kernel_samsung_a34x-permissive/drivers/phy/mediatek/phy-mtk-mt6877.c
2024-04-28 15:49:01 +02:00

1212 lines
31 KiB
C
Executable file

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (C) 2020 MediaTek Inc.
*/
#include <linux/clk.h>
#include <linux/io.h>
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/platform_device.h>
#include <linux/io.h>
#include <linux/of.h>
#include <linux/of_irq.h>
#include <linux/of_address.h>
#include <linux/slab.h>
#include <linux/phy/phy.h>
#include <dt-bindings/phy/phy.h>
#include <linux/delay.h>
#include "phy-mtk.h"
#ifdef CONFIG_MTK_USB2JTAG_SUPPORT
#include <mt-plat/mtk_usb2jtag.h>
#endif
#define MTK_USB_PHY_BASE (phy_drv->phy_base)
#define MTK_USB_PHY_PORT_BASE (instance->port_base)
#define MTK_USB_PHY_MISC_BASE (instance->sif_misc)
#define MTK_USB_PHY_FMREG_BASE (instance->sif_fmreg)
#define MTK_USB_PHY_SPLLC_BASE (instance->sif_spllc)
#define MTK_USB_PHY_U2_BASE (instance->sif_u2phy_com)
#define MTK_USB_PHY_CHIP_BASE (instance->sif_chip)
#define MTK_USB_PHY_U3PHYD_BASE (instance->sif_u3phyd)
#define MTK_USB_PHY_B2_BASE (instance->sif_u3phyd_bank2)
#define MTK_USB_PHY_PHYA_BASE (instance->sif_u3phya)
#define MTK_USB_PHY_PHYA_DA_BASE (instance->sif_u3phya_da)
#include "phy-mtk-ssusb-reg.h"
static DEFINE_MUTEX(prepare_lock);
enum mt_phy_version {
MT_PHY_V1 = 1,
MT_PHY_V2,
};
#ifdef CONFIG_FPGA_EARLY_PORTING
static int phy_inst_init(struct mtk_phy_instance *instance)
{
return 0;
}
static int phy_init_soc(struct mtk_phy_instance *instance)
{
return 0;
}
static void phy_savecurrent(struct mtk_phy_instance *instance)
{
}
static void phy_recover(struct mtk_phy_instance *instance)
{
}
static void phy_charger_switch_bc11(struct mtk_phy_instance *instance,
bool on)
{
}
static void phy_dpdm_pulldown(struct mtk_phy_instance *instance,
bool enable)
{
}
static int phy_lpm_enable(struct mtk_phy_instance *instance, bool on)
{
return 0;
}
static int phy_host_mode(struct mtk_phy_instance *instance, bool on)
{
return 0;
}
static int phy_ioread(struct mtk_phy_instance *instance, u32 reg)
{
return 0;
}
static int phy_iowrite(struct mtk_phy_instance *instance,
u32 val, u32 reg)
{
return 0;
}
static bool phy_u3_loop_back_test(struct mtk_phy_instance *instance)
{
return true;
}
static void phy_switch_to_usb(struct mtk_phy_instance *instance)
{
}
static void phy_switch_to_uart(struct mtk_phy_instance *instance)
{
}
bool phy_check_in_uart_mode(struct mtk_phy_instance *instance)
{
return true;
}
static void phy_dump_usb2uart_reg(struct mtk_phy_instance *instance)
{
}
#else
static bool usb_enable_clock(struct mtk_phy_drv *u3phy, bool enable)
{
static int count;
if (!u3phy->clk)
return false;
mutex_lock(&prepare_lock);
phy_printk(K_INFO, "CG, enable<%d>, count<%d>\n", enable, count);
if (enable && count == 0) {
if (clk_prepare_enable(u3phy->clk) != 0)
phy_printk(K_ERR, "clk enable fail\n");
} else if (!enable && count == 1) {
clk_disable_unprepare(u3phy->clk);
}
if (enable)
count++;
else
count = (count == 0) ? 0 : (count - 1);
mutex_unlock(&prepare_lock);
return true;
}
static void u3phywrite32(void __iomem *addr, int offset, int mask, int value)
{
int cur_value;
int new_value;
cur_value = readl(addr);
new_value = (cur_value & (~mask)) | ((value << offset) & mask);
writel(new_value, addr);
}
static int u3phyread32(void __iomem *addr)
{
return readl(addr);
}
static void phy_advance_settings(struct mtk_phy_instance *instance)
{
/* special request from DE */
u32 val, offset;
/* RG_SSUSB_TX_EIDLE_CM, 0x11F40B20[31:28] */
/* 4'b1000, ssusb_USB30_PHYA_regmap_T12FF_TPHY */
val = 0x8;
offset = 0x20;
