kernel_samsung_a34x-permissive/drivers/devfreq/helio-dvfsrc-v3/helio-dvfsrc-mt6853.c
2024-04-28 15:49:01 +02:00

807 lines
19 KiB
C
Executable file

/* SPDX-License-Identifier: GPL-2.0 */
/*
* Copyright (c) 2019 MediaTek Inc.
*/
#include <linux/fb.h>
#include <linux/platform_device.h>
#ifdef CONFIG_MEDIATEK_DRAMC
#include <dramc.h>
#endif
#ifdef CONFIG_MTK_EMI
#include <mt_emi_api.h>
#endif
#include <mt-plat/upmu_common.h>
#include "helio-dvfsrc-ip-v2.h"
#include <helio-dvfsrc-opp.h>
#include <helio-dvfsrc-mt6853.h>
#include <mt-plat/mtk_devinfo.h>
#include <linux/regulator/consumer.h>
#include "mmdvfs_pmqos.h"
#include <linux/sysfs.h>
#include <linux/of.h>
#include <linux/platform_device.h>
#include <linux/sched/clock.h>
#include <dbgtop.h>
#define DVFSRC_FB_MD_TABLE_SWITCH
/* #define AUTOK_ENABLE */
#define dvfsrc_rmw(offset, val, mask, shift) \
dvfsrc_write(offset, (dvfsrc_read(offset) & ~(mask << shift)) \
| (val << shift))
static struct reg_config dvfsrc_init_configs[][128] = {
{
{ DVFSRC_HRT_REQ_UNIT, 0x0000001E },
{ DVFSRC_DEBOUNCE_TIME, 0x00001965 },
{ DVFSRC_TIMEOUT_NEXTREQ, 0x00000015 },
{ DVFSRC_LEVEL_MASK, 0x000EE000 },
{ DVFSRC_DDR_QOS0, 0x00000019 },
{ DVFSRC_DDR_QOS1, 0x00000026 },
{ DVFSRC_DDR_QOS2, 0x00000033 },
{ DVFSRC_DDR_QOS3, 0x0000003B },
{ DVFSRC_DDR_QOS4, 0x0000004C },
{ DVFSRC_DDR_QOS5, 0x00000066 },
{ DVFSRC_DDR_QOS6, 0x00000066 },
{ DVFSRC_LEVEL_LABEL_0_1, 0x50436053 },
{ DVFSRC_LEVEL_LABEL_2_3, 0x40335042 },
{ DVFSRC_LEVEL_LABEL_4_5, 0x40314032 },
{ DVFSRC_LEVEL_LABEL_6_7, 0x30223023 },
{ DVFSRC_LEVEL_LABEL_8_9, 0x20133021 },
{ DVFSRC_LEVEL_LABEL_10_11, 0x20112012 },
{ DVFSRC_LEVEL_LABEL_12_13, 0x10032010 },
{ DVFSRC_LEVEL_LABEL_14_15, 0x10011002 },
{ DVFSRC_LEVEL_LABEL_16_17, 0x00131000 },
{ DVFSRC_LEVEL_LABEL_18_19, 0x00110012},
{ DVFSRC_LEVEL_LABEL_20_21, 0x00000010 },
{ DVFSRC_MD_LATENCY_IMPROVE, 0x00000040 },
{ DVFSRC_HRT_BW_BASE, 0x00000004 },
{ DVSFRC_HRT_REQ_MD_URG, 0x000D20D2 },
{ DVFSRC_HRT_REQ_MD_BW_0, 0x00200802 },
{ DVFSRC_HRT_REQ_MD_BW_1, 0x00200802 },
{ DVFSRC_HRT_REQ_MD_BW_2, 0x00200800 },
{ DVFSRC_HRT_REQ_MD_BW_3, 0x00400802 },
{ DVFSRC_HRT_REQ_MD_BW_4, 0x00601404 },
{ DVFSRC_HRT_REQ_MD_BW_5, 0x00D02C09 },
{ DVFSRC_HRT_REQ_MD_BW_6, 0x00000012 },
{ DVFSRC_HRT_REQ_MD_BW_7, 0x00000024 },
