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gerrit-public.fairphone.software / kernel / msm / edd98336b35d36d8d871d78e16da4fe33b0d4df6 / . / arch / arm / mach-msm / msm_bus / msm_bus_noc.c
blob: 988d7202def87e1cc123fc246260569a6933e420 [file] [log] [blame]
/* Copyright (c) 2012-2014, The Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#define pr_fmt(fmt) "AXI: NOC: %s(): " fmt, __func__
#include <linux/slab.h>
#include <linux/io.h>
#include <mach/msm_bus_board.h>
#include "msm_bus_core.h"
#include "msm_bus_noc.h"
/* NOC_QOS generic */
#define __CLZ(x) ((8 * sizeof(uint32_t)) - 1 - __fls(x))
#define SAT_SCALE 16 /* 16 bytes minimum for saturation */
#define BW_SCALE 256 /* 1/256 byte per cycle unit */
#define QOS_DEFAULT_BASEOFFSET 0x00003000
#define MAX_BW_FIELD (NOC_QOS_BWn_BW_BMSK >> NOC_QOS_BWn_BW_SHFT)
#define MAX_SAT_FIELD (NOC_QOS_SATn_SAT_BMSK >> NOC_QOS_SATn_SAT_SHFT)
#define NOC_QOS_REG_BASE(b, o) ((b) + (o))
#define NOC_QOS_ID_COREIDn_ADDR(b, o, n) \
(NOC_QOS_REG_BASE(b, o) + 0x80 * (n))
enum noc_qos_id_coreidn {
NOC_QOS_ID_COREIDn_RMSK = 0xffffffff,
NOC_QOS_ID_COREIDn_MAXn = 32,
NOC_QOS_ID_COREIDn_CORECHSUM_BMSK = 0xffffff00,
NOC_QOS_ID_COREIDn_CORECHSUM_SHFT = 0x8,
NOC_QOS_ID_COREIDn_CORETYPEID_BMSK = 0xff,
NOC_QOS_ID_COREIDn_CORETYPEID_SHFT = 0x0,
};
#define NOC_QOS_ID_REVISIONIDn_ADDR(b, o, n) \
(NOC_QOS_REG_BASE(b, o) + 0x4 + 0x80 * (n))
enum noc_qos_id_revisionidn {
NOC_QOS_ID_REVISIONIDn_RMSK = 0xffffffff,
NOC_QOS_ID_REVISIONIDn_MAXn = 32,
NOC_QOS_ID_REVISIONIDn_FLEXNOCID_BMSK = 0xffffff00,
NOC_QOS_ID_REVISIONIDn_FLEXNOCID_SHFT = 0x8,
NOC_QOS_ID_REVISIONIDn_USERID_BMSK = 0xff,
NOC_QOS_ID_REVISIONIDn_USERID_SHFT = 0x0,
};
#define NOC_QOS_PRIORITYn_ADDR(b, o, n) \
(NOC_QOS_REG_BASE(b, o) + 0x8 + 0x80 * (n))
enum noc_qos_id_priorityn {
NOC_QOS_PRIORITYn_RMSK = 0x0000000f,
NOC_QOS_PRIORITYn_MAXn = 32,
NOC_QOS_PRIORITYn_P1_BMSK = 0xc,
NOC_QOS_PRIORITYn_P1_SHFT = 0x2,
NOC_QOS_PRIORITYn_P0_BMSK = 0x3,
NOC_QOS_PRIORITYn_P0_SHFT = 0x0,
};
#define NOC_QOS_MODEn_ADDR(b, o, n) \
(NOC_QOS_REG_BASE(b, o) + 0xC + 0x80 * (n))
enum noc_qos_id_moden_rmsk {
NOC_QOS_MODEn_RMSK = 0x00000003,
NOC_QOS_MODEn_MAXn = 32,
NOC_QOS_MODEn_MODE_BMSK = 0x3,
NOC_QOS_MODEn_MODE_SHFT = 0x0,
};
#define NOC_QOS_BWn_ADDR(b, o, n) \
(NOC_QOS_REG_BASE(b, o) + 0x10 + 0x80 * (n))
enum noc_qos_id_bwn {
NOC_QOS_BWn_RMSK = 0x0000ffff,
