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linux/drivers/net/ethernet/qlogic/qed/qed_init_fw_funcs.c
Alexander Lobakin 5ab903418a net: qed: sanitize BE/LE data processing 
Current code assumes that both host and device operates in Little Endian
in lots of places. While this is true for x86 platform, this doesn't mean
we should not care about this.

This commit addresses all parts of the code that were pointed out by sparse
checker. All operations with restricted (__be*/__le*) types are now
protected with explicit from/to CPU conversions, even if they're noops on
common setups.

I'm sure there are more such places, but this implies a deeper code
investigation, and is a subject for future works.

Signed-off-by: Alexander Lobakin <alobakin@marvell.com>
Signed-off-by: Igor Russkikh <irusskikh@marvell.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
2020-07-06 13:18:56 -07:00

1703 lines
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// SPDX-License-Identifier: (GPL-2.0-only OR BSD-3-Clause)
/* QLogic qed NIC Driver
* Copyright (c) 2015-2017 QLogic Corporation
* Copyright (c) 2019-2020 Marvell International Ltd.
*/
#include <linux/types.h>
#include <linux/crc8.h>
#include <linux/delay.h>
#include <linux/kernel.h>
#include <linux/slab.h>
#include <linux/string.h>
#include "qed_hsi.h"
#include "qed_hw.h"
#include "qed_init_ops.h"
#include "qed_reg_addr.h"
#define CDU_VALIDATION_DEFAULT_CFG 61
static u16 con_region_offsets[3][NUM_OF_CONNECTION_TYPES_E4] = {
{400, 336, 352, 368, 304, 384, 416, 352}, /* region 3 offsets */
{528, 496, 416, 512, 448, 512, 544, 480}, /* region 4 offsets */
{608, 544, 496, 576, 576, 592, 624, 560} /* region 5 offsets */
};
static u16 task_region_offsets[1][NUM_OF_CONNECTION_TYPES_E4] = {
{240, 240, 112, 0, 0, 0, 0, 96} /* region 1 offsets */
};
/* General constants */
#define QM_PQ_MEM_4KB(pq_size) (pq_size ? DIV_ROUND_UP((pq_size + 1) * \
QM_PQ_ELEMENT_SIZE, \
0x1000) : 0)
#define QM_PQ_SIZE_256B(pq_size) (pq_size ? DIV_ROUND_UP(pq_size, \
0x100) - 1 : 0)
#define QM_INVALID_PQ_ID 0xffff
/* Max link speed (in Mbps) */
#define QM_MAX_LINK_SPEED 100000
/* Feature enable */
#define QM_BYPASS_EN 1
#define QM_BYTE_CRD_EN 1
/* Other PQ constants */
#define QM_OTHER_PQS_PER_PF 4
/* WFQ constants */
/* Upper bound in MB, 10 * burst size of 1ms in 50Gbps */
#define QM_WFQ_UPPER_BOUND 62500000
/* Bit of VOQ in WFQ VP PQ map */
#define QM_WFQ_VP_PQ_VOQ_SHIFT 0
/* Bit of PF in WFQ VP PQ map */
#define QM_WFQ_VP_PQ_PF_E4_SHIFT 5
/* 0x9000 = 4*9*1024 */
#define QM_WFQ_INC_VAL(weight) ((weight) * 0x9000)
/* Max WFQ increment value is 0.7 * upper bound */
#define QM_WFQ_MAX_INC_VAL ((QM_WFQ_UPPER_BOUND * 7) / 10)
/* RL constants */
/* Period in us */
#define QM_RL_PERIOD 5
/* Period in 25MHz cycles */
#define QM_RL_PERIOD_CLK_25M (25 * QM_RL_PERIOD)
/* RL increment value - rate is specified in mbps */
#define QM_RL_INC_VAL(rate) ({ \
typeof(rate) __rate = (rate); \
max_t(u32, \
(u32)(((__rate ? __rate : 1000000) * QM_RL_PERIOD * 101) / \
(8 * 100)), \
1); })
/* PF RL Upper bound is set to 10 * burst size of 1ms in 50Gbps */
#define QM_PF_RL_UPPER_BOUND 62500000
/* Max PF RL increment value is 0.7 * upper bound */
#define QM_PF_RL_MAX_INC_VAL ((QM_PF_RL_UPPER_BOUND * 7) / 10)
/* Vport RL Upper bound, link speed is in Mpbs */
#define QM_VP_RL_UPPER_BOUND(speed) ((u32)max_t(u32, \
QM_RL_INC_VAL(speed), \
9700 + 1000))
/* Max Vport RL increment value is the Vport RL upper bound */
#define QM_VP_RL_MAX_INC_VAL(speed) QM_VP_RL_UPPER_BOUND(speed)
/* Vport RL credit threshold in case of QM bypass */
#define QM_VP_RL_BYPASS_THRESH_SPEED (QM_VP_RL_UPPER_BOUND(10000) - 1)
/* AFullOprtnstcCrdMask constants */
#define QM_OPPOR_LINE_VOQ_DEF 1
#define QM_OPPOR_FW_STOP_DEF 0
#define QM_OPPOR_PQ_EMPTY_DEF 1
/* Command Queue constants */
/* Pure LB CmdQ lines (+spare) */
#define PBF_CMDQ_PURE_LB_LINES 150
#define PBF_CMDQ_LINES_RT_OFFSET(ext_voq) \
(PBF_REG_YCMD_QS_NUM_LINES_VOQ0_RT_OFFSET + \
(ext_voq) * (PBF_REG_YCMD_QS_NUM_LINES_VOQ1_RT_OFFSET - \
PBF_REG_YCMD_QS_NUM_LINES_VOQ0_RT_OFFSET))
#define PBF_BTB_GUARANTEED_RT_OFFSET(ext_voq) \
(PBF_REG_BTB_GUARANTEED_VOQ0_RT_OFFSET + \
(ext_voq) * (PBF_REG_BTB_GUARANTEED_VOQ1_RT_OFFSET - \
PBF_REG_BTB_GUARANTEED_VOQ0_RT_OFFSET))
/* Returns the VOQ line credit for the specified number of PBF command lines.
* PBF lines are specified in 256b units.
*/
#define QM_VOQ_LINE_CRD(pbf_cmd_lines) \
((((pbf_cmd_lines) - 4) * 2) | QM_LINE_CRD_REG_SIGN_BIT)
/* BTB: blocks constants (block size = 256B) */
/* 256B blocks in 9700B packet */
#define BTB_JUMBO_PKT_BLOCKS 38
/* Headroom per-port */
#define BTB_HEADROOM_BLOCKS BTB_JUMBO_PKT_BLOCKS
#define BTB_PURE_LB_FACTOR 10
/* Factored (hence really 0.7) */
#define BTB_PURE_LB_RATIO 7
/* QM stop command constants */
#define QM_STOP_PQ_MASK_WIDTH 32
#define QM_STOP_CMD_ADDR 2
#define QM_STOP_CMD_STRUCT_SIZE 2
#define QM_STOP_CMD_PAUSE_MASK_OFFSET 0
#define QM_STOP_CMD_PAUSE_MASK_SHIFT 0
#define QM_STOP_CMD_PAUSE_MASK_MASK -1
#define QM_STOP_CMD_GROUP_ID_OFFSET 1
#define QM_STOP_CMD_GROUP_ID_SHIFT 16
#define QM_STOP_CMD_GROUP_ID_MASK 15
#define QM_STOP_CMD_PQ_TYPE_OFFSET 1
#define QM_STOP_CMD_PQ_TYPE_SHIFT 24
#define QM_STOP_CMD_PQ_TYPE_MASK 1
#define QM_STOP_CMD_MAX_POLL_COUNT 100
#define QM_STOP_CMD_POLL_PERIOD_US 500
/* QM command macros */
#define QM_CMD_STRUCT_SIZE(cmd) cmd ## _STRUCT_SIZE
#define QM_CMD_SET_FIELD(var, cmd, field, value) \
SET_FIELD(var[cmd ## _ ## field ## _OFFSET], \
cmd ## _ ## field, \
value)
#define QM_INIT_TX_PQ_MAP(p_hwfn, map, chip, pq_id, vp_pq_id, rl_valid, \
rl_id, ext_voq, wrr) \
do { \
u32 __reg = 0; \
\
BUILD_BUG_ON(sizeof((map).reg) != sizeof(__reg)); \
\
SET_FIELD(__reg, QM_RF_PQ_MAP_##chip##_PQ_VALID, 1); \
SET_FIELD(__reg, QM_RF_PQ_MAP_##chip##_RL_VALID, \
!!(rl_valid)); \
SET_FIELD(__reg, QM_RF_PQ_MAP_##chip##_VP_PQ_ID, (vp_pq_id)); \
SET_FIELD(__reg, QM_RF_PQ_MAP_##chip##_RL_ID, (rl_id)); \
SET_FIELD(__reg, QM_RF_PQ_MAP_##chip##_VOQ, (ext_voq)); \
SET_FIELD(__reg, QM_RF_PQ_MAP_##chip##_WRR_WEIGHT_GROUP, \
(wrr)); \
\
STORE_RT_REG((p_hwfn), QM_REG_TXPQMAP_RT_OFFSET + (pq_id), \
__reg); \
(map).reg = cpu_to_le32(__reg); \
