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ufs-qcom.c
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ufs-qcom.c
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// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (c) 2013-2016, Linux Foundation. All rights reserved.
*/
#include <linux/acpi.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/devfreq.h>
#include <linux/gpio/consumer.h>
#include <linux/interconnect.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/phy/phy.h>
#include <linux/platform_device.h>
#include <linux/reset-controller.h>
#include <linux/time.h>
#include <soc/qcom/ice.h>
#include <ufs/ufshcd.h>
#include <ufs/ufshci.h>
#include <ufs/ufs_quirks.h>
#include <ufs/unipro.h>
#include "ufshcd-pltfrm.h"
#include "ufs-qcom.h"
#define MCQ_QCFGPTR_MASK GENMASK(7, 0)
#define MCQ_QCFGPTR_UNIT 0x200
#define MCQ_SQATTR_OFFSET(c) \
((((c) >> 16) & MCQ_QCFGPTR_MASK) * MCQ_QCFGPTR_UNIT)
#define MCQ_QCFG_SIZE 0x40
enum {
TSTBUS_UAWM,
TSTBUS_UARM,
TSTBUS_TXUC,
TSTBUS_RXUC,
TSTBUS_DFC,
TSTBUS_TRLUT,
TSTBUS_TMRLUT,
TSTBUS_OCSC,
TSTBUS_UTP_HCI,
TSTBUS_COMBINED,
TSTBUS_WRAPPER,
TSTBUS_UNIPRO,
TSTBUS_MAX,
};
#define QCOM_UFS_MAX_GEAR 4
#define QCOM_UFS_MAX_LANE 2
enum {
MODE_MIN,
MODE_PWM,
MODE_HS_RA,
MODE_HS_RB,
MODE_MAX,
};
static const struct __ufs_qcom_bw_table {
u32 mem_bw;
u32 cfg_bw;
} ufs_qcom_bw_table[MODE_MAX + 1][QCOM_UFS_MAX_GEAR + 1][QCOM_UFS_MAX_LANE + 1] = {
[MODE_MIN][0][0] = { 0, 0 }, /* Bandwidth values in KB/s */
[MODE_PWM][UFS_PWM_G1][UFS_LANE_1] = { 922, 1000 },
[MODE_PWM][UFS_PWM_G2][UFS_LANE_1] = { 1844, 1000 },
[MODE_PWM][UFS_PWM_G3][UFS_LANE_1] = { 3688, 1000 },
[MODE_PWM][UFS_PWM_G4][UFS_LANE_1] = { 7376, 1000 },
[MODE_PWM][UFS_PWM_G1][UFS_LANE_2] = { 1844, 1000 },
[MODE_PWM][UFS_PWM_G2][UFS_LANE_2] = { 3688, 1000 },
[MODE_PWM][UFS_PWM_G3][UFS_LANE_2] = { 7376, 1000 },
[MODE_PWM][UFS_PWM_G4][UFS_LANE_2] = { 14752, 1000 },
[MODE_HS_RA][UFS_HS_G1][UFS_LANE_1] = { 127796, 1000 },
[MODE_HS_RA][UFS_HS_G2][UFS_LANE_1] = { 255591, 1000 },
[MODE_HS_RA][UFS_HS_G3][UFS_LANE_1] = { 1492582, 102400 },
[MODE_HS_RA][UFS_HS_G4][UFS_LANE_1] = { 2915200, 204800 },
[MODE_HS_RA][UFS_HS_G1][UFS_LANE_2] = { 255591, 1000 },
[MODE_HS_RA][UFS_HS_G2][UFS_LANE_2] = { 511181, 1000 },
[MODE_HS_RA][UFS_HS_G3][UFS_LANE_2] = { 1492582, 204800 },
[MODE_HS_RA][UFS_HS_G4][UFS_LANE_2] = { 2915200, 409600 },
[MODE_HS_RB][UFS_HS_G1][UFS_LANE_1] = { 149422, 1000 },
[MODE_HS_RB][UFS_HS_G2][UFS_LANE_1] = { 298189, 1000 },
[MODE_HS_RB][UFS_HS_G3][UFS_LANE_1] = { 1492582, 102400 },
[MODE_HS_RB][UFS_HS_G4][UFS_LANE_1] = { 2915200, 204800 },
[MODE_HS_RB][UFS_HS_G1][UFS_LANE_2] = { 298189, 1000 },
[MODE_HS_RB][UFS_HS_G2][UFS_LANE_2] = { 596378, 1000 },
[MODE_HS_RB][UFS_HS_G3][UFS_LANE_2] = { 1492582, 204800 },
[MODE_HS_RB][UFS_HS_G4][UFS_LANE_2] = { 2915200, 409600 },
[MODE_MAX][0][0] = { 7643136, 307200 },
};
static void ufs_qcom_get_default_testbus_cfg(struct ufs_qcom_host *host);
static int ufs_qcom_set_core_clk_ctrl(struct ufs_hba *hba, bool is_scale_up);
static struct ufs_qcom_host *rcdev_to_ufs_host(struct reset_controller_dev *rcd)
{