{ DVFSRC_HRT_REQ_MD_BW_8, 0x00000000 },
{ DVFSRC_HRT_REQ_MD_BW_9, 0x00000000 },
{ DVFSRC_HRT_REQ_MD_BW_10, 0x00034800 },
{ DVFSRC_HRT1_REQ_MD_BW_0, 0x04B12C4B },
{ DVFSRC_HRT1_REQ_MD_BW_1, 0x04B12C4B },
{ DVFSRC_HRT1_REQ_MD_BW_2, 0x04B12C00 },
{ DVFSRC_HRT1_REQ_MD_BW_3, 0x04B12C4B },
{ DVFSRC_HRT1_REQ_MD_BW_4, 0x04B12C4B },
{ DVFSRC_HRT1_REQ_MD_BW_5, 0x04B12C4B },
{ DVFSRC_HRT1_REQ_MD_BW_6, 0x0000004B },
{ DVFSRC_HRT1_REQ_MD_BW_7, 0x0000005C },
{ DVFSRC_HRT1_REQ_MD_BW_8, 0x00000000 },
{ DVFSRC_HRT1_REQ_MD_BW_9, 0x00000000 },
{ DVFSRC_HRT1_REQ_MD_BW_10, 0x00034800 },
#ifdef DVFSRC_FB_MD_TABLE_SWITCH
{ DVFSRC_95MD_SCEN_BW0_T, 0x40444440 },
{ DVFSRC_95MD_SCEN_BW1_T, 0x22244444 },
{ DVFSRC_95MD_SCEN_BW2_T, 0x00400444 },
{ DVFSRC_95MD_SCEN_BW3_T, 0x60000000 },
{ DVFSRC_95MD_SCEN_BW0, 0x20222220 },
{ DVFSRC_95MD_SCEN_BW1, 0x00022222},
{ DVFSRC_95MD_SCEN_BW2, 0x00200222 },
{ DVFSRC_95MD_SCEN_BW3, 0x60000000 },
{ DVFSRC_95MD_SCEN_BW4, 0x00000006 },
{ DVFSRC_RSRV_5, 0x00000001 },
#else
{ DVFSRC_95MD_SCEN_BW0_T, 0x40444440 },
{ DVFSRC_95MD_SCEN_BW1_T, 0x22244444},
{ DVFSRC_95MD_SCEN_BW2_T, 0x00400444 },
{ DVFSRC_95MD_SCEN_BW3_T, 0x60000000 },
{ DVFSRC_95MD_SCEN_BW0, 0x20222220 },
{ DVFSRC_95MD_SCEN_BW1, 0x00022222 },
{ DVFSRC_95MD_SCEN_BW2, 0x00200222 },
{ DVFSRC_95MD_SCEN_BW3, 0x60000000 },
{ DVFSRC_95MD_SCEN_BW4, 0x00000006 },
{ DVFSRC_RSRV_5, 0x00000001 },
#endif
{ DVFSRC_DDR_REQUEST, 0x00004321 },
{ DVFSRC_DDR_REQUEST3, 0x00000065 },
{ DVFSRC_DDR_ADD_REQUEST, 0x66543210 },
{ DVFSRC_HRT_REQUEST, 0x66654321 },
{ DVFSRC_DDR_REQUEST5, 0x54321000 },
{ DVFSRC_DDR_REQUEST7, 0x66000000 },
{ DVFSRC_EMI_MON_DEBOUNCE_TIME, 0x4C2D0000 },
{ DVFSRC_DDR_REQUEST6, 0x66543210 },
{ DVFSRC_VCORE_USER_REQ, 0x00010A29 },
{ DVFSRC_HRT_HIGH_3, 0x18A618A6 },
{ DVFSRC_HRT_HIGH_2, 0x18A61183 },
{ DVFSRC_HRT_HIGH_1, 0x0D690B80 },
{ DVFSRC_HRT_HIGH, 0x070804B0 },
{ DVFSRC_HRT_LOW_3, 0x18A518A5 },
{ DVFSRC_HRT_LOW_2, 0x18A51182 },
{ DVFSRC_HRT_LOW_1, 0x0D680B7F},
{ DVFSRC_HRT_LOW, 0x070704AF },
{ DVFSRC_BASIC_CONTROL_3, 0x00000006 },
{ DVFSRC_INT_EN, 0x00000002 },
{ DVFSRC_QOS_EN, 0x0000407C },
{ DVFSRC_CURRENT_FORCE, 0x00000001 },
{ DVFSRC_BASIC_CONTROL, 0x6698444B },
{ DVFSRC_BASIC_CONTROL, 0x6698054B },
{ DVFSRC_CURRENT_FORCE, 0x00000000 },
{ -1, 0 },
},
/* NULL */
{
{ -1, 0 },
},