} while (0)
#define WRITE_PQ_INFO_TO_RAM 1
#define PQ_INFO_ELEMENT(vp, pf, tc, port, rl_valid, rl) \
(((vp) << 0) | ((pf) << 12) | ((tc) << 16) | ((port) << 20) | \
((rl_valid ? 1 : 0) << 22) | (((rl) & 255) << 24) | \
(((rl) >> 8) << 9))
#define PQ_INFO_RAM_GRC_ADDRESS(pq_id) \
XSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM + \
XSTORM_PQ_INFO_OFFSET(pq_id)
/******************** INTERNAL IMPLEMENTATION *********************/
/* Returns the external VOQ number */
static u8 qed_get_ext_voq(struct qed_hwfn *p_hwfn,
u8 port_id, u8 tc, u8 max_phys_tcs_per_port)
{
if (tc == PURE_LB_TC)
return NUM_OF_PHYS_TCS * MAX_NUM_PORTS_BB + port_id;
else
return port_id * max_phys_tcs_per_port + tc;
}
/* Prepare PF RL enable/disable runtime init values */
static void qed_enable_pf_rl(struct qed_hwfn *p_hwfn, bool pf_rl_en)
{
STORE_RT_REG(p_hwfn, QM_REG_RLPFENABLE_RT_OFFSET, pf_rl_en ? 1 : 0);
if (pf_rl_en) {
u8 num_ext_voqs = MAX_NUM_VOQS_E4;
u64 voq_bit_mask = ((u64)1 << num_ext_voqs) - 1;
/* Enable RLs for all VOQs */
STORE_RT_REG(p_hwfn,
QM_REG_RLPFVOQENABLE_RT_OFFSET,
(u32)voq_bit_mask);
/* Write RL period */
STORE_RT_REG(p_hwfn,
QM_REG_RLPFPERIOD_RT_OFFSET, QM_RL_PERIOD_CLK_25M);
STORE_RT_REG(p_hwfn,
QM_REG_RLPFPERIODTIMER_RT_OFFSET,
QM_RL_PERIOD_CLK_25M);
/* Set credit threshold for QM bypass flow */
if (QM_BYPASS_EN)
STORE_RT_REG(p_hwfn,
QM_REG_AFULLQMBYPTHRPFRL_RT_OFFSET,
QM_PF_RL_UPPER_BOUND);
}
}
/* Prepare PF WFQ enable/disable runtime init values */
static void qed_enable_pf_wfq(struct qed_hwfn *p_hwfn, bool pf_wfq_en)
{
STORE_RT_REG(p_hwfn, QM_REG_WFQPFENABLE_RT_OFFSET, pf_wfq_en ? 1 : 0);
/* Set credit threshold for QM bypass flow */
if (pf_wfq_en && QM_BYPASS_EN)
STORE_RT_REG(p_hwfn,
QM_REG_AFULLQMBYPTHRPFWFQ_RT_OFFSET,
QM_WFQ_UPPER_BOUND);
}
/* Prepare global RL enable/disable runtime init values */
static void qed_enable_global_rl(struct qed_hwfn *p_hwfn, bool global_rl_en)
{
STORE_RT_REG(p_hwfn, QM_REG_RLGLBLENABLE_RT_OFFSET,
global_rl_en ? 1 : 0);
if (global_rl_en) {
/* Write RL period (use timer 0 only) */
STORE_RT_REG(p_hwfn,
QM_REG_RLGLBLPERIOD_0_RT_OFFSET,
QM_RL_PERIOD_CLK_25M);
STORE_RT_REG(p_hwfn,
QM_REG_RLGLBLPERIODTIMER_0_RT_OFFSET,
QM_RL_PERIOD_CLK_25M);
/* Set credit threshold for QM bypass flow */
if (QM_BYPASS_EN)
STORE_RT_REG(p_hwfn,
QM_REG_AFULLQMBYPTHRGLBLRL_RT_OFFSET,
QM_VP_RL_BYPASS_THRESH_SPEED);
}
}
/* Prepare VPORT WFQ enable/disable runtime init values */
static void qed_enable_vport_wfq(struct qed_hwfn *p_hwfn, bool vport_wfq_en)
{
STORE_RT_REG(p_hwfn, QM_REG_WFQVPENABLE_RT_OFFSET,
vport_wfq_en ? 1 : 0);
/* Set credit threshold for QM bypass flow */
if (vport_wfq_en && QM_BYPASS_EN)
STORE_RT_REG(p_hwfn,
QM_REG_AFULLQMBYPTHRVPWFQ_RT_OFFSET,
QM_WFQ_UPPER_BOUND);
}
/* Prepare runtime init values to allocate PBF command queue lines for
* the specified VOQ.
*/
static void qed_cmdq_lines_voq_rt_init(struct qed_hwfn *p_hwfn,
u8 ext_voq, u16 cmdq_lines)
{
u32 qm_line_crd = QM_VOQ_LINE_CRD(cmdq_lines);
OVERWRITE_RT_REG(p_hwfn, PBF_CMDQ_LINES_RT_OFFSET(ext_voq),
(u32)cmdq_lines);
STORE_RT_REG(p_hwfn, QM_REG_VOQCRDLINE_RT_OFFSET + ext_voq,
qm_line_crd);
STORE_RT_REG(p_hwfn, QM_REG_VOQINITCRDLINE_RT_OFFSET + ext_voq,
qm_line_crd);
}
/* Prepare runtime init values to allocate PBF command queue lines. */
static void qed_cmdq_lines_rt_init(
struct qed_hwfn *p_hwfn,
u8 max_ports_per_engine,
u8 max_phys_tcs_per_port,
struct init_qm_port_params port_params[MAX_NUM_PORTS])
{
u8 tc, ext_voq, port_id, num_tcs_in_port;
u8 num_ext_voqs = MAX_NUM_VOQS_E4;
/* Clear PBF lines of all VOQs */
for (ext_voq = 0; ext_voq < num_ext_voqs; ext_voq++)
STORE_RT_REG(p_hwfn, PBF_CMDQ_LINES_RT_OFFSET(ext_voq), 0);
for (port_id = 0; port_id < max_ports_per_engine; port_id++) {
u16 phys_lines, phys_lines_per_tc;
if (!port_params[port_id].active)
continue;
/* Find number of command queue lines to divide between the
* active physical TCs.
*/
phys_lines = port_params[port_id].num_pbf_cmd_lines;
phys_lines -= PBF_CMDQ_PURE_LB_LINES;
/* Find #lines per active physical TC */
num_tcs_in_port = 0;
for (tc = 0; tc < max_phys_tcs_per_port; tc++)
if (((port_params[port_id].active_phys_tcs >>
tc) & 0x1) == 1)
num_tcs_in_port++;
phys_lines_per_tc = phys_lines / num_tcs_in_port;
/* Init registers per active TC */
for (tc = 0; tc < max_phys_tcs_per_port; tc++) {
ext_voq = qed_get_ext_voq(p_hwfn,
port_id,
tc, max_phys_tcs_per_port);
if (((port_params[port_id].active_phys_tcs >>
tc) & 0x1) == 1)
qed_cmdq_lines_voq_rt_init(p_hwfn,
ext_voq,
phys_lines_per_tc);
}
/* Init registers for pure LB TC */
ext_voq = qed_get_ext_voq(p_hwfn,
port_id,
PURE_LB_TC, max_phys_tcs_per_port);
qed_cmdq_lines_voq_rt_init(p_hwfn, ext_voq,
PBF_CMDQ_PURE_LB_LINES);
}
}
/* Prepare runtime init values to allocate guaranteed BTB blocks for the
* specified port. The guaranteed BTB space is divided between the TCs as
* follows (shared space Is currently not used):
* 1. Parameters:
* B - BTB blocks for this port
* C - Number of physical TCs for this port
* 2. Calculation:
* a. 38 blocks (9700B jumbo frame) are allocated for global per port
* headroom.
* b. B = B - 38 (remainder after global headroom allocation).
* c. MAX(38,B/(C+0.7)) blocks are allocated for the pure LB VOQ.
* d. B = B - MAX(38, B/(C+0.7)) (remainder after pure LB allocation).
* e. B/C blocks are allocated for each physical TC.
* Assumptions:
* - MTU is up to 9700 bytes (38 blocks)
* - All TCs are considered symmetrical (same rate and packet size)
* - No optimization for lossy TC (all are considered lossless). Shared space
* is not enabled and allocated for each TC.
*/
static void qed_btb_blocks_rt_init(
struct qed_hwfn *p_hwfn,
u8 max_ports_per_engine,
u8 max_phys_tcs_per_port,
struct init_qm_port_params port_params[MAX_NUM_PORTS])
{
u32 usable_blocks, pure_lb_blocks, phys_blocks;
u8 tc, ext_voq, port_id, num_tcs_in_port;
for (port_id = 0; port_id < max_ports_per_engine; port_id++) {
if (!port_params[port_id].active)
continue;
/* Subtract headroom blocks */
usable_blocks = port_params[port_id].num_btb_blocks -
BTB_HEADROOM_BLOCKS;
/* Find blocks per physical TC. Use factor to avoid floating
* arithmethic.