u3phywrite32(
(MTK_USB_PHY_PHYA_BASE + offset), 28,
(0xf<<28), val);
/* rg_ssusb_cdr_bir_ltr, 0x11F4095C[20:16] 5'b01101 */
/* ssusb_USB30_PHYD_regmap_T12FF_TPHY */
val = 0xd;
offset = 0x5c;
u3phywrite32(
(MTK_USB_PHY_U3PHYD_BASE + offset), 16,
(0x1f<<16), val);
/* HQA request */
u3phywrite32(U3D_USBPHYACR6, RG_USB20_SQTH_OFST,
RG_USB20_SQTH, 0x5);
u3phywrite32(U3D_USBPHYACR6, (28),
(0x1<<28), 0x1);
}
static void phy_efuse_settings(struct mtk_phy_instance *instance)
{
u32 evalue;
evalue = (get_devinfo_with_index(108) & (0x1f<<0)) >> 0;
if (evalue) {
phy_printk(K_INFO, "RG_USB20_INTR_CAL=0x%x\n",
evalue);
u3phywrite32(U3D_USBPHYACR1,
RG_USB20_INTR_CAL_OFST,
RG_USB20_INTR_CAL, evalue);
}
evalue = (get_devinfo_with_index(107) & (0x3f << 16)) >> 16;
if (evalue) {
phy_printk(K_INFO, "RG_SSUSB_IEXT_INTR_CTRL=0x%x\n",
evalue);
u3phywrite32(U3D_USB30_PHYA_REG0,
RG_SSUSB_IEXT_INTR_CTRL_OFST,
RG_SSUSB_IEXT_INTR_CTRL, evalue);
}
evalue = (get_devinfo_with_index(107) & (0x1f << 8)) >> 8;
if (evalue) {
phy_printk(K_INFO, "rg_ssusb_rx_impsel=0x%x\n",
evalue);
u3phywrite32(U3D_PHYD_IMPCAL1,
RG_SSUSB_RX_IMPSEL_OFST,
RG_SSUSB_RX_IMPSEL, evalue);
}
evalue = (get_devinfo_with_index(107) & (0x1f << 0)) >> 0;
if (evalue) {
phy_printk(K_INFO, "g_ssusb_tx_impsel=0x%x (R50)\n",
evalue);
if (evalue < 6)
evalue += 2;
else if (evalue >= 6 && evalue < 15)
evalue += 3;
else
evalue = 15;
phy_printk(K_INFO, "g_ssusb_tx_impsel=0x%x (R45)\n",
evalue);
u3phywrite32(U3D_PHYD_IMPCAL0,
RG_SSUSB_TX_IMPSEL_OFST,
RG_SSUSB_TX_IMPSEL, evalue);
}
}
static int phy_slew_rate_calibration(struct mtk_phy_instance *instance)
{
int i = 0;
int fgRet = 0;
int u4FmOut = 0;
int u4Tmp = 0;
phy_printk(K_DEBUG, "%s\n", __func__);
/* enable USB ring oscillator */
u3phywrite32(U3D_USBPHYACR5, RG_USB20_HSTX_SRCAL_EN_OFST,
RG_USB20_HSTX_SRCAL_EN, 1);
/* wait 1us */
udelay(1);
/* Enable free run clock */
u3phywrite32(RG_SSUSB_SIFSLV_FMMONR1, RG_FRCK_EN_OFST,
RG_FRCK_EN, 0x1);
/* Setting cyclecnt */
u3phywrite32(RG_SSUSB_SIFSLV_FMCR0, RG_CYCLECNT_OFST,
RG_CYCLECNT, 0x400);
/* Enable frequency meter */
u3phywrite32(RG_SSUSB_SIFSLV_FMCR0, RG_FREQDET_EN_OFST,
RG_FREQDET_EN, 0x1);
phy_printk(K_DEBUG, "Freq_Valid=(0x%08X)\n",
u3phyread32(RG_SSUSB_SIFSLV_FMMONR1));
mdelay(1);
/* wait for FM detection done, set 10ms timeout */
for (i = 0; i < 10; i++) {
u4FmOut = u3phyread32(RG_SSUSB_SIFSLV_FMMONR0);
phy_printk(K_DEBUG, "FM_OUT u4FmOut = %d(0x%08X)\n",
u4FmOut, u4FmOut);
if (u4FmOut != 0) {
fgRet = 0;
phy_printk(K_DEBUG, "FM detect loop = %d\n", i);
break;
}
fgRet = 1;
mdelay(1);
}
u3phywrite32(RG_SSUSB_SIFSLV_FMCR0, RG_FREQDET_EN_OFST,
RG_FREQDET_EN, 0);
u3phywrite32(RG_SSUSB_SIFSLV_FMMONR1, RG_FRCK_EN_OFST,
RG_FRCK_EN, 0);
if (u4FmOut == 0) {
u3phywrite32(U3D_USBPHYACR5, RG_USB20_HSTX_SRCTRL_OFST,
RG_USB20_HSTX_SRCTRL, 0x4);
fgRet = 1;
} else {
u4Tmp = (1024 * U3D_PHY_REF_CK * U2_SR_COEF);
u4Tmp = u4Tmp / (u4FmOut * 1000);
phy_printk(K_DEBUG, "SR cali u1SrCalVal = %d\n", u4Tmp);
u3phywrite32(U3D_USBPHYACR5, RG_USB20_HSTX_SRCTRL_OFST,
RG_USB20_HSTX_SRCTRL, u4Tmp);
}
u3phywrite32(U3D_USBPHYACR5, RG_USB20_HSTX_SRCAL_EN_OFST,
RG_USB20_HSTX_SRCAL_EN, 0);
return fgRet;
}
#ifdef CONFIG_MTK_UART_USB_SWITCH
static bool bFirstUartCheck = true;
static bool phy_check_in_uart_mode(struct mtk_phy_instance *instance);
#endif
static int phy_init_soc(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_DEBUG, "%s\n", __func__);
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USB30_PHYA_REG1, RG_SSUSB_VUSB10_ON_OFST,
RG_SSUSB_VUSB10_ON, 1);
#ifdef CONFIG_MTK_UART_USB_SWITCH