return container_of(rcd, struct ufs_qcom_host, rcdev);
}
#ifdef CONFIG_SCSI_UFS_CRYPTO
static inline void ufs_qcom_ice_enable(struct ufs_qcom_host *host)
{
if (host->hba->caps & UFSHCD_CAP_CRYPTO)
qcom_ice_enable(host->ice);
}
static int ufs_qcom_ice_init(struct ufs_qcom_host *host)
{
struct ufs_hba *hba = host->hba;
struct device *dev = hba->dev;
struct qcom_ice *ice;
ice = of_qcom_ice_get(dev);
if (ice == ERR_PTR(-EOPNOTSUPP)) {
dev_warn(dev, "Disabling inline encryption support\n");
ice = NULL;
}
if (IS_ERR_OR_NULL(ice))
return PTR_ERR_OR_ZERO(ice);
host->ice = ice;
hba->caps |= UFSHCD_CAP_CRYPTO;
return 0;
}
static inline int ufs_qcom_ice_resume(struct ufs_qcom_host *host)
{
if (host->hba->caps & UFSHCD_CAP_CRYPTO)
return qcom_ice_resume(host->ice);
return 0;
}
static inline int ufs_qcom_ice_suspend(struct ufs_qcom_host *host)
{
if (host->hba->caps & UFSHCD_CAP_CRYPTO)
return qcom_ice_suspend(host->ice);
return 0;
}
static int ufs_qcom_ice_program_key(struct ufs_hba *hba,
const union ufs_crypto_cfg_entry *cfg,
int slot)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
union ufs_crypto_cap_entry cap;
bool config_enable =
cfg->config_enable & UFS_CRYPTO_CONFIGURATION_ENABLE;
/* Only AES-256-XTS has been tested so far. */
cap = hba->crypto_cap_array[cfg->crypto_cap_idx];
if (cap.algorithm_id != UFS_CRYPTO_ALG_AES_XTS ||
cap.key_size != UFS_CRYPTO_KEY_SIZE_256)
return -EOPNOTSUPP;
if (config_enable)
return qcom_ice_program_key(host->ice,
QCOM_ICE_CRYPTO_ALG_AES_XTS,
QCOM_ICE_CRYPTO_KEY_SIZE_256,
cfg->crypto_key,
cfg->data_unit_size, slot);
else
return qcom_ice_evict_key(host->ice, slot);
}
#else
#define ufs_qcom_ice_program_key NULL
static inline void ufs_qcom_ice_enable(struct ufs_qcom_host *host)
{
}
static int ufs_qcom_ice_init(struct ufs_qcom_host *host)
{
return 0;
}
static inline int ufs_qcom_ice_resume(struct ufs_qcom_host *host)
{
return 0;
}
static inline int ufs_qcom_ice_suspend(struct ufs_qcom_host *host)
{
return 0;
}
#endif
static void ufs_qcom_disable_lane_clks(struct ufs_qcom_host *host)
{
if (!host->is_lane_clks_enabled)
return;
clk_bulk_disable_unprepare(host->num_clks, host->clks);
host->is_lane_clks_enabled = false;
}
static int ufs_qcom_enable_lane_clks(struct ufs_qcom_host *host)
{
int err;
err = clk_bulk_prepare_enable(host->num_clks, host->clks);
if (err)
return err;
host->is_lane_clks_enabled = true;
return 0;
}
static int ufs_qcom_init_lane_clks(struct ufs_qcom_host *host)
{
int err;
struct device *dev = host->hba->dev;
if (has_acpi_companion(dev))
return 0;
err = devm_clk_bulk_get_all(dev, &host->clks);
if (err <= 0)
return err;
host->num_clks = err;
return 0;
}
static int ufs_qcom_check_hibern8(struct ufs_hba *hba)
{
int err;
u32 tx_fsm_val;
unsigned long timeout = jiffies + msecs_to_jiffies(HBRN8_POLL_TOUT_MS);
do {
err = ufshcd_dme_get(hba,
UIC_ARG_MIB_SEL(MPHY_TX_FSM_STATE,
UIC_ARG_MPHY_TX_GEN_SEL_INDEX(0)),
&tx_fsm_val);
if (err || tx_fsm_val == TX_FSM_HIBERN8)
break;
/* sleep for max. 200us */
usleep_range(100, 200);
} while (time_before(jiffies, timeout));
/*
* we might have scheduled out for long during polling so
* check the state again.