*/
num_tcs_in_port = 0;
for (tc = 0; tc < NUM_OF_PHYS_TCS; tc++)
if (((port_params[port_id].active_phys_tcs >>
tc) & 0x1) == 1)
num_tcs_in_port++;
pure_lb_blocks = (usable_blocks * BTB_PURE_LB_FACTOR) /
(num_tcs_in_port * BTB_PURE_LB_FACTOR +
BTB_PURE_LB_RATIO);
pure_lb_blocks = max_t(u32, BTB_JUMBO_PKT_BLOCKS,
pure_lb_blocks / BTB_PURE_LB_FACTOR);
phys_blocks = (usable_blocks - pure_lb_blocks) /
num_tcs_in_port;
/* Init physical TCs */
for (tc = 0; tc < NUM_OF_PHYS_TCS; tc++) {
if (((port_params[port_id].active_phys_tcs >>
tc) & 0x1) == 1) {
ext_voq =
qed_get_ext_voq(p_hwfn,
port_id,
tc,
max_phys_tcs_per_port);
STORE_RT_REG(p_hwfn,
PBF_BTB_GUARANTEED_RT_OFFSET
(ext_voq), phys_blocks);
}
}
/* Init pure LB TC */
ext_voq = qed_get_ext_voq(p_hwfn,
port_id,
PURE_LB_TC, max_phys_tcs_per_port);
STORE_RT_REG(p_hwfn, PBF_BTB_GUARANTEED_RT_OFFSET(ext_voq),
pure_lb_blocks);
}
}
/* Prepare runtime init values for the specified RL.
* Set max link speed (100Gbps) per rate limiter.
* Return -1 on error.
*/
static int qed_global_rl_rt_init(struct qed_hwfn *p_hwfn)
{
u32 upper_bound = QM_VP_RL_UPPER_BOUND(QM_MAX_LINK_SPEED) |
(u32)QM_RL_CRD_REG_SIGN_BIT;
u32 inc_val;
u16 rl_id;
/* Go over all global RLs */
for (rl_id = 0; rl_id < MAX_QM_GLOBAL_RLS; rl_id++) {
inc_val = QM_RL_INC_VAL(QM_MAX_LINK_SPEED);
STORE_RT_REG(p_hwfn,
QM_REG_RLGLBLCRD_RT_OFFSET + rl_id,
(u32)QM_RL_CRD_REG_SIGN_BIT);
STORE_RT_REG(p_hwfn,
QM_REG_RLGLBLUPPERBOUND_RT_OFFSET + rl_id,
upper_bound);
STORE_RT_REG(p_hwfn,
QM_REG_RLGLBLINCVAL_RT_OFFSET + rl_id, inc_val);
}
return 0;
}
/* Prepare Tx PQ mapping runtime init values for the specified PF */
static void qed_tx_pq_map_rt_init(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
struct qed_qm_pf_rt_init_params *p_params,
u32 base_mem_addr_4kb)
{
u32 tx_pq_vf_mask[MAX_QM_TX_QUEUES / QM_PF_QUEUE_GROUP_SIZE] = { 0 };
struct init_qm_vport_params *vport_params = p_params->vport_params;
u32 num_tx_pq_vf_masks = MAX_QM_TX_QUEUES / QM_PF_QUEUE_GROUP_SIZE;
u16 num_pqs, first_pq_group, last_pq_group, i, j, pq_id, pq_group;
struct init_qm_pq_params *pq_params = p_params->pq_params;
u32 pq_mem_4kb, vport_pq_mem_4kb, mem_addr_4kb;
num_pqs = p_params->num_pf_pqs + p_params->num_vf_pqs;
first_pq_group = p_params->start_pq / QM_PF_QUEUE_GROUP_SIZE;
last_pq_group = (p_params->start_pq + num_pqs - 1) /
QM_PF_QUEUE_GROUP_SIZE;
pq_mem_4kb = QM_PQ_MEM_4KB(p_params->num_pf_cids);
vport_pq_mem_4kb = QM_PQ_MEM_4KB(p_params->num_vf_cids);
mem_addr_4kb = base_mem_addr_4kb;
/* Set mapping from PQ group to PF */
for (pq_group = first_pq_group; pq_group <= last_pq_group; pq_group++)
STORE_RT_REG(p_hwfn, QM_REG_PQTX2PF_0_RT_OFFSET + pq_group,
(u32)(p_params->pf_id));
/* Set PQ sizes */
STORE_RT_REG(p_hwfn, QM_REG_MAXPQSIZE_0_RT_OFFSET,
QM_PQ_SIZE_256B(p_params->num_pf_cids));
STORE_RT_REG(p_hwfn, QM_REG_MAXPQSIZE_1_RT_OFFSET,
QM_PQ_SIZE_256B(p_params->num_vf_cids));
/* Go over all Tx PQs */
for (i = 0, pq_id = p_params->start_pq; i < num_pqs; i++, pq_id++) {
u16 *p_first_tx_pq_id, vport_id_in_pf;
struct qm_rf_pq_map_e4 tx_pq_map;
u8 tc_id = pq_params[i].tc_id;
bool is_vf_pq;
u8 ext_voq;
ext_voq = qed_get_ext_voq(p_hwfn,
pq_params[i].port_id,
tc_id,
p_params->max_phys_tcs_per_port);
is_vf_pq = (i >= p_params->num_pf_pqs);
/* Update first Tx PQ of VPORT/TC */
vport_id_in_pf = pq_params[i].vport_id - p_params->start_vport;
p_first_tx_pq_id =
&vport_params[vport_id_in_pf].first_tx_pq_id[tc_id];
if (*p_first_tx_pq_id == QM_INVALID_PQ_ID) {
u32 map_val =
(ext_voq << QM_WFQ_VP_PQ_VOQ_SHIFT) |
(p_params->pf_id << QM_WFQ_VP_PQ_PF_E4_SHIFT);
/* Create new VP PQ */
*p_first_tx_pq_id = pq_id;
/* Map VP PQ to VOQ and PF */
STORE_RT_REG(p_hwfn,
QM_REG_WFQVPMAP_RT_OFFSET +
*p_first_tx_pq_id,
map_val);
}
/* Prepare PQ map entry */
QM_INIT_TX_PQ_MAP(p_hwfn,
tx_pq_map,
E4,
pq_id,
*p_first_tx_pq_id,
pq_params[i].rl_valid,
pq_params[i].rl_id,
ext_voq, pq_params[i].wrr_group);
/* Set PQ base address */
STORE_RT_REG(p_hwfn,
QM_REG_BASEADDRTXPQ_RT_OFFSET + pq_id,
mem_addr_4kb);
/* Clear PQ pointer table entry (64 bit) */
if (p_params->is_pf_loading)
for (j = 0; j < 2; j++)
STORE_RT_REG(p_hwfn,
QM_REG_PTRTBLTX_RT_OFFSET +
(pq_id * 2) + j, 0);
/* Write PQ info to RAM */
if (WRITE_PQ_INFO_TO_RAM != 0) {
u32 pq_info = 0;
pq_info = PQ_INFO_ELEMENT(*p_first_tx_pq_id,
p_params->pf_id,
tc_id,
pq_params[i].port_id,
pq_params[i].rl_valid,
pq_params[i].rl_id);
qed_wr(p_hwfn, p_ptt, PQ_INFO_RAM_GRC_ADDRESS(pq_id),
pq_info);
}
/* If VF PQ, add indication to PQ VF mask */
if (is_vf_pq) {
tx_pq_vf_mask[pq_id /
QM_PF_QUEUE_GROUP_SIZE] |=
BIT((pq_id % QM_PF_QUEUE_GROUP_SIZE));
mem_addr_4kb += vport_pq_mem_4kb;
} else {
mem_addr_4kb += pq_mem_4kb;
}
}
/* Store Tx PQ VF mask to size select register */
for (i = 0; i < num_tx_pq_vf_masks; i++)
if (tx_pq_vf_mask[i])
STORE_RT_REG(p_hwfn,
QM_REG_MAXPQSIZETXSEL_0_RT_OFFSET + i,
tx_pq_vf_mask[i]);
}
/* Prepare Other PQ mapping runtime init values for the specified PF */
static void qed_other_pq_map_rt_init(struct qed_hwfn *p_hwfn,
u8 pf_id,
bool is_pf_loading,
u32 num_pf_cids,
u32 num_tids, u32 base_mem_addr_4kb)
{
u32 pq_size, pq_mem_4kb, mem_addr_4kb;
u16 i, j, pq_id, pq_group;
/* A single other PQ group is used in each PF, where PQ group i is used
* in PF i.
