
PXP2_REG_PSWRQ_BW_UB1},
{PXP2_REG_PSWRQ_BW_L2, PXP2_REG_PSWRQ_BW_ADD2,
PXP2_REG_PSWRQ_BW_UB2},
{PXP2_REG_PSWRQ_BW_L3, PXP2_REG_PSWRQ_BW_ADD3,
PXP2_REG_PSWRQ_BW_UB3},
{PXP2_REG_RQ_BW_RD_L4, PXP2_REG_RQ_BW_RD_ADD4,
PXP2_REG_RQ_BW_RD_UBOUND4},
{PXP2_REG_RQ_BW_RD_L5, PXP2_REG_RQ_BW_RD_ADD5,
PXP2_REG_RQ_BW_RD_UBOUND5},
{PXP2_REG_PSWRQ_BW_L6, PXP2_REG_PSWRQ_BW_ADD6,
PXP2_REG_PSWRQ_BW_UB6},
{PXP2_REG_PSWRQ_BW_L7, PXP2_REG_PSWRQ_BW_ADD7,
PXP2_REG_PSWRQ_BW_UB7},
{PXP2_REG_PSWRQ_BW_L8, PXP2_REG_PSWRQ_BW_ADD8,
PXP2_REG_PSWRQ_BW_UB8},
{PXP2_REG_PSWRQ_BW_L9, PXP2_REG_PSWRQ_BW_ADD9,
PXP2_REG_PSWRQ_BW_UB9},
{PXP2_REG_PSWRQ_BW_L10, PXP2_REG_PSWRQ_BW_ADD10,
PXP2_REG_PSWRQ_BW_UB10},
{PXP2_REG_PSWRQ_BW_L11, PXP2_REG_PSWRQ_BW_ADD11,
PXP2_REG_PSWRQ_BW_UB11},
{PXP2_REG_RQ_BW_RD_L12, PXP2_REG_RQ_BW_RD_ADD12,
PXP2_REG_RQ_BW_RD_UBOUND12},
{PXP2_REG_RQ_BW_RD_L13, PXP2_REG_RQ_BW_RD_ADD13,
PXP2_REG_RQ_BW_RD_UBOUND13},
{PXP2_REG_RQ_BW_RD_L14, PXP2_REG_RQ_BW_RD_ADD14,
PXP2_REG_RQ_BW_RD_UBOUND14},
{PXP2_REG_RQ_BW_RD_L15, PXP2_REG_RQ_BW_RD_ADD15,
PXP2_REG_RQ_BW_RD_UBOUND15},
{PXP2_REG_RQ_BW_RD_L16, PXP2_REG_RQ_BW_RD_ADD16,
PXP2_REG_RQ_BW_RD_UBOUND16},
{PXP2_REG_RQ_BW_RD_L17, PXP2_REG_RQ_BW_RD_ADD17,
PXP2_REG_RQ_BW_RD_UBOUND17},
{PXP2_REG_RQ_BW_RD_L18, PXP2_REG_RQ_BW_RD_ADD18,
PXP2_REG_RQ_BW_RD_UBOUND18},
{PXP2_REG_RQ_BW_RD_L19, PXP2_REG_RQ_BW_RD_ADD19,
PXP2_REG_RQ_BW_RD_UBOUND19},
{PXP2_REG_RQ_BW_RD_L20, PXP2_REG_RQ_BW_RD_ADD20,
PXP2_REG_RQ_BW_RD_UBOUND20},
{PXP2_REG_RQ_BW_RD_L22, PXP2_REG_RQ_BW_RD_ADD22,
PXP2_REG_RQ_BW_RD_UBOUND22},
{PXP2_REG_RQ_BW_RD_L23, PXP2_REG_RQ_BW_RD_ADD23,
PXP2_REG_RQ_BW_RD_UBOUND23},
{PXP2_REG_RQ_BW_RD_L24, PXP2_REG_RQ_BW_RD_ADD24,
PXP2_REG_RQ_BW_RD_UBOUND24},
{PXP2_REG_RQ_BW_RD_L25, PXP2_REG_RQ_BW_RD_ADD25,
PXP2_REG_RQ_BW_RD_UBOUND25},
{PXP2_REG_RQ_BW_RD_L26, PXP2_REG_RQ_BW_RD_ADD26,
PXP2_REG_RQ_BW_RD_UBOUND26},
{PXP2_REG_RQ_BW_RD_L27, PXP2_REG_RQ_BW_RD_ADD27,
PXP2_REG_RQ_BW_RD_UBOUND27},
{PXP2_REG_PSWRQ_BW_L28, PXP2_REG_PSWRQ_BW_ADD28,
PXP2_REG_PSWRQ_BW_UB28}
};
/* register addresses for write queues */
static const struct arb_line write_arb_addr[NUM_WR_Q-1] = {
{PXP2_REG_PSWRQ_BW_L1, PXP2_REG_PSWRQ_BW_ADD1,
PXP2_REG_PSWRQ_BW_UB1},
{PXP2_REG_PSWRQ_BW_L2, PXP2_REG_PSWRQ_BW_ADD2,
PXP2_REG_PSWRQ_BW_UB2},
{PXP2_REG_PSWRQ_BW_L3, PXP2_REG_PSWRQ_BW_ADD3,
PXP2_REG_PSWRQ_BW_UB3},
{PXP2_REG_PSWRQ_BW_L6, PXP2_REG_PSWRQ_BW_ADD6,