*/
if (time_after(jiffies, timeout))
err = ufshcd_dme_get(hba,
UIC_ARG_MIB_SEL(MPHY_TX_FSM_STATE,
UIC_ARG_MPHY_TX_GEN_SEL_INDEX(0)),
&tx_fsm_val);
if (err) {
dev_err(hba->dev, "%s: unable to get TX_FSM_STATE, err %d\n",
__func__, err);
} else if (tx_fsm_val != TX_FSM_HIBERN8) {
err = tx_fsm_val;
dev_err(hba->dev, "%s: invalid TX_FSM_STATE = %d\n",
__func__, err);
}
return err;
}
static void ufs_qcom_select_unipro_mode(struct ufs_qcom_host *host)
{
ufshcd_rmwl(host->hba, QUNIPRO_SEL, QUNIPRO_SEL, REG_UFS_CFG1);
if (host->hw_ver.major >= 0x05)
ufshcd_rmwl(host->hba, QUNIPRO_G4_SEL, 0, REG_UFS_CFG0);
/* make sure above configuration is applied before we return */
mb();
}
/*
* ufs_qcom_host_reset - reset host controller and PHY
*/
static int ufs_qcom_host_reset(struct ufs_hba *hba)
{
int ret;
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
bool reenable_intr;
if (!host->core_reset)
return 0;
reenable_intr = hba->is_irq_enabled;
ufshcd_disable_irq(hba);
ret = reset_control_assert(host->core_reset);
if (ret) {
dev_err(hba->dev, "%s: core_reset assert failed, err = %d\n",
__func__, ret);
return ret;
}
/*
* The hardware requirement for delay between assert/deassert
* is at least 3-4 sleep clock (32.7KHz) cycles, which comes to
* ~125us (4/32768). To be on the safe side add 200us delay.
*/
usleep_range(200, 210);
ret = reset_control_deassert(host->core_reset);
if (ret) {
dev_err(hba->dev, "%s: core_reset deassert failed, err = %d\n",
__func__, ret);
return ret;
}
usleep_range(1000, 1100);
if (reenable_intr)
ufshcd_enable_irq(hba);
return 0;
}
static u32 ufs_qcom_get_hs_gear(struct ufs_hba *hba)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
if (host->hw_ver.major >= 0x4)
return UFS_QCOM_MAX_GEAR(ufshcd_readl(hba, REG_UFS_PARAM0));
/* Default is HS-G3 */
return UFS_HS_G3;
}
static int ufs_qcom_power_up_sequence(struct ufs_hba *hba)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
struct ufs_host_params *host_params = &host->host_params;
struct phy *phy = host->generic_phy;
enum phy_mode mode;
int ret;
/*
* HW ver 5 can only support up to HS-G5 Rate-A due to HW limitations.
* If the HS-G5 PHY gear is used, update host_params->hs_rate to Rate-A,
* so that the subsequent power mode change shall stick to Rate-A.