*/
pq_group = pf_id;
pq_size = num_pf_cids + num_tids;
pq_mem_4kb = QM_PQ_MEM_4KB(pq_size);
mem_addr_4kb = base_mem_addr_4kb;
/* Map PQ group to PF */
STORE_RT_REG(p_hwfn, QM_REG_PQOTHER2PF_0_RT_OFFSET + pq_group,
(u32)(pf_id));
/* Set PQ sizes */
STORE_RT_REG(p_hwfn, QM_REG_MAXPQSIZE_2_RT_OFFSET,
QM_PQ_SIZE_256B(pq_size));
for (i = 0, pq_id = pf_id * QM_PF_QUEUE_GROUP_SIZE;
i < QM_OTHER_PQS_PER_PF; i++, pq_id++) {
/* Set PQ base address */
STORE_RT_REG(p_hwfn,
QM_REG_BASEADDROTHERPQ_RT_OFFSET + pq_id,
mem_addr_4kb);
/* Clear PQ pointer table entry */
if (is_pf_loading)
for (j = 0; j < 2; j++)
STORE_RT_REG(p_hwfn,
QM_REG_PTRTBLOTHER_RT_OFFSET +
(pq_id * 2) + j, 0);
mem_addr_4kb += pq_mem_4kb;
}
}
/* Prepare PF WFQ runtime init values for the specified PF.
* Return -1 on error.
*/
static int qed_pf_wfq_rt_init(struct qed_hwfn *p_hwfn,
struct qed_qm_pf_rt_init_params *p_params)
{
u16 num_tx_pqs = p_params->num_pf_pqs + p_params->num_vf_pqs;
struct init_qm_pq_params *pq_params = p_params->pq_params;
u32 inc_val, crd_reg_offset;
u8 ext_voq;
u16 i;
inc_val = QM_WFQ_INC_VAL(p_params->pf_wfq);
if (!inc_val || inc_val > QM_WFQ_MAX_INC_VAL) {
DP_NOTICE(p_hwfn, "Invalid PF WFQ weight configuration\n");
return -1;
}
for (i = 0; i < num_tx_pqs; i++) {
ext_voq = qed_get_ext_voq(p_hwfn,
pq_params[i].port_id,
pq_params[i].tc_id,
p_params->max_phys_tcs_per_port);
crd_reg_offset =
(p_params->pf_id < MAX_NUM_PFS_BB ?
QM_REG_WFQPFCRD_RT_OFFSET :
QM_REG_WFQPFCRD_MSB_RT_OFFSET) +
ext_voq * MAX_NUM_PFS_BB +
(p_params->pf_id % MAX_NUM_PFS_BB);
OVERWRITE_RT_REG(p_hwfn,
crd_reg_offset, (u32)QM_WFQ_CRD_REG_SIGN_BIT);
}
STORE_RT_REG(p_hwfn,
QM_REG_WFQPFUPPERBOUND_RT_OFFSET + p_params->pf_id,
QM_WFQ_UPPER_BOUND | (u32)QM_WFQ_CRD_REG_SIGN_BIT);
STORE_RT_REG(p_hwfn, QM_REG_WFQPFWEIGHT_RT_OFFSET + p_params->pf_id,
inc_val);
return 0;
}
/* Prepare PF RL runtime init values for the specified PF.
* Return -1 on error.
*/
static int qed_pf_rl_rt_init(struct qed_hwfn *p_hwfn, u8 pf_id, u32 pf_rl)
{
u32 inc_val = QM_RL_INC_VAL(pf_rl);
if (inc_val > QM_PF_RL_MAX_INC_VAL) {
DP_NOTICE(p_hwfn, "Invalid PF rate limit configuration\n");
return -1;
}
STORE_RT_REG(p_hwfn,
QM_REG_RLPFCRD_RT_OFFSET + pf_id,
(u32)QM_RL_CRD_REG_SIGN_BIT);
STORE_RT_REG(p_hwfn,
QM_REG_RLPFUPPERBOUND_RT_OFFSET + pf_id,
QM_PF_RL_UPPER_BOUND | (u32)QM_RL_CRD_REG_SIGN_BIT);
STORE_RT_REG(p_hwfn, QM_REG_RLPFINCVAL_RT_OFFSET + pf_id, inc_val);
return 0;
}
/* Prepare VPORT WFQ runtime init values for the specified VPORTs.
* Return -1 on error.
*/
static int qed_vp_wfq_rt_init(struct qed_hwfn *p_hwfn,
u16 num_vports,
struct init_qm_vport_params *vport_params)
{
u16 vport_pq_id, i;
u32 inc_val;
u8 tc;
/* Go over all PF VPORTs */
for (i = 0; i < num_vports; i++) {
if (!vport_params[i].wfq)
continue;
inc_val = QM_WFQ_INC_VAL(vport_params[i].wfq);
if (inc_val > QM_WFQ_MAX_INC_VAL) {
DP_NOTICE(p_hwfn,
"Invalid VPORT WFQ weight configuration\n");
return -1;
}
/* Each VPORT can have several VPORT PQ IDs for various TCs */
for (tc = 0; tc < NUM_OF_TCS; tc++) {
vport_pq_id = vport_params[i].first_tx_pq_id[tc];
if (vport_pq_id != QM_INVALID_PQ_ID) {
STORE_RT_REG(p_hwfn,
QM_REG_WFQVPCRD_RT_OFFSET +
vport_pq_id,
(u32)QM_WFQ_CRD_REG_SIGN_BIT);
STORE_RT_REG(p_hwfn,
QM_REG_WFQVPWEIGHT_RT_OFFSET +
vport_pq_id, inc_val);
}
}
}
return 0;
}
static bool qed_poll_on_qm_cmd_ready(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt)
{
u32 reg_val, i;
for (i = 0, reg_val = 0; i < QM_STOP_CMD_MAX_POLL_COUNT && !reg_val;
i++) {
udelay(QM_STOP_CMD_POLL_PERIOD_US);
reg_val = qed_rd(p_hwfn, p_ptt, QM_REG_SDMCMDREADY);
}
/* Check if timeout while waiting for SDM command ready */
if (i == QM_STOP_CMD_MAX_POLL_COUNT) {
DP_VERBOSE(p_hwfn, NETIF_MSG_HW,
"Timeout when waiting for QM SDM command ready signal\n");
return false;
}
return true;
}
static bool qed_send_qm_cmd(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
u32 cmd_addr, u32 cmd_data_lsb, u32 cmd_data_msb)
{
if (!qed_poll_on_qm_cmd_ready(p_hwfn, p_ptt))
return false;
qed_wr(p_hwfn, p_ptt, QM_REG_SDMCMDADDR, cmd_addr);
qed_wr(p_hwfn, p_ptt, QM_REG_SDMCMDDATALSB, cmd_data_lsb);
qed_wr(p_hwfn, p_ptt, QM_REG_SDMCMDDATAMSB, cmd_data_msb);
qed_wr(p_hwfn, p_ptt, QM_REG_SDMCMDGO, 1);
qed_wr(p_hwfn, p_ptt, QM_REG_SDMCMDGO, 0);
return qed_poll_on_qm_cmd_ready(p_hwfn, p_ptt);
}
/******************** INTERFACE IMPLEMENTATION *********************/
u32 qed_qm_pf_mem_size(u32 num_pf_cids,
u32 num_vf_cids,
u32 num_tids, u16 num_pf_pqs, u16 num_vf_pqs)
{
return QM_PQ_MEM_4KB(num_pf_cids) * num_pf_pqs +
QM_PQ_MEM_4KB(num_vf_cids) * num_vf_pqs +
QM_PQ_MEM_4KB(num_pf_cids + num_tids) * QM_OTHER_PQS_PER_PF;
}
int qed_qm_common_rt_init(struct qed_hwfn *p_hwfn,
struct qed_qm_common_rt_init_params *p_params)
{
u32 mask = 0;
/* Init AFullOprtnstcCrdMask */
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_LINEVOQ,
QM_OPPOR_LINE_VOQ_DEF);
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_BYTEVOQ, QM_BYTE_CRD_EN);
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_PFWFQ, p_params->pf_wfq_en);
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_VPWFQ, p_params->vport_wfq_en);
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_PFRL, p_params->pf_rl_en);
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_VPQCNRL,
p_params->global_rl_en);
SET_FIELD(mask, QM_RF_OPPORTUNISTIC_MASK_FWPAUSE, QM_OPPOR_FW_STOP_DEF);
SET_FIELD(mask,