NOC_QOS_BWn_MAXn = 32,
NOC_QOS_BWn_BW_BMSK = 0xffff,
NOC_QOS_BWn_BW_SHFT = 0x0,
};
/* QOS Saturation registers */
#define NOC_QOS_SATn_ADDR(b, o, n) \
(NOC_QOS_REG_BASE(b, o) + 0x14 + 0x80 * (n))
enum noc_qos_id_saturationn {
NOC_QOS_SATn_RMSK = 0x000003ff,
NOC_QOS_SATn_MAXn = 32,
NOC_QOS_SATn_SAT_BMSK = 0x3ff,
NOC_QOS_SATn_SAT_SHFT = 0x0,
};
static int noc_div(uint64_t *a, uint32_t b)
{
if ((*a > 0) && (*a < b))
return 1;
else
return do_div(*a, b);
}
/**
* Calculates bw hardware is using from register values
* bw returned is in bytes/sec
*/
static uint64_t noc_bw(uint32_t bw_field, uint32_t qos_freq)
{
uint64_t res;
uint32_t rem, scale;
res = 2 * qos_freq * bw_field;
scale = BW_SCALE * 1000;
rem = noc_div(&res, scale);
MSM_BUS_DBG("NOC: Calculated bw: %llu\n", res * 1000000ULL);
return res * 1000000ULL;
}
static uint32_t noc_bw_ceil(long int bw_field, uint32_t qos_freq)
{
uint64_t bw_temp = 2 * qos_freq * bw_field;
uint32_t scale = 1000 * BW_SCALE;
noc_div(&bw_temp, scale);
return bw_temp * 1000000;
}
#define MAX_BW(timebase) noc_bw_ceil(MAX_BW_FIELD, (timebase))
/**
* Calculates ws hardware is using from register values
* ws returned is in nanoseconds
*/
static uint32_t noc_ws(uint64_t bw, uint32_t sat, uint32_t qos_freq)
{
if (bw && qos_freq) {
uint32_t bwf = bw * qos_freq;
uint64_t scale = 1000000000000LL * BW_SCALE *
SAT_SCALE * sat;
noc_div(&scale, bwf);
MSM_BUS_DBG("NOC: Calculated ws: %llu\n", scale);
return scale;
}
return 0;
}
#define MAX_WS(bw, timebase) noc_ws((bw), MAX_SAT_FIELD, (timebase))
/* Calculate bandwidth field value for requested bandwidth */
static uint32_t noc_bw_field(uint64_t bw, uint32_t qos_freq)
{
uint32_t bw_field = 0;
if (bw) {
uint32_t rem;
uint64_t bw_capped = min_t(uint64_t, bw, MAX_BW(qos_freq));
uint64_t bwc = bw_capped * BW_SCALE;
uint64_t qf = 2 * qos_freq * 1000;
rem = noc_div(&bwc, qf);
bw_field = (uint32_t)min_t(uint64_t, bwc, MAX_BW_FIELD);
}
MSM_BUS_DBG("NOC: bw_field: %u\n", bw_field);
return bw_field;
}
static uint32_t noc_sat_field(uint64_t bw, uint32_t ws, uint32_t qos_freq)
{
uint32_t sat_field = 0, win;
if (bw) {
/* Limit to max bw and scale bw to 100 KB increments */
uint64_t tbw, tscale;
uint64_t bw_scaled = min_t(uint64_t, bw, MAX_BW(qos_freq));
uint32_t rem = noc_div(&bw_scaled, 100000);
/**
* Calculate saturation from windows size.
* WS must be at least one arb period.