PXP2_REG_PSWRQ_BW_UB6},
{PXP2_REG_PSWRQ_BW_L7, PXP2_REG_PSWRQ_BW_ADD7,
PXP2_REG_PSWRQ_BW_UB7},
{PXP2_REG_PSWRQ_BW_L8, PXP2_REG_PSWRQ_BW_ADD8,
PXP2_REG_PSWRQ_BW_UB8},
{PXP2_REG_PSWRQ_BW_L9, PXP2_REG_PSWRQ_BW_ADD9,
PXP2_REG_PSWRQ_BW_UB9},
{PXP2_REG_PSWRQ_BW_L10, PXP2_REG_PSWRQ_BW_ADD10,
PXP2_REG_PSWRQ_BW_UB10},
{PXP2_REG_PSWRQ_BW_L11, PXP2_REG_PSWRQ_BW_ADD11,
PXP2_REG_PSWRQ_BW_UB11},
{PXP2_REG_PSWRQ_BW_L28, PXP2_REG_PSWRQ_BW_ADD28,
PXP2_REG_PSWRQ_BW_UB28},
{PXP2_REG_RQ_BW_WR_L29, PXP2_REG_RQ_BW_WR_ADD29,
PXP2_REG_RQ_BW_WR_UBOUND29},
{PXP2_REG_RQ_BW_WR_L30, PXP2_REG_RQ_BW_WR_ADD30,
PXP2_REG_RQ_BW_WR_UBOUND30}
};
static void bnx2x_init_pxp(struct bnx2x *bp)
{
int r_order, w_order;
u32 val, i;
pci_read_config_word(bp->pdev,
bp->pcie_cap + PCI_EXP_DEVCTL, (u16 *)&val);
DP(NETIF_MSG_HW, "read 0x%x from devctl\n", (u16)val);
w_order = ((val & PCI_EXP_DEVCTL_PAYLOAD) >> 5);
r_order = ((val & PCI_EXP_DEVCTL_READRQ) >> 12);
if (r_order > MAX_RD_ORD) {
DP(NETIF_MSG_HW, "read order of %d order adjusted to %d\n",
r_order, MAX_RD_ORD);
r_order = MAX_RD_ORD;
}
if (w_order > MAX_WR_ORD) {
DP(NETIF_MSG_HW, "write order of %d order adjusted to %d\n",
w_order, MAX_WR_ORD);
w_order = MAX_WR_ORD;
}
if (CHIP_REV_IS_FPGA(bp)) {
DP(NETIF_MSG_HW, "write order adjusted to 1 for FPGA\n");
w_order = 0;
}
DP(NETIF_MSG_HW, "read order %d write order %d\n", r_order, w_order);
for (i = 0; i < NUM_RD_Q-1; i++) {
REG_WR(bp, read_arb_addr[i].l, read_arb_data[i][r_order].l);
REG_WR(bp, read_arb_addr[i].add,
read_arb_data[i][r_order].add);
REG_WR(bp, read_arb_addr[i].ubound,
read_arb_data[i][r_order].ubound);
}
for (i = 0; i < NUM_WR_Q-1; i++) {
if ((write_arb_addr[i].l == PXP2_REG_RQ_BW_WR_L29) ||
(write_arb_addr[i].l == PXP2_REG_RQ_BW_WR_L30)) {
REG_WR(bp, write_arb_addr[i].l,
write_arb_data[i][w_order].l);
REG_WR(bp, write_arb_addr[i].add,
write_arb_data[i][w_order].add);
REG_WR(bp, write_arb_addr[i].ubound,
write_arb_data[i][w_order].ubound);
} else {
val = REG_RD(bp, write_arb_addr[i].l);
REG_WR(bp, write_arb_addr[i].l,
val | (write_arb_data[i][w_order].l << 10));
val = REG_RD(bp, write_arb_addr[i].add);
REG_WR(bp, write_arb_addr[i].add,
val | (write_arb_data[i][w_order].add << 10));
val = REG_RD(bp, write_arb_addr[i].ubound);
REG_WR(bp, write_arb_addr[i].ubound,
val | (write_arb_data[i][w_order].ubound << 7));
}
}