if ((bFirstUartCheck && phy_check_in_uart_mode(instance)) ||
instance->uart_mode) {
phy_printk(K_ALET, "%s+ already in UART_MODE\n", __func__);
bFirstUartCheck = false;
instance->uart_mode = 1;
goto reg_done;
} else
bFirstUartCheck = false;
#endif
#ifdef CONFIG_MTK_USB2JTAG_SUPPORT
if (usb2jtag_mode()) {
phy_printk(K_INFO, "%s, bypass in usb2jtag mode\n", __func__);
return 0;
}
#endif
/*switch to USB function. (system register, force ip into usb mode) */
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_EN_OFST,
FORCE_UART_EN, 0);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_EN_OFST,
RG_UART_EN, 0);
u3phywrite32(U3D_U2PHYACR4, RG_USB20_GPIO_CTL_OFST,
RG_USB20_GPIO_CTL, 0);
u3phywrite32(U3D_U2PHYACR4, USB20_GPIO_MODE_OFST,
USB20_GPIO_MODE, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_UART_MODE_OFST,
RG_UART_MODE, 0);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_BC11_SW_EN_OFST,
RG_USB20_BC11_SW_EN, 0);
u3phywrite32(U3D_U2PHYACR4, RG_USB20_DP_100K_MODE_OFST,
RG_USB20_DP_100K_MODE, 1);
u3phywrite32(U3D_U2PHYACR4, USB20_DP_100K_EN_OFST,
USB20_DP_100K_EN, 0);
u3phywrite32(U3D_U2PHYACR4, RG_USB20_DM_100K_EN_OFST,
RG_USB20_DM_100K_EN, 0);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_OTG_VBUSCMP_EN_OFST,
RG_USB20_OTG_VBUSCMP_EN, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_SUSPENDM_OFST,
FORCE_SUSPENDM, 0);
udelay(800);
u3phywrite32(U3D_U2PHYDTM1, FORCE_VBUSVALID_OFST,
FORCE_VBUSVALID, 1);
u3phywrite32(U3D_U2PHYDTM1, FORCE_AVALID_OFST,
FORCE_AVALID, 1);
u3phywrite32(U3D_U2PHYDTM1, FORCE_SESSEND_OFST,
FORCE_SESSEND, 1);
#ifdef CONFIG_MTK_UART_USB_SWITCH
reg_done:
#endif
usb_enable_clock(phy_drv, false);
return 0;
}
static void phy_savecurrent(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_ALET, "%s\n", __func__);
if (instance->sib_mode) {
phy_printk(K_INFO, "%s sib_mode can't savecurrent\n", __func__);
return;
}
#ifdef CONFIG_MTK_UART_USB_SWITCH
if (instance->uart_mode)
goto reg_done;
#endif
#ifdef CONFIG_MTK_USB2JTAG_SUPPORT
if (usb2jtag_mode()) {
phy_printk(K_INFO, "%s, bypass in usb2jtag mode\n", __func__);
return;
}
#endif
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_EN_OFST,
FORCE_UART_EN, 0);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_EN_OFST,
RG_UART_EN, 0);
u3phywrite32(U3D_U2PHYACR4, RG_USB20_GPIO_CTL_OFST,
RG_USB20_GPIO_CTL, 0);
u3phywrite32(U3D_U2PHYACR4, USB20_GPIO_MODE_OFST,
USB20_GPIO_MODE, 0);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_BC11_SW_EN_OFST,
RG_USB20_BC11_SW_EN, 0);
/*u3phywrite32(U3D_USBPHYACR6,
*RG_USB20_OTG_VBUSCMP_EN_OFST,
*RG_USB20_OTG_VBUSCMP_EN, 0);
*/
u3phywrite32(U3D_U2PHYDTM0, RG_SUSPENDM_OFST,
RG_SUSPENDM, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_SUSPENDM_OFST,
FORCE_SUSPENDM, 1);
udelay(2000);
u3phywrite32(U3D_U2PHYDTM0, RG_DPPULLDOWN_OFST,
RG_DPPULLDOWN, 1);
u3phywrite32(U3D_U2PHYDTM0, RG_DMPULLDOWN_OFST,
RG_DMPULLDOWN, 1);
u3phywrite32(U3D_U2PHYDTM0, RG_XCVRSEL_OFST,
RG_XCVRSEL, 0x1);
u3phywrite32(U3D_U2PHYDTM0, RG_TERMSEL_OFST,
RG_TERMSEL, 1);
u3phywrite32(U3D_U2PHYDTM0, RG_DATAIN_OFST,
RG_DATAIN, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_DP_PULLDOWN_OFST,
FORCE_DP_PULLDOWN, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_DM_PULLDOWN_OFST,
FORCE_DM_PULLDOWN, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_XCVRSEL_OFST,
FORCE_XCVRSEL, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_TERMSEL_OFST,
FORCE_TERMSEL, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_DATAIN_OFST,
FORCE_DATAIN, 1);
udelay(800);
u3phywrite32(U3D_U2PHYDTM0, RG_SUSPENDM_OFST,
RG_SUSPENDM, 0);