QM_RF_OPPORTUNISTIC_MASK_QUEUEEMPTY, QM_OPPOR_PQ_EMPTY_DEF);
STORE_RT_REG(p_hwfn, QM_REG_AFULLOPRTNSTCCRDMASK_RT_OFFSET, mask);
/* Enable/disable PF RL */
qed_enable_pf_rl(p_hwfn, p_params->pf_rl_en);
/* Enable/disable PF WFQ */
qed_enable_pf_wfq(p_hwfn, p_params->pf_wfq_en);
/* Enable/disable global RL */
qed_enable_global_rl(p_hwfn, p_params->global_rl_en);
/* Enable/disable VPORT WFQ */
qed_enable_vport_wfq(p_hwfn, p_params->vport_wfq_en);
/* Init PBF CMDQ line credit */
qed_cmdq_lines_rt_init(p_hwfn,
p_params->max_ports_per_engine,
p_params->max_phys_tcs_per_port,
p_params->port_params);
/* Init BTB blocks in PBF */
qed_btb_blocks_rt_init(p_hwfn,
p_params->max_ports_per_engine,
p_params->max_phys_tcs_per_port,
p_params->port_params);
qed_global_rl_rt_init(p_hwfn);
return 0;
}
int qed_qm_pf_rt_init(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
struct qed_qm_pf_rt_init_params *p_params)
{
struct init_qm_vport_params *vport_params = p_params->vport_params;
u32 other_mem_size_4kb = QM_PQ_MEM_4KB(p_params->num_pf_cids +
p_params->num_tids) *
QM_OTHER_PQS_PER_PF;
u16 i;
u8 tc;
/* Clear first Tx PQ ID array for each VPORT */
for (i = 0; i < p_params->num_vports; i++)
for (tc = 0; tc < NUM_OF_TCS; tc++)
vport_params[i].first_tx_pq_id[tc] = QM_INVALID_PQ_ID;
/* Map Other PQs (if any) */
qed_other_pq_map_rt_init(p_hwfn,
p_params->pf_id,
p_params->is_pf_loading, p_params->num_pf_cids,
p_params->num_tids, 0);
/* Map Tx PQs */
qed_tx_pq_map_rt_init(p_hwfn, p_ptt, p_params, other_mem_size_4kb);
/* Init PF WFQ */
if (p_params->pf_wfq)
if (qed_pf_wfq_rt_init(p_hwfn, p_params))
return -1;
/* Init PF RL */
if (qed_pf_rl_rt_init(p_hwfn, p_params->pf_id, p_params->pf_rl))
return -1;
/* Init VPORT WFQ */
if (qed_vp_wfq_rt_init(p_hwfn, p_params->num_vports, vport_params))
return -1;
return 0;
}
int qed_init_pf_wfq(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, u8 pf_id, u16 pf_wfq)
{
u32 inc_val = QM_WFQ_INC_VAL(pf_wfq);
if (!inc_val || inc_val > QM_WFQ_MAX_INC_VAL) {
DP_NOTICE(p_hwfn, "Invalid PF WFQ weight configuration\n");
return -1;
}
qed_wr(p_hwfn, p_ptt, QM_REG_WFQPFWEIGHT + pf_id * 4, inc_val);
return 0;
}
int qed_init_pf_rl(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, u8 pf_id, u32 pf_rl)
{
u32 inc_val = QM_RL_INC_VAL(pf_rl);
if (inc_val > QM_PF_RL_MAX_INC_VAL) {
DP_NOTICE(p_hwfn, "Invalid PF rate limit configuration\n");
return -1;
}
qed_wr(p_hwfn,
p_ptt, QM_REG_RLPFCRD + pf_id * 4, (u32)QM_RL_CRD_REG_SIGN_BIT);
qed_wr(p_hwfn, p_ptt, QM_REG_RLPFINCVAL + pf_id * 4, inc_val);
return 0;
}
int qed_init_vport_wfq(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
u16 first_tx_pq_id[NUM_OF_TCS], u16 wfq)
{
u16 vport_pq_id;
u32 inc_val;
u8 tc;
inc_val = QM_WFQ_INC_VAL(wfq);
if (!inc_val || inc_val > QM_WFQ_MAX_INC_VAL) {
DP_NOTICE(p_hwfn, "Invalid VPORT WFQ configuration.\n");
return -1;
}
/* A VPORT can have several VPORT PQ IDs for various TCs */
for (tc = 0; tc < NUM_OF_TCS; tc++) {
vport_pq_id = first_tx_pq_id[tc];
if (vport_pq_id != QM_INVALID_PQ_ID)
qed_wr(p_hwfn,
p_ptt,
QM_REG_WFQVPWEIGHT + vport_pq_id * 4, inc_val);
}
return 0;
}
int qed_init_global_rl(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, u16 rl_id, u32 rate_limit)
{
u32 inc_val;
inc_val = QM_RL_INC_VAL(rate_limit);
if (inc_val > QM_VP_RL_MAX_INC_VAL(rate_limit)) {
DP_NOTICE(p_hwfn, "Invalid rate limit configuration.\n");
return -1;
}
qed_wr(p_hwfn, p_ptt,
QM_REG_RLGLBLCRD + rl_id * 4, (u32)QM_RL_CRD_REG_SIGN_BIT);
qed_wr(p_hwfn, p_ptt, QM_REG_RLGLBLINCVAL + rl_id * 4, inc_val);
return 0;
}
bool qed_send_qm_stop_cmd(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
bool is_release_cmd,
bool is_tx_pq, u16 start_pq, u16 num_pqs)
{
u32 cmd_arr[QM_CMD_STRUCT_SIZE(QM_STOP_CMD)] = { 0 };
u32 pq_mask = 0, last_pq, pq_id;
last_pq = start_pq + num_pqs - 1;
/* Set command's PQ type */
QM_CMD_SET_FIELD(cmd_arr, QM_STOP_CMD, PQ_TYPE, is_tx_pq ? 0 : 1);
/* Go over requested PQs */
for (pq_id = start_pq; pq_id <= last_pq; pq_id++) {
/* Set PQ bit in mask (stop command only) */
if (!is_release_cmd)
pq_mask |= BIT((pq_id % QM_STOP_PQ_MASK_WIDTH));
/* If last PQ or end of PQ mask, write command */
if ((pq_id == last_pq) ||
(pq_id % QM_STOP_PQ_MASK_WIDTH ==
(QM_STOP_PQ_MASK_WIDTH - 1))) {
QM_CMD_SET_FIELD(cmd_arr,
QM_STOP_CMD, PAUSE_MASK, pq_mask);
QM_CMD_SET_FIELD(cmd_arr,
QM_STOP_CMD,
GROUP_ID,
pq_id / QM_STOP_PQ_MASK_WIDTH);
if (!qed_send_qm_cmd(p_hwfn, p_ptt, QM_STOP_CMD_ADDR,
cmd_arr[0], cmd_arr[1]))
return false;
pq_mask = 0;
}
}
return true;
}
#define SET_TUNNEL_TYPE_ENABLE_BIT(var, offset, enable) \
do { \
typeof(var) *__p_var = &(var); \
typeof(offset) __offset = offset; \
*__p_var = (*__p_var & ~BIT(__offset)) | \
((enable) ? BIT(__offset) : 0); \
} while (0)
#define PRS_ETH_TUNN_OUTPUT_FORMAT 0xF4DAB910
#define PRS_ETH_OUTPUT_FORMAT 0xFFFF4910
#define ARR_REG_WR(dev, ptt, addr, arr, arr_size) \
do { \
u32 i; \
\
for (i = 0; i < (arr_size); i++) \
qed_wr(dev, ptt, \
((addr) + (4 * i)), \
((u32 *)&(arr))[i]); \
} while (0)
/**
* qed_dmae_to_grc() - Internal function for writing from host to
* wide-bus registers (split registers are not supported yet).
*
* @p_hwfn: HW device data.
* @p_ptt: PTT window used for writing the registers.
* @p_data: Pointer to source data.
* @addr: Destination register address.
* @len_in_dwords: Data length in dwords (u32).
*
* Return: Length of the written data in dwords (u32) or -1 on invalid
* input.