* Saturation must not exceed max field size
*
* Bandwidth is in 100KB increments
* Window size is in ns
* qos_freq is in KHz
*/
win = max(ws, 1000000 / qos_freq);
tbw = bw_scaled * win * qos_freq;
tscale = 10000000ULL * BW_SCALE * SAT_SCALE;
rem = noc_div(&tbw, tscale);
sat_field = (uint32_t)min_t(uint64_t, tbw, MAX_SAT_FIELD);
}
MSM_BUS_DBG("NOC: sat_field: %d\n", sat_field);
return sat_field;
}
static void noc_set_qos_mode(struct msm_bus_noc_info *ninfo, uint32_t mport,
uint8_t mode, uint8_t perm_mode)
{
if (mode < NOC_QOS_MODE_MAX &&
((1 << mode) & perm_mode)) {
uint32_t reg_val;
reg_val = readl_relaxed(NOC_QOS_MODEn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport)) & NOC_QOS_MODEn_RMSK;
writel_relaxed(((reg_val & (~(NOC_QOS_MODEn_MODE_BMSK))) |
(mode & NOC_QOS_MODEn_MODE_BMSK)),
NOC_QOS_MODEn_ADDR(ninfo->base, ninfo->qos_baseoffset,
mport));
}
/* Ensure qos mode is set before exiting */
wmb();
}
static void noc_set_qos_priority(struct msm_bus_noc_info *ninfo, uint32_t mport,
struct msm_bus_noc_qos_priority *priority)
{
uint32_t reg_val, val;
reg_val = readl_relaxed(NOC_QOS_PRIORITYn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport))
& NOC_QOS_PRIORITYn_RMSK;
val = priority->p1 << NOC_QOS_PRIORITYn_P1_SHFT;
writel_relaxed(((reg_val & (~(NOC_QOS_PRIORITYn_P1_BMSK))) |
(val & NOC_QOS_PRIORITYn_P1_BMSK)),
NOC_QOS_PRIORITYn_ADDR(ninfo->base, ninfo->qos_baseoffset,
mport));
reg_val = readl_relaxed(NOC_QOS_PRIORITYn_ADDR(ninfo->base,
ninfo->qos_baseoffset,
mport))
& NOC_QOS_PRIORITYn_RMSK;
writel_relaxed(((reg_val & (~(NOC_QOS_PRIORITYn_P0_BMSK))) |
(priority->p0 & NOC_QOS_PRIORITYn_P0_BMSK)),
NOC_QOS_PRIORITYn_ADDR(ninfo->base, ninfo->qos_baseoffset,
mport));
/* Ensure qos priority is set before exiting */
wmb();
}
static void msm_bus_noc_set_qos_bw(struct msm_bus_noc_info *ninfo,
uint32_t mport, uint8_t perm_mode, struct msm_bus_noc_qos_bw *qbw)
{
uint32_t reg_val, val, mode;
if (!ninfo->qos_freq) {
MSM_BUS_DBG("Zero QoS Freq\n");
return;
}
/* If Limiter or Regulator modes are not supported, bw not available*/
if (perm_mode & (NOC_QOS_PERM_MODE_LIMITER |
NOC_QOS_PERM_MODE_REGULATOR)) {
uint32_t bw_val = noc_bw_field(qbw->bw, ninfo->qos_freq);
uint32_t sat_val = noc_sat_field(qbw->bw, qbw->ws,
ninfo->qos_freq);
MSM_BUS_DBG("NOC: BW: perm_mode: %d bw_val: %d, sat_val: %d\n",
perm_mode, bw_val, sat_val);
/*
* If in Limiter/Regulator mode, first go to fixed mode.
* Clear QoS accumulator
**/
mode = readl_relaxed(NOC_QOS_MODEn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport))
& NOC_QOS_MODEn_MODE_BMSK;
if (mode == NOC_QOS_MODE_REGULATOR || mode ==
NOC_QOS_MODE_LIMITER) {
reg_val = readl_relaxed(NOC_QOS_MODEn_ADDR(ninfo->
base, ninfo->qos_baseoffset, mport));
val = NOC_QOS_MODE_FIXED;
writel_relaxed((reg_val & (~(NOC_QOS_MODEn_MODE_BMSK)))
| (val & NOC_QOS_MODEn_MODE_BMSK),
NOC_QOS_MODEn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport));
}
reg_val = readl_relaxed(NOC_QOS_BWn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport));
val = bw_val << NOC_QOS_BWn_BW_SHFT;
writel_relaxed(((reg_val & (~(NOC_QOS_BWn_BW_BMSK))) |
(val & NOC_QOS_BWn_BW_BMSK)),
NOC_QOS_BWn_ADDR(ninfo->base, ninfo->qos_baseoffset,
mport));