udelay(1);
u3phywrite32(U3D_U2PHYDTM1, RG_VBUSVALID_OFST,
RG_VBUSVALID, 0);
u3phywrite32(U3D_U2PHYDTM1, RG_AVALID_OFST,
RG_AVALID, 0);
u3phywrite32(U3D_U2PHYDTM1, RG_SESSEND_OFST,
RG_SESSEND, 1);
#ifdef CONFIG_MTK_UART_USB_SWITCH
reg_done:
#endif
u3phywrite32(U3D_USB30_PHYA_REG1, RG_SSUSB_VUSB10_ON_OFST,
RG_SSUSB_VUSB10_ON, 1);
udelay(10);
usb_enable_clock(phy_drv, false);
}
#define VAL_MAX_WIDTH_2 0x3
#define VAL_MAX_WIDTH_3 0x7
static void usb_phy_tuning(struct mtk_phy_instance *instance)
{
s32 u2_vrt_ref, u2_term_ref, u2_enhance;
struct device_node *of_node;
if (!instance->phy_tuning.inited) {
instance->phy_tuning.u2_vrt_ref = 6;
instance->phy_tuning.u2_term_ref = 6;
instance->phy_tuning.u2_enhance = 1;
of_node = of_find_compatible_node(NULL, NULL,
instance->phycfg->tuning_node_name);
if (of_node) {
/* value won't be updated if property not being found */
of_property_read_u32(of_node, "u2_vrt_ref",
(u32 *) &instance->phy_tuning.u2_vrt_ref);
of_property_read_u32(of_node, "u2_term_ref",
(u32 *) &instance->phy_tuning.u2_term_ref);
of_property_read_u32(of_node, "u2_enhance",
(u32 *) &instance->phy_tuning.u2_enhance);
}
instance->phy_tuning.inited = true;
}
u2_vrt_ref = instance->phy_tuning.u2_vrt_ref;
u2_term_ref = instance->phy_tuning.u2_term_ref;
u2_enhance = instance->phy_tuning.u2_enhance;
if (u2_vrt_ref != -1) {
if (u2_vrt_ref <= VAL_MAX_WIDTH_3) {
u3phywrite32(U3D_USBPHYACR1,
RG_USB20_VRT_VREF_SEL_OFST,
RG_USB20_VRT_VREF_SEL, u2_vrt_ref);
}
}
if (u2_term_ref != -1) {
if (u2_term_ref <= VAL_MAX_WIDTH_3) {
u3phywrite32(U3D_USBPHYACR1,
RG_USB20_TERM_VREF_SEL_OFST,
RG_USB20_TERM_VREF_SEL, u2_term_ref);
}
}
if (u2_enhance != -1) {
if (u2_enhance <= VAL_MAX_WIDTH_2) {
u3phywrite32(U3D_USBPHYACR6,
RG_USB20_PHY_REV_6_OFST,
RG_USB20_PHY_REV_6, u2_enhance);
}
}
phy_printk(K_INFO, "%s - SSUSB TX EYE Tuning\n", __func__);
u3phywrite32(U3D_PHYD_MIX6, RG_SSUSB_IDRVSEL_OFST,
RG_SSUSB_IDRVSEL, 0x19);
u3phywrite32(U3D_PHYD_MIX6, RG_SSUSB_FORCE_IDRVSEL_OFST,
RG_SSUSB_FORCE_IDRVSEL, 1);
u3phywrite32(U3D_PHYD_MIX6, RG_SSUSB_IDEMSEL_OFST,
RG_SSUSB_IDEMSEL, 0x1a);
u3phywrite32(U3D_PHYD_MIX6, RG_SSUSB_FORCE_IDEMSEL_OFST,
RG_SSUSB_FORCE_IDEMSEL, 1);
}
static void phy_recover(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_INFO, "%s+\n", __func__);
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USB30_PHYA_REG1, RG_SSUSB_VUSB10_ON_OFST,
RG_SSUSB_VUSB10_ON, 1);
#ifdef CONFIG_MTK_UART_USB_SWITCH
if (instance->uart_mode)
return;
#endif
#ifdef CONFIG_MTK_USB2JTAG_SUPPORT
if (usb2jtag_mode()) {
phy_printk(K_INFO, "%s, bypass in usb2jtag mode\n", __func__);
return;
}
#endif
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_EN_OFST,
FORCE_UART_EN, 0);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_EN_OFST,
RG_UART_EN, 0);
u3phywrite32(U3D_U2PHYACR4, RG_USB20_GPIO_CTL_OFST,
RG_USB20_GPIO_CTL, 0);
u3phywrite32(U3D_U2PHYACR4, USB20_GPIO_MODE_OFST,
USB20_GPIO_MODE, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_SUSPENDM_OFST,
FORCE_SUSPENDM, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_DPPULLDOWN_OFST,
RG_DPPULLDOWN, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_DMPULLDOWN_OFST,
RG_DMPULLDOWN, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_XCVRSEL_OFST,
RG_XCVRSEL, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_TERMSEL_OFST,
RG_TERMSEL, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_DATAIN_OFST,
RG_DATAIN, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_DP_PULLDOWN_OFST,
FORCE_DP_PULLDOWN, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_DM_PULLDOWN_OFST,