*/
static int qed_dmae_to_grc(struct qed_hwfn *p_hwfn, struct qed_ptt *p_ptt,
__le32 *p_data, u32 addr, u32 len_in_dwords)
{
struct qed_dmae_params params = {};
u32 *data_cpu;
int rc;
if (!p_data)
return -1;
/* Set DMAE params */
SET_FIELD(params.flags, QED_DMAE_PARAMS_COMPLETION_DST, 1);
/* Execute DMAE command */
rc = qed_dmae_host2grc(p_hwfn, p_ptt,
(u64)(uintptr_t)(p_data),
addr, len_in_dwords, &params);
/* If not read using DMAE, read using GRC */
if (rc) {
DP_VERBOSE(p_hwfn,
QED_MSG_DEBUG,
"Failed writing to chip using DMAE, using GRC instead\n");
/* Swap to CPU byteorder and write to registers using GRC */
data_cpu = (__force u32 *)p_data;
le32_to_cpu_array(data_cpu, len_in_dwords);
ARR_REG_WR(p_hwfn, p_ptt, addr, data_cpu, len_in_dwords);
cpu_to_le32_array(data_cpu, len_in_dwords);
}
return len_in_dwords;
}
void qed_set_vxlan_dest_port(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, u16 dest_port)
{
/* Update PRS register */
qed_wr(p_hwfn, p_ptt, PRS_REG_VXLAN_PORT, dest_port);
/* Update NIG register */
qed_wr(p_hwfn, p_ptt, NIG_REG_VXLAN_CTRL, dest_port);
/* Update PBF register */
qed_wr(p_hwfn, p_ptt, PBF_REG_VXLAN_PORT, dest_port);
}
void qed_set_vxlan_enable(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, bool vxlan_enable)
{
u32 reg_val;
u8 shift;
/* Update PRS register */
reg_val = qed_rd(p_hwfn, p_ptt, PRS_REG_ENCAPSULATION_TYPE_EN);
shift = PRS_REG_ENCAPSULATION_TYPE_EN_VXLAN_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, vxlan_enable);
qed_wr(p_hwfn, p_ptt, PRS_REG_ENCAPSULATION_TYPE_EN, reg_val);
if (reg_val) {
reg_val =
qed_rd(p_hwfn, p_ptt, PRS_REG_OUTPUT_FORMAT_4_0_BB_K2);
/* Update output only if tunnel blocks not included. */
if (reg_val == (u32)PRS_ETH_OUTPUT_FORMAT)
qed_wr(p_hwfn, p_ptt, PRS_REG_OUTPUT_FORMAT_4_0_BB_K2,
(u32)PRS_ETH_TUNN_OUTPUT_FORMAT);
}
/* Update NIG register */
reg_val = qed_rd(p_hwfn, p_ptt, NIG_REG_ENC_TYPE_ENABLE);
shift = NIG_REG_ENC_TYPE_ENABLE_VXLAN_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, vxlan_enable);
qed_wr(p_hwfn, p_ptt, NIG_REG_ENC_TYPE_ENABLE, reg_val);
/* Update DORQ register */
qed_wr(p_hwfn,
p_ptt, DORQ_REG_L2_EDPM_TUNNEL_VXLAN_EN, vxlan_enable ? 1 : 0);
}
void qed_set_gre_enable(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
bool eth_gre_enable, bool ip_gre_enable)
{
u32 reg_val;
u8 shift;
/* Update PRS register */
reg_val = qed_rd(p_hwfn, p_ptt, PRS_REG_ENCAPSULATION_TYPE_EN);
shift = PRS_REG_ENCAPSULATION_TYPE_EN_ETH_OVER_GRE_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, eth_gre_enable);
shift = PRS_REG_ENCAPSULATION_TYPE_EN_IP_OVER_GRE_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, ip_gre_enable);
qed_wr(p_hwfn, p_ptt, PRS_REG_ENCAPSULATION_TYPE_EN, reg_val);
if (reg_val) {
reg_val =
qed_rd(p_hwfn, p_ptt, PRS_REG_OUTPUT_FORMAT_4_0_BB_K2);
/* Update output only if tunnel blocks not included. */
if (reg_val == (u32)PRS_ETH_OUTPUT_FORMAT)
qed_wr(p_hwfn, p_ptt, PRS_REG_OUTPUT_FORMAT_4_0_BB_K2,
(u32)PRS_ETH_TUNN_OUTPUT_FORMAT);
}
/* Update NIG register */
reg_val = qed_rd(p_hwfn, p_ptt, NIG_REG_ENC_TYPE_ENABLE);
shift = NIG_REG_ENC_TYPE_ENABLE_ETH_OVER_GRE_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, eth_gre_enable);
shift = NIG_REG_ENC_TYPE_ENABLE_IP_OVER_GRE_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, ip_gre_enable);
qed_wr(p_hwfn, p_ptt, NIG_REG_ENC_TYPE_ENABLE, reg_val);
/* Update DORQ registers */
qed_wr(p_hwfn,
p_ptt,
DORQ_REG_L2_EDPM_TUNNEL_GRE_ETH_EN, eth_gre_enable ? 1 : 0);
qed_wr(p_hwfn,
p_ptt, DORQ_REG_L2_EDPM_TUNNEL_GRE_IP_EN, ip_gre_enable ? 1 : 0);
}
void qed_set_geneve_dest_port(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, u16 dest_port)
{
/* Update PRS register */
qed_wr(p_hwfn, p_ptt, PRS_REG_NGE_PORT, dest_port);
/* Update NIG register */
qed_wr(p_hwfn, p_ptt, NIG_REG_NGE_PORT, dest_port);
/* Update PBF register */
qed_wr(p_hwfn, p_ptt, PBF_REG_NGE_PORT, dest_port);
}
void qed_set_geneve_enable(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
bool eth_geneve_enable, bool ip_geneve_enable)
{
u32 reg_val;
u8 shift;
/* Update PRS register */
reg_val = qed_rd(p_hwfn, p_ptt, PRS_REG_ENCAPSULATION_TYPE_EN);
shift = PRS_REG_ENCAPSULATION_TYPE_EN_ETH_OVER_GENEVE_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, eth_geneve_enable);
shift = PRS_REG_ENCAPSULATION_TYPE_EN_IP_OVER_GENEVE_ENABLE_SHIFT;
SET_TUNNEL_TYPE_ENABLE_BIT(reg_val, shift, ip_geneve_enable);
qed_wr(p_hwfn, p_ptt, PRS_REG_ENCAPSULATION_TYPE_EN, reg_val);
if (reg_val) {
reg_val =
qed_rd(p_hwfn, p_ptt, PRS_REG_OUTPUT_FORMAT_4_0_BB_K2);
/* Update output only if tunnel blocks not included. */
if (reg_val == (u32)PRS_ETH_OUTPUT_FORMAT)
qed_wr(p_hwfn, p_ptt, PRS_REG_OUTPUT_FORMAT_4_0_BB_K2,
(u32)PRS_ETH_TUNN_OUTPUT_FORMAT);
}
/* Update NIG register */
qed_wr(p_hwfn, p_ptt, NIG_REG_NGE_ETH_ENABLE,
eth_geneve_enable ? 1 : 0);
qed_wr(p_hwfn, p_ptt, NIG_REG_NGE_IP_ENABLE, ip_geneve_enable ? 1 : 0);
/* EDPM with geneve tunnel not supported in BB */
if (QED_IS_BB_B0(p_hwfn->cdev))
return;
/* Update DORQ registers */
qed_wr(p_hwfn,
p_ptt,
DORQ_REG_L2_EDPM_TUNNEL_NGE_ETH_EN_K2_E5,
eth_geneve_enable ? 1 : 0);
qed_wr(p_hwfn,
p_ptt,
DORQ_REG_L2_EDPM_TUNNEL_NGE_IP_EN_K2_E5,
ip_geneve_enable ? 1 : 0);
}
#define PRS_ETH_VXLAN_NO_L2_ENABLE_OFFSET 3
#define PRS_ETH_VXLAN_NO_L2_OUTPUT_FORMAT -925189872
void qed_set_vxlan_no_l2_enable(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt, bool enable)
{
u32 reg_val, cfg_mask;
/* read PRS config register */
reg_val = qed_rd(p_hwfn, p_ptt, PRS_REG_MSG_INFO);
/* set VXLAN_NO_L2_ENABLE mask */
cfg_mask = BIT(PRS_ETH_VXLAN_NO_L2_ENABLE_OFFSET);
if (enable) {
/* set VXLAN_NO_L2_ENABLE flag */
reg_val |= cfg_mask;
/* update PRS FIC register */
qed_wr(p_hwfn,
p_ptt,
PRS_REG_OUTPUT_FORMAT_4_0_BB_K2,
(u32)PRS_ETH_VXLAN_NO_L2_OUTPUT_FORMAT);
} else {
/* clear VXLAN_NO_L2_ENABLE flag */
reg_val &= ~cfg_mask;
}
/* write PRS config register */
qed_wr(p_hwfn, p_ptt, PRS_REG_MSG_INFO, reg_val);
}
#define T_ETH_PACKET_ACTION_GFT_EVENTID 23
#define PARSER_ETH_CONN_GFT_ACTION_CM_HDR 272
#define T_ETH_PACKET_MATCH_RFS_EVENTID 25
#define PARSER_ETH_CONN_CM_HDR 0
#define CAM_LINE_SIZE sizeof(u32)
#define RAM_LINE_SIZE sizeof(u64)
#define REG_SIZE sizeof(u32)
void qed_gft_disable(struct qed_hwfn *p_hwfn, struct qed_ptt *p_ptt, u16 pf_id)
{
struct regpair ram_line = { };
/* Disable gft search for PF */
qed_wr(p_hwfn, p_ptt, PRS_REG_SEARCH_GFT, 0);
/* Clean ram & cam for next gft session */
/* Zero camline */
qed_wr(p_hwfn, p_ptt, PRS_REG_GFT_CAM + CAM_LINE_SIZE * pf_id, 0);
/* Zero ramline */