MSM_BUS_DBG("NOC: BW: Wrote value: 0x%x\n", ((reg_val &
(~NOC_QOS_BWn_BW_BMSK)) | (val &
NOC_QOS_BWn_BW_BMSK)));
reg_val = readl_relaxed(NOC_QOS_SATn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport));
val = sat_val << NOC_QOS_SATn_SAT_SHFT;
writel_relaxed(((reg_val & (~(NOC_QOS_SATn_SAT_BMSK))) |
(val & NOC_QOS_SATn_SAT_BMSK)),
NOC_QOS_SATn_ADDR(ninfo->base, ninfo->qos_baseoffset,
mport));
MSM_BUS_DBG("NOC: SAT: Wrote value: 0x%x\n", ((reg_val &
(~NOC_QOS_SATn_SAT_BMSK)) | (val &
NOC_QOS_SATn_SAT_BMSK)));
/* Set mode back to what it was initially */
reg_val = readl_relaxed(NOC_QOS_MODEn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport));
writel_relaxed((reg_val & (~(NOC_QOS_MODEn_MODE_BMSK)))
| (mode & NOC_QOS_MODEn_MODE_BMSK),
NOC_QOS_MODEn_ADDR(ninfo->base, ninfo->qos_baseoffset,
mport));
/* Ensure that all writes for bandwidth registers have
* completed before returning
*/
wmb();
}
}
uint8_t msm_bus_noc_get_qos_mode(struct msm_bus_noc_info *ninfo,
uint32_t mport, uint32_t mode, uint32_t perm_mode)
{
if (NOC_QOS_MODES_ALL_PERM == perm_mode)
return readl_relaxed(NOC_QOS_MODEn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport)) &
NOC_QOS_MODEn_MODE_BMSK;
else
return 31 - __CLZ(mode &
NOC_QOS_MODES_ALL_PERM);
}
void msm_bus_noc_get_qos_priority(struct msm_bus_noc_info *ninfo,
uint32_t mport, struct msm_bus_noc_qos_priority *priority)
{
priority->p1 = (readl_relaxed(NOC_QOS_PRIORITYn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport)) & NOC_QOS_PRIORITYn_P1_BMSK) >>
NOC_QOS_PRIORITYn_P1_SHFT;
priority->p0 = (readl_relaxed(NOC_QOS_PRIORITYn_ADDR(ninfo->base,
ninfo->qos_baseoffset, mport)) & NOC_QOS_PRIORITYn_P0_BMSK) >>
NOC_QOS_PRIORITYn_P0_SHFT;
}
void msm_bus_noc_get_qos_bw(struct msm_bus_noc_info *ninfo,
uint32_t mport, uint8_t perm_mode, struct msm_bus_noc_qos_bw *qbw)
{
if (perm_mode & (NOC_QOS_PERM_MODE_LIMITER |
NOC_QOS_PERM_MODE_REGULATOR)) {
uint32_t bw_val = readl_relaxed(NOC_QOS_BWn_ADDR(ninfo->
base, ninfo->qos_baseoffset, mport)) &
NOC_QOS_BWn_BW_BMSK;
uint32_t sat = readl_relaxed(NOC_QOS_SATn_ADDR(ninfo->
base, ninfo->qos_baseoffset, mport)) &
NOC_QOS_SATn_SAT_BMSK;
qbw->bw = noc_bw(bw_val, ninfo->qos_freq);
qbw->ws = noc_ws(qbw->bw, sat, ninfo->qos_freq);
} else {
qbw->bw = 0;
qbw->ws = 0;
}
}
static int msm_bus_noc_mas_init(struct msm_bus_noc_info *ninfo,
struct msm_bus_inode_info *info)
{
int i;
struct msm_bus_noc_qos_priority *prio;
prio = kzalloc(sizeof(struct msm_bus_noc_qos_priority),
GFP_KERNEL);
if (!prio) {
MSM_BUS_WARN("Couldn't alloc prio data for node: %d\n",
info->node_info->id);
return -ENOMEM;
}
prio->read_prio = info->node_info->prio_rd;
prio->write_prio = info->node_info->prio_wr;
prio->p1 = info->node_info->prio1;
prio->p0 = info->node_info->prio0;
info->hw_data = (void *)prio;
if (!info->node_info->qport) {
MSM_BUS_DBG("No QoS Ports to init\n");
return 0;
}
for (i = 0; i < info->node_info->num_mports; i++) {
if (info->node_info->mode != NOC_QOS_MODE_BYPASS) {
noc_set_qos_priority(ninfo, info->node_info->qport[i],
prio);
if (info->node_info->mode != NOC_QOS_MODE_FIXED) {
struct msm_bus_noc_qos_bw qbw;
qbw.ws = info->node_info->ws;
qbw.bw = 0;
msm_bus_noc_set_qos_bw(ninfo, info->node_info->