*/
if (host->hw_ver.major == 0x5) {
if (host->phy_gear == UFS_HS_G5)
host_params->hs_rate = PA_HS_MODE_A;
else
host_params->hs_rate = PA_HS_MODE_B;
}
mode = host_params->hs_rate == PA_HS_MODE_B ? PHY_MODE_UFS_HS_B : PHY_MODE_UFS_HS_A;
/* Reset UFS Host Controller and PHY */
ret = ufs_qcom_host_reset(hba);
if (ret)
return ret;
/* phy initialization - calibrate the phy */
ret = phy_init(phy);
if (ret) {
dev_err(hba->dev, "%s: phy init failed, ret = %d\n",
__func__, ret);
return ret;
}
ret = phy_set_mode_ext(phy, mode, host->phy_gear);
if (ret)
goto out_disable_phy;
/* power on phy - start serdes and phy's power and clocks */
ret = phy_power_on(phy);
if (ret) {
dev_err(hba->dev, "%s: phy power on failed, ret = %d\n",
__func__, ret);
goto out_disable_phy;
}
ufs_qcom_select_unipro_mode(host);
return 0;
out_disable_phy:
phy_exit(phy);
return ret;
}
/*
* The UTP controller has a number of internal clock gating cells (CGCs).
* Internal hardware sub-modules within the UTP controller control the CGCs.
* Hardware CGCs disable the clock to inactivate UTP sub-modules not involved
* in a specific operation, UTP controller CGCs are by default disabled and
* this function enables them (after every UFS link startup) to save some power
* leakage.
*/
static void ufs_qcom_enable_hw_clk_gating(struct ufs_hba *hba)
{
ufshcd_rmwl(hba, REG_UFS_CFG2_CGC_EN_ALL, REG_UFS_CFG2_CGC_EN_ALL,
REG_UFS_CFG2);
/* Ensure that HW clock gating is enabled before next operations */
mb();
}
static int ufs_qcom_hce_enable_notify(struct ufs_hba *hba,
enum ufs_notify_change_status status)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
int err;
switch (status) {
case PRE_CHANGE:
err = ufs_qcom_power_up_sequence(hba);
if (err)
return err;
/*
* The PHY PLL output is the source of tx/rx lane symbol
* clocks, hence, enable the lane clocks only after PHY
* is initialized.
*/
err = ufs_qcom_enable_lane_clks(host);
break;
case POST_CHANGE:
/* check if UFS PHY moved from DISABLED to HIBERN8 */
err = ufs_qcom_check_hibern8(hba);
ufs_qcom_enable_hw_clk_gating(hba);
ufs_qcom_ice_enable(host);
break;
default:
dev_err(hba->dev, "%s: invalid status %d\n", __func__, status);
err = -EINVAL;
break;
}
return err;
}
/**
* ufs_qcom_cfg_timers - Configure ufs qcom cfg timers
*
* @hba: host controller instance
* @gear: Current operating gear
* @hs: current power mode
* @rate: current operating rate (A or B)
* @update_link_startup_timer: indicate if link_start ongoing
* @is_pre_scale_up: flag to check if pre scale up condition.
* Return: zero for success and non-zero in case of a failure.
*/
static int ufs_qcom_cfg_timers(struct ufs_hba *hba, u32 gear,
u32 hs, u32 rate, bool update_link_startup_timer,
bool is_pre_scale_up)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
struct ufs_clk_info *clki;
unsigned long core_clk_rate = 0;
u32 core_clk_cycles_per_us;
/*
* UTP controller uses SYS1CLK_1US_REG register for Interrupt
* Aggregation logic.
* It is mandatory to write SYS1CLK_1US_REG register on UFS host
* controller V4.0.0 onwards.
*/
if (host->hw_ver.major < 4 && !ufshcd_is_intr_aggr_allowed(hba))
return 0;
if (gear == 0) {
dev_err(hba->dev, "%s: invalid gear = %d\n", __func__, gear);
return -EINVAL;
}
list_for_each_entry(clki, &hba->clk_list_head, list) {
if (!strcmp(clki->name, "core_clk")) {
if (is_pre_scale_up)
core_clk_rate = clki->max_freq;
else
core_clk_rate = clk_get_rate(clki->clk);
break;
}
}
/* If frequency is smaller than 1MHz, set to 1MHz */
if (core_clk_rate < DEFAULT_CLK_RATE_HZ)
core_clk_rate = DEFAULT_CLK_RATE_HZ;
core_clk_cycles_per_us = core_clk_rate / USEC_PER_SEC;
if (ufshcd_readl(hba, REG_UFS_SYS1CLK_1US) != core_clk_cycles_per_us) {
ufshcd_writel(hba, core_clk_cycles_per_us, REG_UFS_SYS1CLK_1US);
/*
* make sure above write gets applied before we return from
* this function.