FORCE_DM_PULLDOWN, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_XCVRSEL_OFST,
FORCE_XCVRSEL, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_TERMSEL_OFST,
FORCE_TERMSEL, 0);
u3phywrite32(U3D_U2PHYDTM0, FORCE_DATAIN_OFST,
FORCE_DATAIN, 0);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_BC11_SW_EN_OFST,
RG_USB20_BC11_SW_EN, 0);
/*u3phywrite32(U3D_USBPHYACR6, RG_USB20_OTG_VBUSCMP_EN_OFST,
* RG_USB20_OTG_VBUSCMP_EN, 1);
*/
/* Wait 800 usec */
udelay(800);
u3phywrite32(U3D_U2PHYDTM1, RG_VBUSVALID_OFST,
RG_VBUSVALID, 1);
u3phywrite32(U3D_U2PHYDTM1, RG_AVALID_OFST,
RG_AVALID, 1);
u3phywrite32(U3D_U2PHYDTM1, RG_SESSEND_OFST,
RG_SESSEND, 0);
phy_efuse_settings(instance);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_DISCTH_OFST,
RG_USB20_DISCTH, 0x7);
usb_phy_tuning(instance);
phy_advance_settings(instance);
phy_slew_rate_calibration(instance);
phy_printk(K_INFO, "%s-\n", __func__);
}
static int charger_detect_init(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_INFO, "%s+\n", __func__);
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_BC11_SW_EN_OFST,
RG_USB20_BC11_SW_EN, 1);
udelay(1);
usb_enable_clock(phy_drv, false);
phy_printk(K_INFO, "%s-\n", __func__);
return 0;
}
static int charger_detect_release(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_INFO, "%s+\n", __func__);
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_BC11_SW_EN_OFST,
RG_USB20_BC11_SW_EN, 0);
udelay(1);
usb_enable_clock(phy_drv, false);
phy_printk(K_INFO, "%s-\n", __func__);
return 0;
}
static void phy_charger_switch_bc11(struct mtk_phy_instance *instance,
bool on)
{
if (on)
charger_detect_init(instance);
else
charger_detect_release(instance);
}
static void phy_dpdm_pulldown(struct mtk_phy_instance *instance,
bool enable)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_INFO, "%s+\n", __func__);
usb_enable_clock(phy_drv, true);
udelay(250);
if (enable) {
u3phywrite32(U3D_U2PHYDTM0, RG_DPPULLDOWN_OFST,
RG_DPPULLDOWN, 1);
u3phywrite32(U3D_U2PHYDTM0, RG_DMPULLDOWN_OFST,
RG_DMPULLDOWN, 1);
u3phywrite32(U3D_USBPHYACR6,
RG_USB20_PHY_REV_OFST, (0x2<<24), 0x0);
} else {
u3phywrite32(U3D_U2PHYDTM0, RG_DPPULLDOWN_OFST,
RG_DPPULLDOWN, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_DMPULLDOWN_OFST,
RG_DMPULLDOWN, 0);
/*For water detection function,
*need to set DPPULLDOWN and DMPULLDOWN 0
*Also adjust RG_USB20_PHY_REV to prevent power leakage
*/
u3phywrite32(U3D_USBPHYACR6,
RG_USB20_PHY_REV_OFST, (0x2<<24), 0x2);
}
udelay(1);
usb_enable_clock(phy_drv, false);
phy_printk(K_INFO, "%s-\n", __func__);
}
static int phy_lpm_enable(struct mtk_phy_instance *instance, bool on)
{
phy_printk(K_DEBUG, "%s+ = %d\n", __func__, on);
if (on)
u3phywrite32(U3D_U2PHYDCR1, RG_USB20_SW_PLLMODE_OFST,
RG_USB20_SW_PLLMODE, 0x1);
else
u3phywrite32(U3D_U2PHYDCR1, RG_USB20_SW_PLLMODE_OFST,
RG_USB20_SW_PLLMODE, 0x0);
return 0;
}
static int phy_host_mode(struct mtk_phy_instance *instance, bool on)
{
phy_printk(K_DEBUG, "%s+ = %d\n", __func__, on);
return 0;
}
static int phy_ioread(struct mtk_phy_instance *instance, u32 reg)
{
if (reg < instance->port_rgsz)
return readl(instance->sif_u2phy_com + reg);
else
return 0;
}
static int phy_iowrite(struct mtk_phy_instance *instance,
u32 val, u32 reg)
{
if (reg < instance->port_rgsz)
writel(val, instance->sif_u2phy_com + reg);
return 0;
}
static bool phy_u3_loop_back_test(struct mtk_phy_instance *instance)
{
int reg;
bool loop_back_ret = false;
struct mtk_phy_drv *phy_drv = instance->phy_drv;
int r_pipe0, r_rx0, rx_mix0, r_t2rlb;
/* VA10 is shared by U3/UFS */
/* default on and set voltage by PMIC */