val = write_arb_data[NUM_WR_Q-1][w_order].add;
val += write_arb_data[NUM_WR_Q-1][w_order].ubound << 10;
val += write_arb_data[NUM_WR_Q-1][w_order].l << 17;
REG_WR(bp, PXP2_REG_PSWRQ_BW_RD, val);
val = read_arb_data[NUM_RD_Q-1][r_order].add;
val += read_arb_data[NUM_RD_Q-1][r_order].ubound << 10;
val += read_arb_data[NUM_RD_Q-1][r_order].l << 17;
REG_WR(bp, PXP2_REG_PSWRQ_BW_WR, val);
REG_WR(bp, PXP2_REG_RQ_WR_MBS0, w_order);
REG_WR(bp, PXP2_REG_RQ_WR_MBS1, w_order);
REG_WR(bp, PXP2_REG_RQ_RD_MBS0, r_order);
REG_WR(bp, PXP2_REG_RQ_RD_MBS1, r_order);
if (r_order == MAX_RD_ORD)
REG_WR(bp, PXP2_REG_RQ_PDR_LIMIT, 0xe00);
REG_WR(bp, PXP2_REG_WR_USDMDP_TH, (0x18 << w_order));
if (CHIP_IS_E1H(bp)) {
REG_WR(bp, PXP2_REG_WR_HC_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_USDM_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_CSDM_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_TSDM_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_XSDM_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_QM_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_TM_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_SRC_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_DBG_MPS, w_order+1);
REG_WR(bp, PXP2_REG_WR_DMAE_MPS, 2); /* DMAE is special */
REG_WR(bp, PXP2_REG_WR_CDU_MPS, w_order+1);
}
}
/****************************************************************************
* CDU
****************************************************************************/
#define CDU_REGION_NUMBER_XCM_AG 2
#define CDU_REGION_NUMBER_UCM_AG 4
/**
* String-to-compress [31:8] = CID (all 24 bits)
* String-to-compress [7:4] = Region
* String-to-compress [3:0] = Type
*/
#define CDU_VALID_DATA(_cid, _region, _type) \
(((_cid) << 8) | (((_region) & 0xf) << 4) | (((_type) & 0xf)))
#define CDU_CRC8(_cid, _region, _type) \
calc_crc8(CDU_VALID_DATA(_cid, _region, _type), 0xff)
#define CDU_RSRVD_VALUE_TYPE_A(_cid, _region, _type) \
(0x80 | (CDU_CRC8(_cid, _region, _type) & 0x7f))
#define CDU_RSRVD_VALUE_TYPE_B(_crc, _type) \
(0x80 | ((_type) & 0xf << 3) | (CDU_CRC8(_cid, _region, _type) & 0x7))
#define CDU_RSRVD_INVALIDATE_CONTEXT_VALUE(_val) ((_val) & ~0x80)
/*****************************************************************************
* Description:
* Calculates crc 8 on a word value: polynomial 0-1-2-8
* Code was translated from Verilog.