*/
mb();
}
return 0;
}
static int ufs_qcom_link_startup_notify(struct ufs_hba *hba,
enum ufs_notify_change_status status)
{
int err = 0;
switch (status) {
case PRE_CHANGE:
if (ufs_qcom_cfg_timers(hba, UFS_PWM_G1, SLOWAUTO_MODE,
0, true, false)) {
dev_err(hba->dev, "%s: ufs_qcom_cfg_timers() failed\n",
__func__);
return -EINVAL;
}
err = ufs_qcom_set_core_clk_ctrl(hba, true);
if (err)
dev_err(hba->dev, "cfg core clk ctrl failed\n");
/*
* Some UFS devices (and may be host) have issues if LCC is
* enabled. So we are setting PA_Local_TX_LCC_Enable to 0
* before link startup which will make sure that both host
* and device TX LCC are disabled once link startup is
* completed.
*/
if (ufshcd_get_local_unipro_ver(hba) != UFS_UNIPRO_VER_1_41)
err = ufshcd_disable_host_tx_lcc(hba);
break;
default:
break;
}
return err;
}
static void ufs_qcom_device_reset_ctrl(struct ufs_hba *hba, bool asserted)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
/* reset gpio is optional */
if (!host->device_reset)
return;
gpiod_set_value_cansleep(host->device_reset, asserted);
}
static int ufs_qcom_suspend(struct ufs_hba *hba, enum ufs_pm_op pm_op,
enum ufs_notify_change_status status)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
struct phy *phy = host->generic_phy;
if (status == PRE_CHANGE)
return 0;
if (ufs_qcom_is_link_off(hba)) {
/*
* Disable the tx/rx lane symbol clocks before PHY is
* powered down as the PLL source should be disabled
* after downstream clocks are disabled.
*/
ufs_qcom_disable_lane_clks(host);
phy_power_off(phy);
/* reset the connected UFS device during power down */
ufs_qcom_device_reset_ctrl(hba, true);
} else if (!ufs_qcom_is_link_active(hba)) {
ufs_qcom_disable_lane_clks(host);
}
return ufs_qcom_ice_suspend(host);
}
static int ufs_qcom_resume(struct ufs_hba *hba, enum ufs_pm_op pm_op)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
struct phy *phy = host->generic_phy;
int err;
if (ufs_qcom_is_link_off(hba)) {
err = phy_power_on(phy);
if (err) {
dev_err(hba->dev, "%s: failed PHY power on: %d\n",
__func__, err);
return err;
}
err = ufs_qcom_enable_lane_clks(host);
if (err)
return err;
} else if (!ufs_qcom_is_link_active(hba)) {
err = ufs_qcom_enable_lane_clks(host);
if (err)
return err;
}
return ufs_qcom_ice_resume(host);
}
static void ufs_qcom_dev_ref_clk_ctrl(struct ufs_qcom_host *host, bool enable)
{
if (host->dev_ref_clk_ctrl_mmio &&
(enable ^ host->is_dev_ref_clk_enabled)) {
u32 temp = readl_relaxed(host->dev_ref_clk_ctrl_mmio);
if (enable)
temp |= host->dev_ref_clk_en_mask;
else
temp &= ~host->dev_ref_clk_en_mask;
/*
* If we are here to disable this clock it might be immediately
* after entering into hibern8 in which case we need to make
* sure that device ref_clk is active for specific time after
* hibern8 enter.
*/
if (!enable) {
unsigned long gating_wait;
gating_wait = host->hba->dev_info.clk_gating_wait_us;
if (!gating_wait) {
udelay(1);
} else {
/*
* bRefClkGatingWaitTime defines the minimum
* time for which the reference clock is
* required by device during transition from
* HS-MODE to LS-MODE or HIBERN8 state. Give it
* more delay to be on the safe side.