qed_dmae_to_grc(p_hwfn, p_ptt, &ram_line.lo,
PRS_REG_GFT_PROFILE_MASK_RAM + RAM_LINE_SIZE * pf_id,
sizeof(ram_line) / REG_SIZE);
}
void qed_gft_config(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
u16 pf_id,
bool tcp,
bool udp,
bool ipv4, bool ipv6, enum gft_profile_type profile_type)
{
struct regpair ram_line;
u32 search_non_ip_as_gft;
u32 reg_val, cam_line;
u32 lo = 0, hi = 0;
if (!ipv6 && !ipv4)
DP_NOTICE(p_hwfn,
"gft_config: must accept at least on of - ipv4 or ipv6'\n");
if (!tcp && !udp)
DP_NOTICE(p_hwfn,
"gft_config: must accept at least on of - udp or tcp\n");
if (profile_type >= MAX_GFT_PROFILE_TYPE)
DP_NOTICE(p_hwfn, "gft_config: unsupported gft_profile_type\n");
/* Set RFS event ID to be awakened i Tstorm By Prs */
reg_val = T_ETH_PACKET_MATCH_RFS_EVENTID <<
PRS_REG_CM_HDR_GFT_EVENT_ID_SHIFT;
reg_val |= PARSER_ETH_CONN_CM_HDR << PRS_REG_CM_HDR_GFT_CM_HDR_SHIFT;
qed_wr(p_hwfn, p_ptt, PRS_REG_CM_HDR_GFT, reg_val);
/* Do not load context only cid in PRS on match. */
qed_wr(p_hwfn, p_ptt, PRS_REG_LOAD_L2_FILTER, 0);
/* Do not use tenant ID exist bit for gft search */
qed_wr(p_hwfn, p_ptt, PRS_REG_SEARCH_TENANT_ID, 0);
/* Set Cam */
cam_line = 0;
SET_FIELD(cam_line, GFT_CAM_LINE_MAPPED_VALID, 1);
/* Filters are per PF!! */
SET_FIELD(cam_line,
GFT_CAM_LINE_MAPPED_PF_ID_MASK,
GFT_CAM_LINE_MAPPED_PF_ID_MASK_MASK);
SET_FIELD(cam_line, GFT_CAM_LINE_MAPPED_PF_ID, pf_id);
if (!(tcp && udp)) {
SET_FIELD(cam_line,
GFT_CAM_LINE_MAPPED_UPPER_PROTOCOL_TYPE_MASK,
GFT_CAM_LINE_MAPPED_UPPER_PROTOCOL_TYPE_MASK_MASK);
if (tcp)
SET_FIELD(cam_line,
GFT_CAM_LINE_MAPPED_UPPER_PROTOCOL_TYPE,
GFT_PROFILE_TCP_PROTOCOL);
else
SET_FIELD(cam_line,
GFT_CAM_LINE_MAPPED_UPPER_PROTOCOL_TYPE,
GFT_PROFILE_UDP_PROTOCOL);
}
if (!(ipv4 && ipv6)) {
SET_FIELD(cam_line, GFT_CAM_LINE_MAPPED_IP_VERSION_MASK, 1);
if (ipv4)
SET_FIELD(cam_line,
GFT_CAM_LINE_MAPPED_IP_VERSION,
GFT_PROFILE_IPV4);
else
SET_FIELD(cam_line,
GFT_CAM_LINE_MAPPED_IP_VERSION,
GFT_PROFILE_IPV6);
}
/* Write characteristics to cam */
qed_wr(p_hwfn, p_ptt, PRS_REG_GFT_CAM + CAM_LINE_SIZE * pf_id,
cam_line);
cam_line =
qed_rd(p_hwfn, p_ptt, PRS_REG_GFT_CAM + CAM_LINE_SIZE * pf_id);
/* Write line to RAM - compare to filter 4 tuple */
/* Search no IP as GFT */
search_non_ip_as_gft = 0;
/* Tunnel type */
SET_FIELD(lo, GFT_RAM_LINE_TUNNEL_DST_PORT, 1);
SET_FIELD(lo, GFT_RAM_LINE_TUNNEL_OVER_IP_PROTOCOL, 1);
if (profile_type == GFT_PROFILE_TYPE_4_TUPLE) {
SET_FIELD(hi, GFT_RAM_LINE_DST_IP, 1);
SET_FIELD(hi, GFT_RAM_LINE_SRC_IP, 1);
SET_FIELD(hi, GFT_RAM_LINE_OVER_IP_PROTOCOL, 1);
SET_FIELD(lo, GFT_RAM_LINE_ETHERTYPE, 1);
SET_FIELD(lo, GFT_RAM_LINE_SRC_PORT, 1);
SET_FIELD(lo, GFT_RAM_LINE_DST_PORT, 1);
} else if (profile_type == GFT_PROFILE_TYPE_L4_DST_PORT) {
SET_FIELD(hi, GFT_RAM_LINE_OVER_IP_PROTOCOL, 1);
SET_FIELD(lo, GFT_RAM_LINE_ETHERTYPE, 1);
SET_FIELD(lo, GFT_RAM_LINE_DST_PORT, 1);
} else if (profile_type == GFT_PROFILE_TYPE_IP_DST_ADDR) {
SET_FIELD(hi, GFT_RAM_LINE_DST_IP, 1);
SET_FIELD(lo, GFT_RAM_LINE_ETHERTYPE, 1);
} else if (profile_type == GFT_PROFILE_TYPE_IP_SRC_ADDR) {
SET_FIELD(hi, GFT_RAM_LINE_SRC_IP, 1);
SET_FIELD(lo, GFT_RAM_LINE_ETHERTYPE, 1);
} else if (profile_type == GFT_PROFILE_TYPE_TUNNEL_TYPE) {
SET_FIELD(lo, GFT_RAM_LINE_TUNNEL_ETHERTYPE, 1);
/* Allow tunneled traffic without inner IP */
search_non_ip_as_gft = 1;
}
ram_line.lo = cpu_to_le32(lo);
ram_line.hi = cpu_to_le32(hi);
qed_wr(p_hwfn,
p_ptt, PRS_REG_SEARCH_NON_IP_AS_GFT, search_non_ip_as_gft);
qed_dmae_to_grc(p_hwfn, p_ptt, &ram_line.lo,
PRS_REG_GFT_PROFILE_MASK_RAM + RAM_LINE_SIZE * pf_id,
sizeof(ram_line) / REG_SIZE);
/* Set default profile so that no filter match will happen */
ram_line.lo = cpu_to_le32(0xffffffff);
ram_line.hi = cpu_to_le32(0x3ff);
qed_dmae_to_grc(p_hwfn, p_ptt, &ram_line.lo,
PRS_REG_GFT_PROFILE_MASK_RAM + RAM_LINE_SIZE *
PRS_GFT_CAM_LINES_NO_MATCH,
sizeof(ram_line) / REG_SIZE);
/* Enable gft search */
qed_wr(p_hwfn, p_ptt, PRS_REG_SEARCH_GFT, 1);
}
DECLARE_CRC8_TABLE(cdu_crc8_table);
/* Calculate and return CDU validation byte per connection type/region/cid */
static u8 qed_calc_cdu_validation_byte(u8 conn_type, u8 region, u32 cid)
{
const u8 validation_cfg = CDU_VALIDATION_DEFAULT_CFG;
u8 crc, validation_byte = 0;
static u8 crc8_table_valid; /* automatically initialized to 0 */
u32 validation_string = 0;
__be32 data_to_crc;
if (!crc8_table_valid) {
crc8_populate_msb(cdu_crc8_table, 0x07);
crc8_table_valid = 1;
}
/* The CRC is calculated on the String-to-compress:
* [31:8] = {CID[31:20],CID[11:0]}
* [7:4] = Region
* [3:0] = Type
*/
if ((validation_cfg >> CDU_CONTEXT_VALIDATION_CFG_USE_CID) & 1)
validation_string |= (cid & 0xFFF00000) | ((cid & 0xFFF) << 8);
if ((validation_cfg >> CDU_CONTEXT_VALIDATION_CFG_USE_REGION) & 1)
validation_string |= ((region & 0xF) << 4);
if ((validation_cfg >> CDU_CONTEXT_VALIDATION_CFG_USE_TYPE) & 1)
validation_string |= (conn_type & 0xF);
/* Convert to big-endian and calculate CRC8 */
data_to_crc = cpu_to_be32(validation_string);
crc = crc8(cdu_crc8_table, (u8 *)&data_to_crc, sizeof(data_to_crc),
CRC8_INIT_VALUE);
/* The validation byte [7:0] is composed:
* for type A validation
* [7] = active configuration bit
* [6:0] = crc[6:0]
*
* for type B validation
* [7] = active configuration bit
* [6:3] = connection_type[3:0]
* [2:0] = crc[2:0]
*/
validation_byte |=
((validation_cfg >>
CDU_CONTEXT_VALIDATION_CFG_USE_ACTIVE) & 1) << 7;
if ((validation_cfg >>
CDU_CONTEXT_VALIDATION_CFG_VALIDATION_TYPE_SHIFT) & 1)
validation_byte |= ((conn_type & 0xF) << 3) | (crc & 0x7);
else
validation_byte |= crc & 0x7F;
return validation_byte;
}
/* Calcualte and set validation bytes for session context */
void qed_calc_session_ctx_validation(void *p_ctx_mem,
u16 ctx_size, u8 ctx_type, u32 cid)
{
u8 *x_val_ptr, *t_val_ptr, *u_val_ptr, *p_ctx;
p_ctx = (u8 * const)p_ctx_mem;
x_val_ptr = &p_ctx[con_region_offsets[0][ctx_type]];
t_val_ptr = &p_ctx[con_region_offsets[1][ctx_type]];
u_val_ptr = &p_ctx[con_region_offsets[2][ctx_type]];
memset(p_ctx, 0, ctx_size);
*x_val_ptr = qed_calc_cdu_validation_byte(ctx_type, 3, cid);
*t_val_ptr = qed_calc_cdu_validation_byte(ctx_type, 4, cid);
*u_val_ptr = qed_calc_cdu_validation_byte(ctx_type, 5, cid);
}
/* Calcualte and set validation bytes for task context */
void qed_calc_task_ctx_validation(void *p_ctx_mem,
u16 ctx_size, u8 ctx_type, u32 tid)
{
u8 *p_ctx, *region1_val_ptr;
p_ctx = (u8 * const)p_ctx_mem;
region1_val_ptr = &p_ctx[task_region_offsets[0][ctx_type]];
memset(p_ctx, 0, ctx_size);
*region1_val_ptr = qed_calc_cdu_validation_byte(ctx_type, 1, tid);
}