/* off/on in SPM suspend/resume */
usb_enable_clock(phy_drv, true);
r_pipe0 = readl(U3D_PHYD_PIPE0);
r_rx0 = readl(U3D_PHYD_RX0);
rx_mix0 = readl(U3D_PHYD_MIX0);
r_t2rlb = readl(U3D_PHYD_T2RLB);
writel((readl(U3D_PHYD_PIPE0) & ~(0x01<<30)) | 0x01<<30,
U3D_PHYD_PIPE0);
writel((readl(U3D_PHYD_PIPE0) & ~(0x01<<28)) | 0x00<<28,
U3D_PHYD_PIPE0);
writel((readl(U3D_PHYD_PIPE0) & ~(0x03<<26)) | 0x01<<26,
U3D_PHYD_PIPE0);
writel((readl(U3D_PHYD_PIPE0) & ~(0x03<<24)) | 0x00<<24,
U3D_PHYD_PIPE0);
writel((readl(U3D_PHYD_PIPE0) & ~(0x01<<22)) | 0x00<<22,
U3D_PHYD_PIPE0);
writel((readl(U3D_PHYD_PIPE0) & ~(0x01<<21)) | 0x00<<21,
U3D_PHYD_PIPE0);
writel((readl(U3D_PHYD_PIPE0) & ~(0x01<<20)) | 0x01<<20,
U3D_PHYD_PIPE0);
mdelay(10);
/*T2R loop back disable*/
writel((readl(U3D_PHYD_RX0)&~(0x01<<15)) | 0x00<<15,
U3D_PHYD_RX0);
mdelay(10);
/* TSEQ lock detect threshold */
writel((readl(U3D_PHYD_MIX0) & ~(0x07<<24)) | 0x07<<24,
U3D_PHYD_MIX0);
/* set default TSEQ polarity check value = 1 */
writel((readl(U3D_PHYD_MIX0) & ~(0x01<<28)) | 0x01<<28,
U3D_PHYD_MIX0);
/* TSEQ polarity check enable */
writel((readl(U3D_PHYD_MIX0) & ~(0x01<<29)) | 0x01<<29,
U3D_PHYD_MIX0);
/* TSEQ decoder enable */
writel((readl(U3D_PHYD_MIX0) & ~(0x01<<30)) | 0x01<<30,
U3D_PHYD_MIX0);
mdelay(10);
/* set T2R loop back TSEQ length (x 16us) */
writel((readl(U3D_PHYD_T2RLB) & ~(0xff<<0)) | 0xF0<<0,
U3D_PHYD_T2RLB);
/* set T2R loop back BDAT reset period (x 16us) */
writel((readl(U3D_PHYD_T2RLB) & ~(0x0f<<12)) | 0x0F<<12,
U3D_PHYD_T2RLB);
/* T2R loop back pattern select */
writel((readl(U3D_PHYD_T2RLB) & ~(0x03<<8)) | 0x00<<8,
U3D_PHYD_T2RLB);
mdelay(10);
/* T2R loop back serial mode */
writel((readl(U3D_PHYD_RX0) & ~(0x01<<13)) | 0x01<<13,
U3D_PHYD_RX0);
/* T2R loop back parallel mode = 0 */
writel((readl(U3D_PHYD_RX0) & ~(0x01<<12)) | 0x00<<12,
U3D_PHYD_RX0);
/* T2R loop back mode enable */
writel((readl(U3D_PHYD_RX0) & ~(0x01<<11)) | 0x01<<11,
U3D_PHYD_RX0);
/* T2R loop back enable */
writel((readl(U3D_PHYD_RX0) & ~(0x01<<15)) | 0x01<<15,
U3D_PHYD_RX0);
mdelay(100);
reg = u3phyread32(SSUSB_SIFSLV_U3PHYD_BASE + 0xb4);
phy_printk(K_INFO, "rb back : 0x%x\n", reg);
phy_printk(K_INFO, "rb t2rlb_lock : %d\n", (reg >> 2) & 0x01);
phy_printk(K_INFO, "rb t2rlb_pass : %d\n", (reg >> 3) & 0x01);
phy_printk(K_INFO, "rb t2rlb_passth: %d\n", (reg >> 4) & 0x01);
if ((reg & 0x0E) == 0x0E)
loop_back_ret = true;
else
loop_back_ret = false;
writel(r_rx0, U3D_PHYD_RX0);
writel(r_pipe0, U3D_PHYD_PIPE0);
writel(rx_mix0, U3D_PHYD_MIX0);
writel(r_t2rlb, U3D_PHYD_T2RLB);
usb_enable_clock(phy_drv, false);
return loop_back_ret;
}
#ifdef CONFIG_MTK_SIB_USB_SWITCH
static void phy_sib_enable(struct mtk_phy_instance *instance, bool enable)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
phy_printk(K_DEBUG, "usb_phy_sib_enable_switch =%d\n", enable);
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USB30_PHYA_REG1, RG_SSUSB_VUSB10_ON_OFST,
RG_SSUSB_VUSB10_ON, 1);
/* SSUSB_SIFSLV_IPPC_BASE SSUSB_IP_SW_RST = 0 */
writel(0x00031000, (void __iomem *)phy_drv->ippc_base + 0x0);
/* SSUSB_IP_HOST_PDN = 0 */
writel(0x00000000, (void __iomem *)phy_drv->ippc_base + 0x4);
/* SSUSB_IP_DEV_PDN = 0 */
writel(0x00000000, (void __iomem *)phy_drv->ippc_base + 0x8);
/* SSUSB_IP_PCIE_PDN = 0 */
writel(0x00000000, (void __iomem *)phy_drv->ippc_base + 0xC);
/* SSUSB_U3_PORT_DIS/SSUSB_U3_PORT_PDN = 0*/
writel(0x0000000C, (void __iomem *)phy_drv->ippc_base + 0x30);
/*
* USBMAC mode is 0x62910002 (bit 1)
* MDSIB mode is 0x62910008 (bit 3)
* 0x0629 just likes a signature. Can't be removed.