};
static ssize_t dvfsrc_level_mask_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
return sprintf(buf, "%x\n", helio_dvfsrc_level_mask_get());
}
static ssize_t dvfsrc_level_mask_store(struct device *dev,
struct device_attribute *attr, const char *buf, size_t count)
{
int level = 0, en = 0;
if (sscanf(buf, "%d %d", &level, &en) != 2)
return -EINVAL;
helio_dvfsrc_level_mask_set(en, level);
return count;
}
static DEVICE_ATTR(dvfsrc_level_mask, 0644,
dvfsrc_level_mask_show, dvfsrc_level_mask_store);
static ssize_t dvfsrc_vcore_settle_time_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
/* DE's comment: settle time was hard code in fw (15,30) */
return sprintf(buf, "rising 15 uS, falling 30 uS for mt6853\n");
}
static DEVICE_ATTR(dvfsrc_vcore_settle_time, 0444,
dvfsrc_vcore_settle_time_show, NULL);
static ssize_t dvfsrc_md_imp_gear_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
return sprintf(buf, "%x\n", dvfsrc_read(DVFSRC_MD_LATENCY_IMPROVE));
}
static ssize_t dvfsrc_md_imp_gear_store(struct device *dev,
struct device_attribute *attr, const char *buf, size_t count)
{
int gear = 0;
if (kstrtoint(buf, 10, &gear))
return -EINVAL;
if (gear >= DDR_OPP_NUM || gear < 0)
return -EINVAL;
dvfsrc_rmw(DVFSRC_MD_LATENCY_IMPROVE, gear, 0x7, 4);
return count;
}
static DEVICE_ATTR(dvfsrc_md_imp_gear, 0644,
dvfsrc_md_imp_gear_show, dvfsrc_md_imp_gear_store);
static ssize_t dvfsrc_md_qos_performance_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
int len = 0;
len += snprintf(buf + len, PAGE_SIZE - 1 - len,
"%-12s: 0x%08x\n",
"RSRV_5",
dvfsrc_read(DVFSRC_RSRV_5));
len += snprintf(buf + len, PAGE_SIZE - 1 - len,
"%-12s: 0x%08x\n",
"DVFSRC_MD_TURBO",
dvfsrc_read(DVFSRC_MD_TURBO));
len += snprintf(buf + len, PAGE_SIZE - 1 - len,
"%-12s: 0x%08x\n",
"SCEN_URGENT",
dvfsrc_read(DVFSRC_95MD_SCEN_BW4));
len += snprintf(buf + len, PAGE_SIZE - 1 - len,
"%-12s: 0x%08x, %08x, %08x, %08x\n",
"SCEN_BW_T",
dvfsrc_read(DVFSRC_95MD_SCEN_BW0_T),
dvfsrc_read(DVFSRC_95MD_SCEN_BW1_T),
dvfsrc_read(DVFSRC_95MD_SCEN_BW2_T),
dvfsrc_read(DVFSRC_95MD_SCEN_BW3_T));
len += snprintf(buf + len, PAGE_SIZE - 1 - len,
"%-12s: 0x%08x, %08x, %08x, %08x\n",
"SCEN_BW",
dvfsrc_read(DVFSRC_95MD_SCEN_BW0),
dvfsrc_read(DVFSRC_95MD_SCEN_BW1),
dvfsrc_read(DVFSRC_95MD_SCEN_BW2),