****************************************************************************/
static u8 calc_crc8(u32 data, u8 crc)
{
u8 D[32];
u8 NewCRC[8];
u8 C[8];
u8 crc_res;
u8 i;
/* split the data into 31 bits */
for (i = 0; i < 32; i++) {
D[i] = data & 1;
data = data >> 1;
}
/* split the crc into 8 bits */
for (i = 0; i < 8; i++) {
C[i] = crc & 1;
crc = crc >> 1;
}
NewCRC[0] = D[31] ^ D[30] ^ D[28] ^ D[23] ^ D[21] ^ D[19] ^ D[18] ^
D[16] ^ D[14] ^ D[12] ^ D[8] ^ D[7] ^ D[6] ^ D[0] ^ C[4] ^
C[6] ^ C[7];
NewCRC[1] = D[30] ^ D[29] ^ D[28] ^ D[24] ^ D[23] ^ D[22] ^ D[21] ^
D[20] ^ D[18] ^ D[17] ^ D[16] ^ D[15] ^ D[14] ^ D[13] ^
D[12] ^ D[9] ^ D[6] ^ D[1] ^ D[0] ^ C[0] ^ C[4] ^ C[5] ^ C[6];
NewCRC[2] = D[29] ^ D[28] ^ D[25] ^ D[24] ^ D[22] ^ D[17] ^ D[15] ^
D[13] ^ D[12] ^ D[10] ^ D[8] ^ D[6] ^ D[2] ^ D[1] ^ D[0] ^
C[0] ^ C[1] ^ C[4] ^ C[5];
NewCRC[3] = D[30] ^ D[29] ^ D[26] ^ D[25] ^ D[23] ^ D[18] ^ D[16] ^
D[14] ^ D[13] ^ D[11] ^ D[9] ^ D[7] ^ D[3] ^ D[2] ^ D[1] ^
C[1] ^ C[2] ^ C[5] ^ C[6];
NewCRC[4] = D[31] ^ D[30] ^ D[27] ^ D[26] ^ D[24] ^ D[19] ^ D[17] ^
D[15] ^ D[14] ^ D[12] ^ D[10] ^ D[8] ^ D[4] ^ D[3] ^ D[2] ^
C[0] ^ C[2] ^ C[3] ^ C[6] ^ C[7];
NewCRC[5] = D[31] ^ D[28] ^ D[27] ^ D[25] ^ D[20] ^ D[18] ^ D[16] ^
D[15] ^ D[13] ^ D[11] ^ D[9] ^ D[5] ^ D[4] ^ D[3] ^ C[1] ^
C[3] ^ C[4] ^ C[7];
NewCRC[6] = D[29] ^ D[28] ^ D[26] ^ D[21] ^ D[19] ^ D[17] ^ D[16] ^
D[14] ^ D[12] ^ D[10] ^ D[6] ^ D[5] ^ D[4] ^ C[2] ^ C[4] ^
C[5];
NewCRC[7] = D[30] ^ D[29] ^ D[27] ^ D[22] ^ D[20] ^ D[18] ^ D[17] ^
D[15] ^ D[13] ^ D[11] ^ D[7] ^ D[6] ^ D[5] ^ C[3] ^ C[5] ^
C[6];
crc_res = 0;
for (i = 0; i < 8; i++)
crc_res |= (NewCRC[i] << i);
return crc_res;
}
/* regiesers addresses are not in order
so these arrays help simplify the code */
static const int cm_start[E1H_FUNC_MAX][9] = {
{MISC_FUNC0_START, TCM_FUNC0_START, UCM_FUNC0_START, CCM_FUNC0_START,
XCM_FUNC0_START, TSEM_FUNC0_START, USEM_FUNC0_START, CSEM_FUNC0_START,
XSEM_FUNC0_START},
{MISC_FUNC1_START, TCM_FUNC1_START, UCM_FUNC1_START, CCM_FUNC1_START,
XCM_FUNC1_START, TSEM_FUNC1_START, USEM_FUNC1_START, CSEM_FUNC1_START,
XSEM_FUNC1_START},
{MISC_FUNC2_START, TCM_FUNC2_START, UCM_FUNC2_START, CCM_FUNC2_START,
XCM_FUNC2_START, TSEM_FUNC2_START, USEM_FUNC2_START, CSEM_FUNC2_START,
XSEM_FUNC2_START},
{MISC_FUNC3_START, TCM_FUNC3_START, UCM_FUNC3_START, CCM_FUNC3_START,