*/
if (enable) {
writel(0x62910008, MTK_USB_PHY_CHIP_BASE);
instance->sib_mode = true;
} else {
writel(0x62910002, MTK_USB_PHY_CHIP_BASE);
instance->sib_mode = false;
}
}
static bool phy_sib_switch_status(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
int reg;
bool ret;
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USB30_PHYA_REG1, RG_SSUSB_VUSB10_ON_OFST,
RG_SSUSB_VUSB10_ON, 1);
reg = u3phyread32(MTK_USB_PHY_CHIP_BASE);
phy_printk(K_DEBUG, "%s reg=%d\n", __func__, reg);
if (reg == 0x62910008)
ret = true;
else
ret = false;
return ret;
}
#endif
#ifdef CONFIG_MTK_UART_USB_SWITCH
#include <linux/phy/mediatek/mtk_usb_phy.h>
static void phy_dump_usb2uart_reg(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
usb_enable_clock(phy_drv, true);
udelay(250);
phy_printk(K_ALET, "addr: 0x18, value: 0x%x\n",
u3phyread32(U3D_USBPHYACR6));
phy_printk(K_ALET, "addr: 0x20, value: 0x%x\n",
u3phyread32(U3D_U2PHYACR4));
phy_printk(K_ALET, "addr: 0x68, value: 0x%x\n",
u3phyread32(U3D_U2PHYDTM0));
phy_printk(K_ALET, "addr: 0x6C, value: 0x%x\n",
u3phyread32(U3D_U2PHYDTM1));
usb_enable_clock(phy_drv, false);
}
bool phy_check_in_uart_mode(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
int usb_port_mode;
usb_enable_clock(phy_drv, true);
udelay(250);
usb_port_mode = u3phyread32(U3D_U2PHYDTM0) >> RG_UART_MODE_OFST;
usb_enable_clock(phy_drv, false);
phy_printk(K_ALET, "%s - usb_port_mode = %d, ",
__func__, usb_port_mode);
phy_printk(K_ALET, "%s - instance->uart_mode = %d\n",
__func__, instance->uart_mode);
if (usb_port_mode == 0x1)
return true;
else
return false;
}
static int phy_switch_usb2uart_gpio(enum PORT_MODE portmode)
{
struct device_node *node;
void __iomem *gpio_base;
/* SET USB to UART GPIO to UART0 */
node = of_find_compatible_node(NULL, NULL, "mediatek,gpio");
if (!node) {
pr_info("error: can't find GPIO node\n");
return -EINVAL;
}
gpio_base = of_iomap(node, 0);
if (!gpio_base) {
pr_info("error: iomap fail for GPIO\n");
return -EINVAL;
}
if (portmode == PORT_MODE_UART)
writel((readl(gpio_base + RG_GPIO_SELECT) |
(GPIO_SEL_UART0<<GPIO_SEL_OFFSET)),
gpio_base + RG_GPIO_SELECT);
else
writel((readl(gpio_base + RG_GPIO_SELECT) &
~(GPIO_SEL_MASK<<GPIO_SEL_OFFSET)),
gpio_base + RG_GPIO_SELECT);
return 0;
}
static void phy_switch_to_uart(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
if (phy_check_in_uart_mode(instance)) {
phy_printk(K_DEBUG, "%s+ UART_MODE\n", __func__);
return;
}
phy_printk(K_DEBUG, "%s+ USB_MODE\n", __func__);
usb_enable_clock(phy_drv, true);
udelay(250);
u3phywrite32(U3D_USBPHYACR6, RG_USB20_BC11_SW_EN_OFST,
RG_USB20_BC11_SW_EN, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_SUSPENDM_OFST,
RG_SUSPENDM, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_SUSPENDM_OFST,
FORCE_SUSPENDM, 1);
u3phywrite32(U3D_U2PHYDTM0, RG_UART_MODE_OFST,
RG_UART_MODE, 1);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_EN_OFST,
RG_UART_EN, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_EN_OFST,
FORCE_UART_EN, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_TX_OE_OFST,
FORCE_UART_TX_OE, 1);
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_BIAS_EN_OFST,
FORCE_UART_BIAS_EN, 1);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_EN_OFST,
RG_UART_EN, 1);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_TX_OE_OFST,
RG_UART_TX_OE, 1);
u3phywrite32(U3D_U2PHYDTM1, RG_UART_BIAS_EN_OFST,
RG_UART_BIAS_EN, 1);
u3phywrite32(U3D_U2PHYACR4, RG_USB20_DM_100K_EN_OFST,
RG_USB20_DM_100K_EN, 1);
u3phywrite32(U3D_U2PHYDTM0, RG_DPPULLDOWN_OFST,
RG_DPPULLDOWN, 0);
u3phywrite32(U3D_U2PHYDTM0, RG_DMPULLDOWN_OFST,
RG_DMPULLDOWN, 0);
usb_enable_clock(phy_drv, false);
phy_switch_usb2uart_gpio(PORT_MODE_UART);
instance->uart_mode = true;
}
static void phy_switch_to_usb(struct mtk_phy_instance *instance)
{
instance->uart_mode = false;
u3phywrite32(U3D_U2PHYDTM0, FORCE_UART_EN_OFST,
FORCE_UART_EN, 0);
phy_switch_usb2uart_gpio(PORT_MODE_USB);
phy_init_soc(instance);
}
#endif
#ifdef CONFIG_MTK_USB2JTAG_SUPPORT
int usb2jtag_usb_init(void)
{
struct device_node *node = NULL;
void __iomem *usb3_sif2_base;
u32 temp;
pr_notice("[USB2JTAG] %s ++\n", __func__);
node = of_find_compatible_node(NULL, NULL, "mediatek,usb3");
if (!node) {
pr_notice("[USB2JTAG] map node @ mediatek,usb3 failed\n");
return -1;
}
usb3_sif2_base = of_iomap(node, 2);