dvfsrc_read(DVFSRC_95MD_SCEN_BW3));
return len;
}
static DEVICE_ATTR(dvfsrc_md_qos_performance, 0444,
dvfsrc_md_qos_performance_show, NULL);
static struct attribute *mt6853_helio_dvfsrc_attrs[] = {
&dev_attr_dvfsrc_level_mask.attr,
&dev_attr_dvfsrc_vcore_settle_time.attr,
&dev_attr_dvfsrc_md_imp_gear.attr,
&dev_attr_dvfsrc_md_qos_performance.attr,
NULL,
};
static struct attribute_group mt6853_helio_dvfsrc_attr_group = {
.name = "helio-dvfsrc",
.attrs = mt6853_helio_dvfsrc_attrs,
};
#define dvfsrc_rmw(offset, val, mask, shift) \
dvfsrc_write(offset, (dvfsrc_read(offset) & ~(mask << shift)) \
| (val << shift))
u32 dvfsrc_get_ddr_qos(void)
{
unsigned int qos_total_bw = dvfsrc_read(DVFSRC_SW_BW_0) +
dvfsrc_read(DVFSRC_SW_BW_1) +
dvfsrc_read(DVFSRC_SW_BW_2) +
dvfsrc_read(DVFSRC_SW_BW_3) +
dvfsrc_read(DVFSRC_SW_BW_4);
if (qos_total_bw < 0x19)
return 0;
else if (qos_total_bw < 0x26)
return 1;
else if (qos_total_bw < 0x33)
return 2;
else if (qos_total_bw < 0x3B)
return 3;
else if (qos_total_bw < 0x4C)
return 4;
else if (qos_total_bw < 0x66)
return 5;
else
return 6;
return 0;
}
static int dvfsrc_get_emi_mon_gear(void)
{
unsigned int total_bw_status;
int i;
total_bw_status = vcorefs_get_total_emi_status() & 0x3F;
for (i = 5; i >= 0 ; i--) {
if ((total_bw_status >> i) > 0)
return i + 1;
}
return 0;
}
static u32 dvfsrc_calc_hrt_opp(int data)
{
if (data < 0x04B0)
return DDR_OPP_6;
else if (data < 0x0708)
return DDR_OPP_5;
else if (data < 0x0B80)
return DDR_OPP_4;
else if (data < 0x0D69)
return DDR_OPP_3;
else if (data < 0x1183)
return DDR_OPP_2;
else if (data < 0x18A6)
return DDR_OPP_1;
else
return DDR_OPP_0;
}
void dvfsrc_set_isp_hrt_bw(int data)
{
data = (data + 29) / 30;
if (data > 0x3FF)
data = 0x3FF;
dvfsrc_write(DVFSRC_ISP_HRT, data);
}
u32 dvfsrc_calc_isp_hrt_opp(int data)
{
return dvfsrc_calc_hrt_opp(((data + 29) / 30) * 30);
}
u32 dvfsrc_get_pcie_vcore_status(void)
{
u32 val, pcie_en;
val = dvfsrc_read(DVFSRC_DEBUG_STA_2);
pcie_en = (val >> DEBUG_STA2_PCIE_SHIFT) & DEBUG_STA2_PCIE_MASK;
if (pcie_en)
return 1;
else
return 0;
}
struct regulator *dvfsrc_vcore_requlator(struct device *dev)
{
return regulator_get(dev, "vcore");
}
#ifdef AUTOK_ENABLE
__weak int emmc_autok(void)
{
pr_info("NOT SUPPORT EMMC AUTOK\n");
return 0;
}
__weak int sd_autok(void)
{