/* Memset session context to 0 while preserving validation bytes */
void qed_memset_session_ctx(void *p_ctx_mem, u32 ctx_size, u8 ctx_type)
{
u8 *x_val_ptr, *t_val_ptr, *u_val_ptr, *p_ctx;
u8 x_val, t_val, u_val;
p_ctx = (u8 * const)p_ctx_mem;
x_val_ptr = &p_ctx[con_region_offsets[0][ctx_type]];
t_val_ptr = &p_ctx[con_region_offsets[1][ctx_type]];
u_val_ptr = &p_ctx[con_region_offsets[2][ctx_type]];
x_val = *x_val_ptr;
t_val = *t_val_ptr;
u_val = *u_val_ptr;
memset(p_ctx, 0, ctx_size);
*x_val_ptr = x_val;
*t_val_ptr = t_val;
*u_val_ptr = u_val;
}
/* Memset task context to 0 while preserving validation bytes */
void qed_memset_task_ctx(void *p_ctx_mem, u32 ctx_size, u8 ctx_type)
{
u8 *p_ctx, *region1_val_ptr;
u8 region1_val;
p_ctx = (u8 * const)p_ctx_mem;
region1_val_ptr = &p_ctx[task_region_offsets[0][ctx_type]];
region1_val = *region1_val_ptr;
memset(p_ctx, 0, ctx_size);
*region1_val_ptr = region1_val;
}
/* Enable and configure context validation */
void qed_enable_context_validation(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt)
{
u32 ctx_validation;
/* Enable validation for connection region 3: CCFC_CTX_VALID0[31:24] */
ctx_validation = CDU_VALIDATION_DEFAULT_CFG << 24;
qed_wr(p_hwfn, p_ptt, CDU_REG_CCFC_CTX_VALID0, ctx_validation);
/* Enable validation for connection region 5: CCFC_CTX_VALID1[15:8] */
ctx_validation = CDU_VALIDATION_DEFAULT_CFG << 8;
qed_wr(p_hwfn, p_ptt, CDU_REG_CCFC_CTX_VALID1, ctx_validation);
/* Enable validation for connection region 1: TCFC_CTX_VALID0[15:8] */
ctx_validation = CDU_VALIDATION_DEFAULT_CFG << 8;
qed_wr(p_hwfn, p_ptt, CDU_REG_TCFC_CTX_VALID0, ctx_validation);
}
static u32 qed_get_rdma_assert_ram_addr(struct qed_hwfn *p_hwfn, u8 storm_id)
{
switch (storm_id) {
case 0:
return TSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
TSTORM_RDMA_ASSERT_LEVEL_OFFSET(p_hwfn->rel_pf_id);
case 1:
return MSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
MSTORM_RDMA_ASSERT_LEVEL_OFFSET(p_hwfn->rel_pf_id);
case 2:
return USEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
USTORM_RDMA_ASSERT_LEVEL_OFFSET(p_hwfn->rel_pf_id);
case 3:
return XSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
XSTORM_RDMA_ASSERT_LEVEL_OFFSET(p_hwfn->rel_pf_id);
case 4:
return YSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
YSTORM_RDMA_ASSERT_LEVEL_OFFSET(p_hwfn->rel_pf_id);
case 5:
return PSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
PSTORM_RDMA_ASSERT_LEVEL_OFFSET(p_hwfn->rel_pf_id);
default:
return 0;
}
}
void qed_set_rdma_error_level(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
u8 assert_level[NUM_STORMS])
{
u8 storm_id;
for (storm_id = 0; storm_id < NUM_STORMS; storm_id++) {
u32 ram_addr = qed_get_rdma_assert_ram_addr(p_hwfn, storm_id);
qed_wr(p_hwfn, p_ptt, ram_addr, assert_level[storm_id]);
}
}
#define PHYS_ADDR_DWORDS DIV_ROUND_UP(sizeof(dma_addr_t), 4)
#define OVERLAY_HDR_SIZE_DWORDS (sizeof(struct fw_overlay_buf_hdr) / 4)
static u32 qed_get_overlay_addr_ram_addr(struct qed_hwfn *p_hwfn, u8 storm_id)
{
switch (storm_id) {
case 0:
return TSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
TSTORM_OVERLAY_BUF_ADDR_OFFSET;
case 1:
return MSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
MSTORM_OVERLAY_BUF_ADDR_OFFSET;
case 2:
return USEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
USTORM_OVERLAY_BUF_ADDR_OFFSET;
case 3:
return XSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
XSTORM_OVERLAY_BUF_ADDR_OFFSET;
case 4:
return YSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
YSTORM_OVERLAY_BUF_ADDR_OFFSET;
case 5:
return PSEM_REG_FAST_MEMORY + SEM_FAST_REG_INT_RAM +
PSTORM_OVERLAY_BUF_ADDR_OFFSET;
default:
return 0;
}
}
struct phys_mem_desc *qed_fw_overlay_mem_alloc(struct qed_hwfn *p_hwfn,
const u32 * const
fw_overlay_in_buf,
u32 buf_size_in_bytes)
{
u32 buf_size = buf_size_in_bytes / sizeof(u32), buf_offset = 0;
struct phys_mem_desc *allocated_mem;
if (!buf_size)
return NULL;
allocated_mem = kcalloc(NUM_STORMS, sizeof(struct phys_mem_desc),
GFP_KERNEL);
if (!allocated_mem)
return NULL;
memset(allocated_mem, 0, NUM_STORMS * sizeof(struct phys_mem_desc));
/* For each Storm, set physical address in RAM */
while (buf_offset < buf_size) {
struct phys_mem_desc *storm_mem_desc;
struct fw_overlay_buf_hdr *hdr;
u32 storm_buf_size;
u8 storm_id;
hdr =
(struct fw_overlay_buf_hdr *)&fw_overlay_in_buf[buf_offset];
storm_buf_size = GET_FIELD(hdr->data,
FW_OVERLAY_BUF_HDR_BUF_SIZE);
storm_id = GET_FIELD(hdr->data, FW_OVERLAY_BUF_HDR_STORM_ID);
storm_mem_desc = allocated_mem + storm_id;
storm_mem_desc->size = storm_buf_size * sizeof(u32);
/* Allocate physical memory for Storm's overlays buffer */
storm_mem_desc->virt_addr =
dma_alloc_coherent(&p_hwfn->cdev->pdev->dev,
storm_mem_desc->size,
&storm_mem_desc->phys_addr, GFP_KERNEL);
if (!storm_mem_desc->virt_addr)
break;
/* Skip overlays buffer header */
buf_offset += OVERLAY_HDR_SIZE_DWORDS;
/* Copy Storm's overlays buffer to allocated memory */
memcpy(storm_mem_desc->virt_addr,
&fw_overlay_in_buf[buf_offset], storm_mem_desc->size);
/* Advance to next Storm */
buf_offset += storm_buf_size;
}
/* If memory allocation has failed, free all allocated memory */
if (buf_offset < buf_size) {
qed_fw_overlay_mem_free(p_hwfn, allocated_mem);
return NULL;
}
return allocated_mem;
}
void qed_fw_overlay_init_ram(struct qed_hwfn *p_hwfn,
struct qed_ptt *p_ptt,
struct phys_mem_desc *fw_overlay_mem)
{
u8 storm_id;
for (storm_id = 0; storm_id < NUM_STORMS; storm_id++) {
struct phys_mem_desc *storm_mem_desc =
(struct phys_mem_desc *)fw_overlay_mem + storm_id;
u32 ram_addr, i;
/* Skip Storms with no FW overlays */
if (!storm_mem_desc->virt_addr)
continue;
/* Calculate overlay RAM GRC address of current PF */
ram_addr = qed_get_overlay_addr_ram_addr(p_hwfn, storm_id) +
sizeof(dma_addr_t) * p_hwfn->rel_pf_id;
/* Write Storm's overlay physical address to RAM */
for (i = 0; i < PHYS_ADDR_DWORDS; i++, ram_addr += sizeof(u32))
qed_wr(p_hwfn, p_ptt, ram_addr,
((u32 *)&storm_mem_desc->phys_addr)[i]);
}
}
void qed_fw_overlay_mem_free(struct qed_hwfn *p_hwfn,
struct phys_mem_desc *fw_overlay_mem)
{
u8 storm_id;
if (!fw_overlay_mem)
return;
for (storm_id = 0; storm_id < NUM_STORMS; storm_id++) {
struct phys_mem_desc *storm_mem_desc =
(struct phys_mem_desc *)fw_overlay_mem + storm_id;
/* Free Storm's physical memory */
if (storm_mem_desc->virt_addr)
dma_free_coherent(&p_hwfn->cdev->pdev->dev,
storm_mem_desc->size,
storm_mem_desc->virt_addr,
storm_mem_desc->phys_addr);
}
/* Free allocated virtual memory */
kfree(fw_overlay_mem);
}
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