*/
gating_wait += 10;
usleep_range(gating_wait, gating_wait + 10);
}
}
writel_relaxed(temp, host->dev_ref_clk_ctrl_mmio);
/*
* Make sure the write to ref_clk reaches the destination and
* not stored in a Write Buffer (WB).
*/
readl(host->dev_ref_clk_ctrl_mmio);
/*
* If we call hibern8 exit after this, we need to make sure that
* device ref_clk is stable for at least 1us before the hibern8
* exit command.
*/
if (enable)
udelay(1);
host->is_dev_ref_clk_enabled = enable;
}
}
static int ufs_qcom_icc_set_bw(struct ufs_qcom_host *host, u32 mem_bw, u32 cfg_bw)
{
struct device *dev = host->hba->dev;
int ret;
ret = icc_set_bw(host->icc_ddr, 0, mem_bw);
if (ret < 0) {
dev_err(dev, "failed to set bandwidth request: %d\n", ret);
return ret;
}
ret = icc_set_bw(host->icc_cpu, 0, cfg_bw);
if (ret < 0) {
dev_err(dev, "failed to set bandwidth request: %d\n", ret);
return ret;
}
return 0;
}
static struct __ufs_qcom_bw_table ufs_qcom_get_bw_table(struct ufs_qcom_host *host)
{
struct ufs_pa_layer_attr *p = &host->dev_req_params;
int gear = max_t(u32, p->gear_rx, p->gear_tx);
int lane = max_t(u32, p->lane_rx, p->lane_tx);
if (ufshcd_is_hs_mode(p)) {
if (p->hs_rate == PA_HS_MODE_B)
return ufs_qcom_bw_table[MODE_HS_RB][gear][lane];
else
return ufs_qcom_bw_table[MODE_HS_RA][gear][lane];
} else {
return ufs_qcom_bw_table[MODE_PWM][gear][lane];
}
}
static int ufs_qcom_icc_update_bw(struct ufs_qcom_host *host)
{
struct __ufs_qcom_bw_table bw_table;
bw_table = ufs_qcom_get_bw_table(host);
return ufs_qcom_icc_set_bw(host, bw_table.mem_bw, bw_table.cfg_bw);
}
static int ufs_qcom_pwr_change_notify(struct ufs_hba *hba,
enum ufs_notify_change_status status,
struct ufs_pa_layer_attr *dev_max_params,
struct ufs_pa_layer_attr *dev_req_params)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
struct ufs_host_params *host_params = &host->host_params;
int ret = 0;
if (!dev_req_params) {
pr_err("%s: incoming dev_req_params is NULL\n", __func__);
return -EINVAL;
}
switch (status) {
case PRE_CHANGE:
ret = ufshcd_negotiate_pwr_params(host_params, dev_max_params, dev_req_params);
if (ret) {
dev_err(hba->dev, "%s: failed to determine capabilities\n",
__func__);
return ret;
}
/*
* During UFS driver probe, always update the PHY gear to match the negotiated
* gear, so that, if quirk UFSHCD_QUIRK_REINIT_AFTER_MAX_GEAR_SWITCH is enabled,
* the second init can program the optimal PHY settings. This allows one to start
* the first init with either the minimum or the maximum support gear.
*/
if (hba->ufshcd_state == UFSHCD_STATE_RESET) {
/*
* Skip REINIT if the negotiated gear matches with the
* initial phy_gear. Otherwise, update the phy_gear to
* program the optimal gear setting during REINIT.