XCM_FUNC3_START, TSEM_FUNC3_START, USEM_FUNC3_START, CSEM_FUNC3_START,
XSEM_FUNC3_START},
{MISC_FUNC4_START, TCM_FUNC4_START, UCM_FUNC4_START, CCM_FUNC4_START,
XCM_FUNC4_START, TSEM_FUNC4_START, USEM_FUNC4_START, CSEM_FUNC4_START,
XSEM_FUNC4_START},
{MISC_FUNC5_START, TCM_FUNC5_START, UCM_FUNC5_START, CCM_FUNC5_START,
XCM_FUNC5_START, TSEM_FUNC5_START, USEM_FUNC5_START, CSEM_FUNC5_START,
XSEM_FUNC5_START},
{MISC_FUNC6_START, TCM_FUNC6_START, UCM_FUNC6_START, CCM_FUNC6_START,
XCM_FUNC6_START, TSEM_FUNC6_START, USEM_FUNC6_START, CSEM_FUNC6_START,
XSEM_FUNC6_START},
{MISC_FUNC7_START, TCM_FUNC7_START, UCM_FUNC7_START, CCM_FUNC7_START,
XCM_FUNC7_START, TSEM_FUNC7_START, USEM_FUNC7_START, CSEM_FUNC7_START,
XSEM_FUNC7_START}
};
static const int cm_end[E1H_FUNC_MAX][9] = {
{MISC_FUNC0_END, TCM_FUNC0_END, UCM_FUNC0_END, CCM_FUNC0_END,
XCM_FUNC0_END, TSEM_FUNC0_END, USEM_FUNC0_END, CSEM_FUNC0_END,
XSEM_FUNC0_END},
{MISC_FUNC1_END, TCM_FUNC1_END, UCM_FUNC1_END, CCM_FUNC1_END,
XCM_FUNC1_END, TSEM_FUNC1_END, USEM_FUNC1_END, CSEM_FUNC1_END,
XSEM_FUNC1_END},
{MISC_FUNC2_END, TCM_FUNC2_END, UCM_FUNC2_END, CCM_FUNC2_END,
XCM_FUNC2_END, TSEM_FUNC2_END, USEM_FUNC2_END, CSEM_FUNC2_END,
XSEM_FUNC2_END},
{MISC_FUNC3_END, TCM_FUNC3_END, UCM_FUNC3_END, CCM_FUNC3_END,
XCM_FUNC3_END, TSEM_FUNC3_END, USEM_FUNC3_END, CSEM_FUNC3_END,
XSEM_FUNC3_END},
{MISC_FUNC4_END, TCM_FUNC4_END, UCM_FUNC4_END, CCM_FUNC4_END,
XCM_FUNC4_END, TSEM_FUNC4_END, USEM_FUNC4_END, CSEM_FUNC4_END,
XSEM_FUNC4_END},
{MISC_FUNC5_END, TCM_FUNC5_END, UCM_FUNC5_END, CCM_FUNC5_END,
XCM_FUNC5_END, TSEM_FUNC5_END, USEM_FUNC5_END, CSEM_FUNC5_END,
XSEM_FUNC5_END},
{MISC_FUNC6_END, TCM_FUNC6_END, UCM_FUNC6_END, CCM_FUNC6_END,
XCM_FUNC6_END, TSEM_FUNC6_END, USEM_FUNC6_END, CSEM_FUNC6_END,
XSEM_FUNC6_END},
{MISC_FUNC7_END, TCM_FUNC7_END, UCM_FUNC7_END, CCM_FUNC7_END,
XCM_FUNC7_END, TSEM_FUNC7_END, USEM_FUNC7_END, CSEM_FUNC7_END,
XSEM_FUNC7_END},
};
static const int hc_limits[E1H_FUNC_MAX][2] = {
{HC_FUNC0_START, HC_FUNC0_END},
{HC_FUNC1_START, HC_FUNC1_END},
{HC_FUNC2_START, HC_FUNC2_END},
{HC_FUNC3_START, HC_FUNC3_END},
{HC_FUNC4_START, HC_FUNC4_END},
{HC_FUNC5_START, HC_FUNC5_END},
{HC_FUNC6_START, HC_FUNC6_END},
{HC_FUNC7_START, HC_FUNC7_END}
};
#endif /* BNX2X_INIT_H */
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