qport[i], info->node_info->perm_mode,
&qbw);
}
}
noc_set_qos_mode(ninfo, info->node_info->qport[i], info->
node_info->mode, info->node_info->perm_mode);
}
return 0;
}
static void msm_bus_noc_node_init(void *hw_data,
struct msm_bus_inode_info *info)
{
struct msm_bus_noc_info *ninfo =
(struct msm_bus_noc_info *)hw_data;
if (!IS_SLAVE(info->node_info->priv_id))
if (info->node_info->hw_sel != MSM_BUS_RPM)
msm_bus_noc_mas_init(ninfo, info);
}
static int msm_bus_noc_allocate_commit_data(struct msm_bus_fabric_registration
*fab_pdata, void **cdata, int ctx)
{
struct msm_bus_noc_commit **cd = (struct msm_bus_noc_commit **)cdata;
struct msm_bus_noc_info *ninfo =
(struct msm_bus_noc_info *)fab_pdata->hw_data;
*cd = kzalloc(sizeof(struct msm_bus_noc_commit), GFP_KERNEL);
if (!*cd) {
MSM_BUS_DBG("Couldn't alloc mem for cdata\n");
return -ENOMEM;
}
(*cd)->mas = ninfo->cdata[ctx].mas;
(*cd)->slv = ninfo->cdata[ctx].slv;
return 0;
}
static void *msm_bus_noc_allocate_noc_data(struct platform_device *pdev,
struct msm_bus_fabric_registration *fab_pdata)
{
struct resource *noc_mem;
struct resource *noc_io;
struct msm_bus_noc_info *ninfo;
int i;
ninfo = kzalloc(sizeof(struct msm_bus_noc_info), GFP_KERNEL);
if (!ninfo) {
MSM_BUS_DBG("Couldn't alloc mem for noc info\n");
return NULL;
}
ninfo->nmasters = fab_pdata->nmasters;
ninfo->nqos_masters = fab_pdata->nmasters;
ninfo->nslaves = fab_pdata->nslaves;
ninfo->qos_freq = fab_pdata->qos_freq;
if (!fab_pdata->qos_baseoffset)
ninfo->qos_baseoffset = QOS_DEFAULT_BASEOFFSET;
else
ninfo->qos_baseoffset = fab_pdata->qos_baseoffset;
ninfo->mas_modes = kzalloc(sizeof(uint32_t) * fab_pdata->nmasters,
GFP_KERNEL);
if (!ninfo->mas_modes) {
MSM_BUS_DBG("Couldn't alloc mem for noc master-modes\n");
return NULL;
}
for (i = 0; i < NUM_CTX; i++) {
ninfo->cdata[i].mas = kzalloc(sizeof(struct
msm_bus_node_hw_info) * fab_pdata->nmasters * 2,
GFP_KERNEL);
if (!ninfo->cdata[i].mas) {
MSM_BUS_DBG("Couldn't alloc mem for noc master-bw\n");
kfree(ninfo->mas_modes);
kfree(ninfo);
return NULL;
}
ninfo->cdata[i].slv = kzalloc(sizeof(struct
msm_bus_node_hw_info) * fab_pdata->nslaves * 2,
GFP_KERNEL);
if (!ninfo->cdata[i].slv) {
MSM_BUS_DBG("Couldn't alloc mem for noc master-bw\n");
kfree(ninfo->cdata[i].mas);
goto err;
}
}
/* If it's a virtual fabric, don't get memory info */
if (fab_pdata->virt)
goto skip_mem;
noc_mem = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!noc_mem && !fab_pdata->virt) {
MSM_BUS_ERR("Cannot get NoC Base address\n");
goto err;
}
noc_io = request_mem_region(noc_mem->start,
resource_size(noc_mem), pdev->name);
if (!noc_io) {
MSM_BUS_ERR("NoC memory unavailable\n");
goto err;
}
ninfo->base = ioremap(noc_mem->start, resource_size(noc_mem));
if (!ninfo->base) {
MSM_BUS_ERR("IOremap failed for NoC!\n");
release_mem_region(noc_mem->start, resource_size(noc_mem));
goto err;
}
skip_mem:
fab_pdata->hw_data = (void *)ninfo;
return (void *)ninfo;
err:
kfree(ninfo->mas_modes);
kfree(ninfo);
return NULL;
}
static void free_commit_data(void *cdata)
{
struct msm_bus_noc_commit *cd = (struct msm_bus_noc_commit *)cdata;
kfree(cd->mas);
kfree(cd->slv);
kfree(cd);
}
static void msm_bus_noc_update_bw(struct msm_bus_inode_info *hop,