*/
if (host->phy_gear == dev_req_params->gear_tx)
hba->quirks &= ~UFSHCD_QUIRK_REINIT_AFTER_MAX_GEAR_SWITCH;
else
host->phy_gear = dev_req_params->gear_tx;
}
/* enable the device ref clock before changing to HS mode */
if (!ufshcd_is_hs_mode(&hba->pwr_info) &&
ufshcd_is_hs_mode(dev_req_params))
ufs_qcom_dev_ref_clk_ctrl(host, true);
if (host->hw_ver.major >= 0x4) {
ufshcd_dme_configure_adapt(hba,
dev_req_params->gear_tx,
PA_INITIAL_ADAPT);
}
break;
case POST_CHANGE:
if (ufs_qcom_cfg_timers(hba, dev_req_params->gear_rx,
dev_req_params->pwr_rx,
dev_req_params->hs_rate, false, false)) {
dev_err(hba->dev, "%s: ufs_qcom_cfg_timers() failed\n",
__func__);
/*
* we return error code at the end of the routine,
* but continue to configure UFS_PHY_TX_LANE_ENABLE
* and bus voting as usual
*/
ret = -EINVAL;
}
/* cache the power mode parameters to use internally */
memcpy(&host->dev_req_params,
dev_req_params, sizeof(*dev_req_params));
ufs_qcom_icc_update_bw(host);
/* disable the device ref clock if entered PWM mode */
if (ufshcd_is_hs_mode(&hba->pwr_info) &&
!ufshcd_is_hs_mode(dev_req_params))
ufs_qcom_dev_ref_clk_ctrl(host, false);
break;
default:
ret = -EINVAL;
break;
}
return ret;
}
static int ufs_qcom_quirk_host_pa_saveconfigtime(struct ufs_hba *hba)
{
int err;
u32 pa_vs_config_reg1;
err = ufshcd_dme_get(hba, UIC_ARG_MIB(PA_VS_CONFIG_REG1),
&pa_vs_config_reg1);
if (err)
return err;
/* Allow extension of MSB bits of PA_SaveConfigTime attribute */
return ufshcd_dme_set(hba, UIC_ARG_MIB(PA_VS_CONFIG_REG1),
(pa_vs_config_reg1 | (1 << 12)));
}
static int ufs_qcom_apply_dev_quirks(struct ufs_hba *hba)
{
int err = 0;
if (hba->dev_quirks & UFS_DEVICE_QUIRK_HOST_PA_SAVECONFIGTIME)
err = ufs_qcom_quirk_host_pa_saveconfigtime(hba);
if (hba->dev_info.wmanufacturerid == UFS_VENDOR_WDC)
hba->dev_quirks |= UFS_DEVICE_QUIRK_HOST_PA_TACTIVATE;
return err;
}
static u32 ufs_qcom_get_ufs_hci_version(struct ufs_hba *hba)
{
return ufshci_version(2, 0);
}
/**
* ufs_qcom_advertise_quirks - advertise the known QCOM UFS controller quirks
* @hba: host controller instance
*
* QCOM UFS host controller might have some non standard behaviours (quirks)
* than what is specified by UFSHCI specification. Advertise all such
* quirks to standard UFS host controller driver so standard takes them into
* account.
*/
static void ufs_qcom_advertise_quirks(struct ufs_hba *hba)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
if (host->hw_ver.major == 0x2)
hba->quirks |= UFSHCD_QUIRK_BROKEN_UFS_HCI_VERSION;
if (host->hw_ver.major > 0x3)
hba->quirks |= UFSHCD_QUIRK_REINIT_AFTER_MAX_GEAR_SWITCH;
}
static void ufs_qcom_set_phy_gear(struct ufs_qcom_host *host)
{
struct ufs_host_params *host_params = &host->host_params;
u32 val, dev_major;
host->phy_gear = host_params->hs_tx_gear;
if (host->hw_ver.major < 0x4) {
/*
* For controllers whose major HW version is < 4, power up the
* PHY using minimum supported gear (UFS_HS_G2). Switching to
* max gear will be performed during reinit if supported.
* For newer controllers, whose major HW version is >= 4, power
* up the PHY using max supported gear.
*/
host->phy_gear = UFS_HS_G2;
} else if (host->hw_ver.major >= 0x5) {
val = ufshcd_readl(host->hba, REG_UFS_DEBUG_SPARE_CFG);
dev_major = FIELD_GET(UFS_DEV_VER_MAJOR_MASK, val);
/*
* Since the UFS device version is populated, let's remove the
* REINIT quirk as the negotiated gear won't change during boot.
* So there is no need to do reinit.
*/
if (dev_major != 0x0)
host->hba->quirks &= ~UFSHCD_QUIRK_REINIT_AFTER_MAX_GEAR_SWITCH;
/*
* For UFS 3.1 device and older, power up the PHY using HS-G4
* PHY gear to save power.