if (!usb3_sif2_base) {
pr_notice("[USB2JTAG] iomap usb3_sif2_base failed\n");
return -1;
}
/* rg_usb20_gpio_ctl: bit[9] = 1 */
temp = readl(usb3_sif2_base + 0x320);
writel(temp | (1 << 9), usb3_sif2_base + 0x320);
/* RG_USB20_BC11_SW_EN: bit[23] = 0 */
temp = readl(usb3_sif2_base + 0x318);
writel(temp & ~(1 << 23), usb3_sif2_base + 0x318);
/* RG_USB20_BGR_EN: bit[0] = 1 */
temp = readl(usb3_sif2_base + 0x300);
writel(temp | (1 << 0), usb3_sif2_base + 0x300);
/* rg_sifslv_mac_bandgap_en: bit[17] = 0 */
temp = readl(usb3_sif2_base + 0x308);
writel(temp & ~(1 << 17), usb3_sif2_base + 0x308);
/* wait stable */
mdelay(1);
iounmap(usb3_sif2_base);
return 0;
}
#endif
static int phy_inst_init(struct mtk_phy_instance *instance)
{
struct mtk_phy_drv *phy_drv = instance->phy_drv;
void __iomem *port_base;
phy_printk(K_DEBUG, "%s+\n", __func__);
port_base = instance->port_base;
if (phy_drv->phycfg->version == MT_PHY_V1) {
instance->sif_misc = NULL;
instance->sif_fmreg = phy_drv->phy_base + 0x100;
instance->sif_u2phy_com = port_base;
if (instance->phycfg->port_type == PHY_TYPE_USB3) {
instance->sif_spllc = phy_drv->phy_base;
instance->sif_chip = NULL;
instance->sif_u3phyd = port_base + 0x100;
instance->sif_u3phyd_bank2 = port_base + 0x200;
instance->sif_u3phya = port_base + 0x300;
instance->sif_u3phya_da = port_base + 0x400;
}
instance->port_rgsz = 0x800;
} else if (phy_drv->phycfg->version == MT_PHY_V2) {
instance->sif_misc = port_base;
instance->sif_fmreg = port_base + 0x100;
instance->sif_u2phy_com = port_base + 0x300;
instance->port_rgsz = 0x500;
if (instance->phycfg->port_type == PHY_TYPE_USB3) {
instance->sif_spllc = port_base + 0x700;
instance->sif_chip = port_base + 0x800;
instance->sif_u3phyd = port_base + 0x900;
instance->sif_u3phyd_bank2 = port_base + 0xa00;
instance->sif_u3phya = port_base + 0xb00;
instance->sif_u3phya_da = port_base + 0xc00;
instance->port_rgsz = 0x1000;
}
}
return 0;
}
#endif
static int mtk_phy_drv_init(struct platform_device *pdev,
struct mtk_phy_drv *mtkphy)
{
int ret = 0;
struct device *dev = &pdev->dev;
struct resource *res;
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "sif_base");
if (!res)
return -EINVAL;
mtkphy->phy_base = devm_ioremap(dev, res->start, resource_size(res));
if (IS_ERR(mtkphy->phy_base)) {
dev_info(dev, "failed to remap phy regs\n");
return PTR_ERR(mtkphy->phy_base);
}
res = platform_get_resource_byname(pdev, IORESOURCE_MEM, "ippc");
if (!res)
return -EINVAL;
mtkphy->ippc_base = devm_ioremap(dev, res->start, resource_size(res));
if (IS_ERR(mtkphy->ippc_base)) {
dev_info(dev, "failed to remap ippc_base regs\n");
return PTR_ERR(mtkphy->ippc_base);
}
mtkphy->clk = devm_clk_get(dev, "ref_clk");
if (IS_ERR(mtkphy->clk)) {
if (PTR_ERR(mtkphy->clk) == -EPROBE_DEFER) {
dev_info(dev, "mtkphy->clk EPROBE_DEFER\n");
return -EPROBE_DEFER;
}
mtkphy->clk = NULL;
}
return ret;
}
static int mtk_phy_drv_exit(struct platform_device *pdev,
struct mtk_phy_drv *mtkphy)
{
if (!IS_ERR_OR_NULL(mtkphy->clk))
clk_disable_unprepare(mtkphy->clk);
return 0;
}
static const struct mtk_phy_interface ssusb_phys[] = {
{
.name = "port0",
.tuning_node_name = "mediatek,phy_tuning",
.port_num = 0,
.reg_offset = 0,
.port_type = PHY_TYPE_USB3,
.usb_phy_inst_init = phy_inst_init,
.usb_phy_init = phy_init_soc,
.usb_phy_savecurrent = phy_savecurrent,
.usb_phy_recover = phy_recover,
.usb_phy_switch_to_bc11 = phy_charger_switch_bc11,
.usb_phy_dpdm_pulldown = phy_dpdm_pulldown,
.usb_phy_lpm_enable = phy_lpm_enable,
.usb_phy_host_mode = phy_host_mode,
.usb_phy_io_read = phy_ioread,
.usb_phy_io_write = phy_iowrite,
#ifdef CONFIG_MTK_UART_USB_SWITCH
.usb_phy_switch_to_usb = phy_switch_to_usb,
.usb_phy_switch_to_uart = phy_switch_to_uart,
.usb_phy_check_in_uart_mode = phy_check_in_uart_mode,
.usb_phy_dump_usb2uart_reg = phy_dump_usb2uart_reg,
#endif
#ifdef CONFIG_MTK_SIB_USB_SWITCH
.usb_phy_sib_enable_switch = phy_sib_enable,
.usb_phy_sib_switch_status = phy_sib_switch_status,
#endif
.usb_phy_u3_loop_back_test = phy_u3_loop_back_test,
},
};
static const struct mtk_usbphy_config ssusb_phy_config = {
.phys = ssusb_phys,
.num_phys = 1,
.version = MT_PHY_V2,
.usb_drv_init = mtk_phy_drv_init,
.usb_drv_exit = mtk_phy_drv_exit,
};
const struct of_device_id mtk_phy_of_match[] = {
{
.compatible = "mediatek,mt6877-phy",
.data = &ssusb_phy_config,
},
{ },
};