struct msm_bus_inode_info *info,
struct msm_bus_fabric_registration *fab_pdata,
void *sel_cdata, int *master_tiers,
int64_t add_bw)
{
struct msm_bus_noc_info *ninfo;
struct msm_bus_noc_qos_bw qos_bw;
int i, ports;
int64_t bw;
struct msm_bus_noc_commit *sel_cd =
(struct msm_bus_noc_commit *)sel_cdata;
ninfo = (struct msm_bus_noc_info *)fab_pdata->hw_data;
if (!ninfo->qos_freq) {
MSM_BUS_DBG("NOC: No qos frequency to update bw\n");
return;
}
if (info->node_info->num_mports == 0) {
MSM_BUS_DBG("NOC: Skip Master BW\n");
goto skip_mas_bw;
}
ports = info->node_info->num_mports;
bw = INTERLEAVED_BW(fab_pdata, add_bw, ports);
MSM_BUS_DBG("NOC: Update bw for: %d: %lld\n",
info->node_info->priv_id, add_bw);
for (i = 0; i < ports; i++) {
sel_cd->mas[info->node_info->masterp[i]].bw += bw;
sel_cd->mas[info->node_info->masterp[i]].hw_id =
info->node_info->mas_hw_id;
MSM_BUS_DBG("NOC: Update mas_bw: ID: %d, BW: %llu ports:%d\n",
info->node_info->priv_id,
sel_cd->mas[info->node_info->masterp[i]].bw,
ports);
/* Check if info is a shared master.
* If it is, mark it dirty
* If it isn't, then set QOS Bandwidth
**/
if (info->node_info->hw_sel == MSM_BUS_RPM)
sel_cd->mas[info->node_info->masterp[i]].dirty = 1;
else {
if (!info->node_info->qport) {
MSM_BUS_DBG("No qos ports to update!\n");
break;
}
qos_bw.bw = sel_cd->mas[info->node_info->masterp[i]].
bw;
qos_bw.ws = info->node_info->ws;
msm_bus_noc_set_qos_bw(ninfo,
info->node_info->qport[i],
info->node_info->perm_mode, &qos_bw);
MSM_BUS_DBG("NOC: QoS: Update mas_bw: ws: %u\n",
qos_bw.ws);
}
}
skip_mas_bw:
ports = hop->node_info->num_sports;
for (i = 0; i < ports; i++) {
sel_cd->slv[hop->node_info->slavep[i]].bw += add_bw;
sel_cd->slv[hop->node_info->slavep[i]].hw_id =
hop->node_info->slv_hw_id;
MSM_BUS_DBG("NOC: Update slave_bw for ID: %d -> %llu\n",
hop->node_info->priv_id,
sel_cd->slv[hop->node_info->slavep[i]].bw);
MSM_BUS_DBG("NOC: Update slave_bw for hw_id: %d, index: %d\n",
hop->node_info->slv_hw_id, hop->node_info->slavep[i]);
/* Check if hop is a shared slave.
* If it is, mark it dirty
* If it isn't, then nothing to be done as the
* slaves are in bypass mode.
**/
if (hop->node_info->hw_sel == MSM_BUS_RPM)
sel_cd->slv[hop->node_info->slavep[i]].dirty = 1;
}
}
static int msm_bus_noc_commit(struct msm_bus_fabric_registration
*fab_pdata, void *hw_data, void **cdata)
{
MSM_BUS_DBG("\nReached NOC Commit\n");
msm_bus_remote_hw_commit(fab_pdata, hw_data, cdata);
return 0;
}
static int msm_bus_noc_port_halt(uint32_t haltid, uint8_t mport)
{
return 0;
}
static int msm_bus_noc_port_unhalt(uint32_t haltid, uint8_t mport)
{
return 0;
}
int msm_bus_noc_hw_init(struct msm_bus_fabric_registration *pdata,
struct msm_bus_hw_algorithm *hw_algo)
{
/* Set interleaving to true by default */
pdata->il_flag = true;
hw_algo->allocate_commit_data = msm_bus_noc_allocate_commit_data;
hw_algo->allocate_hw_data = msm_bus_noc_allocate_noc_data;
hw_algo->node_init = msm_bus_noc_node_init;
hw_algo->free_commit_data = free_commit_data;
hw_algo->update_bw = msm_bus_noc_update_bw;
hw_algo->commit = msm_bus_noc_commit;
hw_algo->port_halt = msm_bus_noc_port_halt;
hw_algo->port_unhalt = msm_bus_noc_port_unhalt;
hw_algo->config_master = NULL;
return 0;
}