pr_info("NOT SUPPORT SD AUTOK\n");
return 0;
}
__weak int sdio_autok(void)
{
pr_info("NOT SUPPORT SDIO AUTOK\n");
return 0;
}
void begin_autok_task(void)
{
/* notify MM DVFS for msdc autok start */
mmdvfs_prepare_action(MMDVFS_PREPARE_CALIBRATION_START);
}
void finish_autok_task(void)
{
/* check if dvfs force is released */
int force = mtk_pm_qos_request(MTK_PM_QOS_VCORE_DVFS_FORCE_OPP);
/* notify MM DVFS for msdc autok finish */
mmdvfs_prepare_action(MMDVFS_PREPARE_CALIBRATION_END);
if (force >= 0 && force < VCORE_DVFS_OPP_NUM)
pr_info("autok task not release force opp: %d\n", force);
}
static void dvfsrc_autok_manager(void)
{
int r = 0;
begin_autok_task();
r = emmc_autok();
pr_info("EMMC autok done: %s\n", (r == 0) ? "Yes" : "No");
r = sd_autok();
pr_info("SD autok done: %s\n", (r == 0) ? "Yes" : "No");
r = sdio_autok();
pr_info("SDIO autok done: %s\n", (r == 0) ? "Yes" : "No");
finish_autok_task();
}
#endif
static void dvfsrc_update_md_scenario(bool blank)
{
#ifdef DVFSRC_FB_MD_TABLE_SWITCH
if (blank)
dvfsrc_write(DVFSRC_95MD_SCEN_BW1_T, 0x22244444);
else
dvfsrc_write(DVFSRC_95MD_SCEN_BW1_T, 0x22244444);
#endif
}
static int dvfsrc_fb_notifier_call(struct notifier_block *self,
unsigned long event, void *data)
{
struct fb_event *evdata = data;
int blank;
if (event != FB_EVENT_BLANK)
return 0;
blank = *(int *)evdata->data;
switch (blank) {
case FB_BLANK_UNBLANK:
dvfsrc_update_md_scenario(false);
break;
case FB_BLANK_POWERDOWN:
dvfsrc_update_md_scenario(true);
break;
default:
break;
}
return 0;
}
static struct notifier_block dvfsrc_fb_notifier = {
.notifier_call = dvfsrc_fb_notifier_call,
};
void helio_dvfsrc_platform_pre_init(struct helio_dvfsrc *dvfsrc)
{
struct platform_device *pdev = to_platform_device(dvfsrc->dev);
struct resource *res;
res = platform_get_resource(pdev, IORESOURCE_MEM, 1);
dvfsrc->spm_regs = devm_ioremap(&pdev->dev,
res->start, resource_size(res));
if (IS_ERR(dvfsrc->spm_regs))
pr_info("not get spm register\n");
}
__weak void mtk_pm_qos_trace_dbg_dump(int mtk_pm_qos_class)
{
}
void dvfsrc_suspend_cb(struct helio_dvfsrc *dvfsrc)
{
int sw_req;
sw_req = dvfsrc_read(DVFSRC_SW_REQ3);
pr_info("[DVFSRC] V:%d, F_OPP:%d, RG:%08x, %08x, %08x, %08x\n",
get_cur_vcore_uv(),
mtk_pm_qos_request(MTK_PM_QOS_VCORE_DVFS_FORCE_OPP),