*/
if (dev_major > 0x0 && dev_major < 0x4)
host->phy_gear = UFS_HS_G4;
}
}
static void ufs_qcom_set_host_params(struct ufs_hba *hba)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
struct ufs_host_params *host_params = &host->host_params;
ufshcd_init_host_params(host_params);
/* This driver only supports symmetic gear setting i.e., hs_tx_gear == hs_rx_gear */
host_params->hs_tx_gear = host_params->hs_rx_gear = ufs_qcom_get_hs_gear(hba);
}
static void ufs_qcom_set_caps(struct ufs_hba *hba)
{
hba->caps |= UFSHCD_CAP_CLK_GATING | UFSHCD_CAP_HIBERN8_WITH_CLK_GATING;
hba->caps |= UFSHCD_CAP_CLK_SCALING | UFSHCD_CAP_WB_WITH_CLK_SCALING;
hba->caps |= UFSHCD_CAP_AUTO_BKOPS_SUSPEND;
hba->caps |= UFSHCD_CAP_WB_EN;
hba->caps |= UFSHCD_CAP_AGGR_POWER_COLLAPSE;
hba->caps |= UFSHCD_CAP_RPM_AUTOSUSPEND;
}
/**
* ufs_qcom_setup_clocks - enables/disable clocks
* @hba: host controller instance
* @on: If true, enable clocks else disable them.
* @status: PRE_CHANGE or POST_CHANGE notify
*
* Return: 0 on success, non-zero on failure.
*/
static int ufs_qcom_setup_clocks(struct ufs_hba *hba, bool on,
enum ufs_notify_change_status status)
{
struct ufs_qcom_host *host = ufshcd_get_variant(hba);
/*
* In case ufs_qcom_init() is not yet done, simply ignore.
* This ufs_qcom_setup_clocks() shall be called from
* ufs_qcom_init() after init is done.
*/
if (!host)
return 0;
switch (status) {
case PRE_CHANGE:
if (on) {
ufs_qcom_icc_update_bw(host);
} else {
if (!ufs_qcom_is_link_active(hba)) {
/* disable device ref_clk */
ufs_qcom_dev_ref_clk_ctrl(host, false);
}
}
break;
case POST_CHANGE:
if (on) {
/* enable the device ref clock for HS mode*/
if (ufshcd_is_hs_mode(&hba->pwr_info))
ufs_qcom_dev_ref_clk_ctrl(host, true);
} else {
ufs_qcom_icc_set_bw(host, ufs_qcom_bw_table[MODE_MIN][0][0].mem_bw,
ufs_qcom_bw_table[MODE_MIN][0][0].cfg_bw);
}
break;
}
return 0;
}
static int
ufs_qcom_reset_assert(struct reset_controller_dev *rcdev, unsigned long id)
{
struct ufs_qcom_host *host = rcdev_to_ufs_host(rcdev);
ufs_qcom_assert_reset(host->hba);
/* provide 1ms delay to let the reset pulse propagate. */
usleep_range(1000, 1100);
return 0;
}
static int
ufs_qcom_reset_deassert(struct reset_controller_dev *rcdev, unsigned long id)
{
struct ufs_qcom_host *host = rcdev_to_ufs_host(rcdev);
ufs_qcom_deassert_reset(host->hba);
/*
* after reset deassertion, phy will need all ref clocks,
* voltage, current to settle down before starting serdes.
*/
usleep_range(1000, 1100);
return 0;
}
static const struct reset_control_ops ufs_qcom_reset_ops = {
.assert = ufs_qcom_reset_assert,
.deassert = ufs_qcom_reset_deassert,
};
static int ufs_qcom_icc_init(struct ufs_qcom_host *host)
{
struct device *dev = host->hba->dev;
int ret;
host->icc_ddr = devm_of_icc_get(dev, "ufs-ddr");
if (IS_ERR(host->icc_ddr))
return dev_err_probe(dev, PTR_ERR(host->icc_ddr),
"failed to acquire interconnect path\n");
host->icc_cpu = devm_of_icc_get(dev, "cpu-ufs");
if (IS_ERR(host->icc_cpu))
return dev_err_probe(dev, PTR_ERR(host->icc_cpu),
"failed to acquire interconnect path\n");