dvfsrc_read(DVFSRC_CURRENT_LEVEL),
dvfsrc_read(DVFSRC_SW_REQ2),
sw_req,
dvfsrc_read(DVFSRC_DEBUG_STA_0));
if (sw_req & (DDR_SW_AP_MASK << DDR_SW_AP_SHIFT))
mtk_pm_qos_trace_dbg_dump(MTK_PM_QOS_DDR_OPP);
if (sw_req & (VCORE_SW_AP_MASK << VCORE_SW_AP_SHIFT))
mtk_pm_qos_trace_dbg_dump(MTK_PM_QOS_VCORE_OPP);
}
void dvfsrc_resume_cb(struct helio_dvfsrc *dvfsrc)
{
}
void helio_dvfsrc_platform_init(struct helio_dvfsrc *dvfsrc)
{
int spmfw_idx = 0;
struct reg_config *config;
int idx = 0;
sysfs_merge_group(&dvfsrc->dev->kobj, &mt6853_helio_dvfsrc_attr_group);
config = dvfsrc_init_configs[spmfw_idx];
while (config[idx].offset != -1) {
dvfsrc_write(config[idx].offset, config[idx].val);
idx++;
}
#ifdef AUTOK_ENABLE
dvfsrc_autok_manager();
#endif
fb_register_client(&dvfsrc_fb_notifier);
}
int vcore_pmic_to_uv(int pmic_val)
{
return __vcore_pmic_to_uv(pmic_val);
}
int vcore_uv_to_pmic(int vcore_uv)
{
return __vcore_uv_to_pmic(vcore_uv);
}
void get_spm_reg(char *p)
{
p += sprintf(p, "%-24s: 0x%08x\n",
"POWERON_CONFIG_EN",
spm_reg_read(POWERON_CONFIG_EN));
p += sprintf(p, "%-24s: 0x%08x\n",
"SPM_SW_FLAG_0",
spm_reg_read(SPM_SW_FLAG_0));
p += sprintf(p, "%-24s: 0x%08x\n",
"SPM_PC_STA",
spm_reg_read(SPM_PC_STA));
p += sprintf(p, "%-24s: 0x%08x\n",
"SPM_DVFS_LEVEL",
spm_reg_read(SPM_DVFS_LEVEL));
p += sprintf(p, "%-24s: 0x%08x\n",
"SPM_DVS_DFS_LEVEL",
spm_reg_read(SPM_DVS_DFS_LEVEL));
p += sprintf(p, "%-24s: 0x%08x\n",
"SPM_DVFS_STA",
spm_reg_read(SPM_DVFS_STA));
p += sprintf(p, "%-24s: 0x%08x\n",
"SPM_DVFS_MISC",
spm_reg_read(SPM_DVFS_MISC));
p += sprintf(p, "%-24s: 0x%08x, 0x%08x, 0x%08x, 0x%08x, 0x%08x\n",
"SPM_DVFS_CMD0~4",
spm_reg_read(SPM_DVFS_CMD0),
spm_reg_read(SPM_DVFS_CMD1),
spm_reg_read(SPM_DVFS_CMD2),
spm_reg_read(SPM_DVFS_CMD3),
spm_reg_read(SPM_DVFS_CMD4));
}
void get_opp_info(char *p)
{
#if defined(CONFIG_FPGA_EARLY_PORTING) || !defined(CONFIG_MTK_PMIC_COMMON)
int pmic_val = 0;
#else
int pmic_val = pmic_get_register_value(PMIC_VCORE_ADDR);
#endif
#ifdef CONFIG_MEDIATEK_DRAMC
int ddr_khz = mtk_dramc_get_data_rate() * 1000;
#else
int ddr_khz = 0;
#endif
int vcore_uv = vcore_pmic_to_uv(pmic_val);
p += sprintf(p, "%-10s: %-8u uv (PMIC: 0x%x)\n",
"Vcore", vcore_uv, vcore_uv_to_pmic(vcore_uv));
p += sprintf(p, "%-10s: %-8u khz\n", "DDR", ddr_khz);
p += sprintf(p, "%-10s: %d\n", "CT_MODE", dvfsrc_ct_mode());
p += sprintf(p, "%-10s: %x\n", "V_MODE", dvfsrc_vcore_mode());
}
/* met profile table */
static unsigned int met_vcorefs_src[SRC_MAX];
static char *met_src_name[SRC_MAX] = {
"MD2SPM",
"SRC_DDR_OPP",
"DDR__SW_REQ1_SPM",
"DDR__SW_REQ2_CM",
"DDR__SW_REQ3_PMQOS",
"DDR__QOS_BW",
"DDR__EMI_TOTAL",
"DDR__HRT_BW",
"DDR__HIFI",
"DDR__HIFI_LATENCY",
"DDR__MD_LATENCY",
"DDR__MD_DDR",
"DDR__MD_LEVEL_MASK",
"SRC_VCORE_OPP",
"VCORE__SW_REQ3_PMQOS",
"VCORE__SCP",
"VCORE__HIFI",
"VCORE__PCIE",
"SCP_REQ",
"PMQOS_TATOL",
"PMQOS_BW0",
"PMQOS_BW1",
"PMQOS_BW2",
"PMQOS_BW3",
"PMQOS_BW4",
"TOTAL_EMI_BW",
"HRT_MD_BW",
"HRT_DISP_BW",
"HRT_ISP_BW",
"MD_SCENARIO",
"HIFI_SCENARIO_IDX",
"MD_EMI_LATENCY",
};
/* met profile function */
int vcorefs_get_src_req_num(void)
{
return SRC_MAX;
}
EXPORT_SYMBOL(vcorefs_get_src_req_num);
char **vcorefs_get_src_req_name(void)
{
return met_src_name;
}
EXPORT_SYMBOL(vcorefs_get_src_req_name);
static u32 vcorefs_get_md_level_mask_ddr(void)
{
int md_srclk, vopp;
if (dvfsrc_read(DVFSRC_BASIC_CONTROL_3) & 0x8) {
md_srclk = dvfsrc_read(DVFSRC_DEBUG_STA_0);
vopp = get_cur_vcore_opp();
md_srclk = (md_srclk >> MD_SRC_CLK_DEBUG_SHIFT)
& MD_SRC_CLK_DEBUG_MASK;
if (vopp != 3 && md_srclk == 1)
return 2;
}
return 0;
}
static void vcorefs_get_src_ddr_req(void)
{
unsigned int sw_req;
met_vcorefs_src[DDR_OPP_IDX] =
get_cur_ddr_opp();
sw_req = dvfsrc_read(DVFSRC_SW_REQ1);
met_vcorefs_src[DDR_SW_REQ1_SPM_IDX] =
(sw_req >> DDR_SW_AP_SHIFT) & DDR_SW_AP_MASK;
sw_req = dvfsrc_read(DVFSRC_SW_REQ2);
met_vcorefs_src[DDR_SW_REQ2_CM_IDX] =
(sw_req >> DDR_SW_AP_SHIFT) & DDR_SW_AP_MASK;
sw_req = dvfsrc_read(DVFSRC_SW_REQ3);
met_vcorefs_src[DDR_SW_REQ3_PMQOS_IDX] =
(sw_req >> DDR_SW_AP_SHIFT) & DDR_SW_AP_MASK;
met_vcorefs_src[DDR_QOS_BW_IDX] =
dvfsrc_get_ddr_qos();
met_vcorefs_src[DDR_EMI_TOTAL_IDX] =
dvfsrc_get_emi_mon_gear();
met_vcorefs_src[DDR_HRT_BW_IDX] =
vcorefs_get_hrt_bw_ddr();
met_vcorefs_src[DDR_HIFI_IDX] =
vcorefs_get_hifi_ddr_status();
met_vcorefs_src[DDR_HIFI_LATENCY_IDX] =
vcorefs_get_hifi_rising_ddr();
met_vcorefs_src[DDR_MD_LATENCY_IDX] =
vcorefs_get_md_imp_ddr();
met_vcorefs_src[DDR_MD_DDR_IDX] =
vcorefs_get_md_scenario_ddr();
met_vcorefs_src[DDR_MD_SRCLK_IDX] =
vcorefs_get_md_level_mask_ddr();
}
static void vcorefs_get_src_vcore_req(void)
{
u32 sw_req;
u32 scp_en;
scp_en = vcorefs_get_scp_req_status();
met_vcorefs_src[VCORE_OPP_IDX] =
get_cur_vcore_opp();
sw_req = dvfsrc_read(DVFSRC_SW_REQ3);
met_vcorefs_src[VCORE_SW_REQ3_PMQOS_IDX] =
(sw_req >> VCORE_SW_AP_SHIFT) & VCORE_SW_AP_MASK;
if (scp_en) {
sw_req = dvfsrc_read(DVFSRC_VCORE_REQUEST);
met_vcorefs_src[VCORE_SCP_IDX] =
(sw_req >> VCORE_SCP_GEAR_SHIFT) & VCORE_SCP_GEAR_MASK;
} else
met_vcorefs_src[VCORE_SCP_IDX] = 0;
met_vcorefs_src[VCORE_HIFI_IDX] =
vcorefs_get_hifi_vcore_status();
met_vcorefs_src[VCORE_PCIE_IDX] =
dvfsrc_get_pcie_vcore_status();
}
static void vcorefs_get_src_misc_info(void)
{
u32 qos_bw0, qos_bw1, qos_bw2, qos_bw3, qos_bw4;
qos_bw0 = dvfsrc_read(DVFSRC_SW_BW_0);
qos_bw1 = dvfsrc_read(DVFSRC_SW_BW_1);
qos_bw2 = dvfsrc_read(DVFSRC_SW_BW_2);
qos_bw3 = dvfsrc_read(DVFSRC_SW_BW_3);
qos_bw4 = dvfsrc_read(DVFSRC_SW_BW_4);
met_vcorefs_src[SRC_MD2SPM_IDX] =
vcorefs_get_md_scenario() & 0x1FFFF;
met_vcorefs_src[SRC_SCP_REQ_IDX] =
vcorefs_get_scp_req_status();
met_vcorefs_src[SRC_PMQOS_TATOL_IDX] =
qos_bw0 + qos_bw1 + qos_bw2 + qos_bw3 + qos_bw4;
met_vcorefs_src[SRC_PMQOS_BW0_IDX] =
qos_bw0;
met_vcorefs_src[SRC_PMQOS_BW1_IDX] =
qos_bw1;
met_vcorefs_src[SRC_PMQOS_BW2_IDX] =
qos_bw2;
met_vcorefs_src[SRC_PMQOS_BW3_IDX] =
qos_bw3;
met_vcorefs_src[SRC_PMQOS_BW4_IDX] =
qos_bw4;
met_vcorefs_src[SRC_HRT_MD_BW_IDX] =
dvfsrc_get_md_bw();
met_vcorefs_src[SRC_HRT_ISP_BW_IDX] =
dvfsrc_read(DVFSRC_ISP_HRT);
met_vcorefs_src[SRC_MD_SCENARIO_IDX] =
vcorefs_get_md_scenario();
met_vcorefs_src[SRC_HIFI_SCENARIO_IDX] =
vcorefs_get_hifi_scenario();
met_vcorefs_src[SRC_MD_EMI_LATENCY_IDX] =
vcorefs_get_md_emi_latency_status();
}
int dvfsrc_latch_register(int enable)
{
#ifdef CONFIG_MTK_DBGTOP
return mtk_dbgtop_cfg_dvfsrc(1);
#endif
return 0;
}
unsigned int *vcorefs_get_src_req(void)
{
vcorefs_get_src_ddr_req();
vcorefs_get_src_vcore_req();
vcorefs_get_src_misc_info();
vcorefs_trace_qos();
return met_vcorefs_src;
}
EXPORT_SYMBOL(vcorefs_get_src_req);
int get_cur_ddr_ratio(void)
{
int idx;
if (!is_dvfsrc_enabled())
return 0;
idx = get_cur_vcore_dvfs_opp();
if (idx >= VCORE_DVFS_OPP_NUM)
return 0;
if (get_ddr_opp(idx) < DDR_OPP_6)
return 8;
else
return 4;
}
EXPORT_SYMBOL(get_cur_ddr_ratio);