Staging
v0.5.1
v0.5.1
https://github.com/torvalds/linux
Tip revision: 9ff01193a20d391e8dbce4403dd5ef87c7eaaca6 authored by Linus Torvalds on 18 November 2018, 21:33:44 UTC
Linux 4.20-rc3
Linux 4.20-rc3
Tip revision: 9ff0119
phy-mtk-tphy.c
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2015 MediaTek Inc.
* Author: Chunfeng Yun <chunfeng.yun@mediatek.com>
*
*/
#include <dt-bindings/phy/phy.h>
#include <linux/clk.h>
#include <linux/delay.h>
#include <linux/io.h>
#include <linux/iopoll.h>
#include <linux/module.h>
#include <linux/of_address.h>
#include <linux/of_device.h>
#include <linux/phy/phy.h>
#include <linux/platform_device.h>
/* version V1 sub-banks offset base address */
/* banks shared by multiple phys */
#define SSUSB_SIFSLV_V1_SPLLC 0x000 /* shared by u3 phys */
#define SSUSB_SIFSLV_V1_U2FREQ 0x100 /* shared by u2 phys */
#define SSUSB_SIFSLV_V1_CHIP 0x300 /* shared by u3 phys */
/* u2 phy bank */
#define SSUSB_SIFSLV_V1_U2PHY_COM 0x000
/* u3/pcie/sata phy banks */
#define SSUSB_SIFSLV_V1_U3PHYD 0x000
#define SSUSB_SIFSLV_V1_U3PHYA 0x200
/* version V2 sub-banks offset base address */
/* u2 phy banks */
#define SSUSB_SIFSLV_V2_MISC 0x000
#define SSUSB_SIFSLV_V2_U2FREQ 0x100
#define SSUSB_SIFSLV_V2_U2PHY_COM 0x300
/* u3/pcie/sata phy banks */
#define SSUSB_SIFSLV_V2_SPLLC 0x000
#define SSUSB_SIFSLV_V2_CHIP 0x100
#define SSUSB_SIFSLV_V2_U3PHYD 0x200
#define SSUSB_SIFSLV_V2_U3PHYA 0x400
#define U3P_USBPHYACR0 0x000
#define PA0_RG_U2PLL_FORCE_ON BIT(15)
#define PA0_RG_USB20_INTR_EN BIT(5)
#define U3P_USBPHYACR1 0x004
#define PA1_RG_VRT_SEL GENMASK(14, 12)
#define PA1_RG_VRT_SEL_VAL(x) ((0x7 & (x)) << 12)
#define PA1_RG_TERM_SEL GENMASK(10, 8)
#define PA1_RG_TERM_SEL_VAL(x) ((0x7 & (x)) << 8)
#define U3P_USBPHYACR2 0x008
#define PA2_RG_SIF_U2PLL_FORCE_EN BIT(18)
#define U3P_USBPHYACR5 0x014
#define PA5_RG_U2_HSTX_SRCAL_EN BIT(15)
#define PA5_RG_U2_HSTX_SRCTRL GENMASK(14, 12)
#define PA5_RG_U2_HSTX_SRCTRL_VAL(x) ((0x7 & (x)) << 12)
#define PA5_RG_U2_HS_100U_U3_EN BIT(11)
#define U3P_USBPHYACR6 0x018
#define PA6_RG_U2_BC11_SW_EN BIT(23)
#define PA6_RG_U2_OTG_VBUSCMP_EN BIT(20)
#define PA6_RG_U2_SQTH GENMASK(3, 0)
#define PA6_RG_U2_SQTH_VAL(x) (0xf & (x))
#define U3P_U2PHYACR4 0x020
#define P2C_RG_USB20_GPIO_CTL BIT(9)
#define P2C_USB20_GPIO_MODE BIT(8)
#define P2C_U2_GPIO_CTR_MSK (P2C_RG_USB20_GPIO_CTL | P2C_USB20_GPIO_MODE)
#define U3D_U2PHYDCR0 0x060
#define P2C_RG_SIF_U2PLL_FORCE_ON BIT(24)
#define U3P_U2PHYDTM0 0x068
#define P2C_FORCE_UART_EN BIT(26)
#define P2C_FORCE_DATAIN BIT(23)
#define P2C_FORCE_DM_PULLDOWN BIT(21)
#define P2C_FORCE_DP_PULLDOWN BIT(20)
#define P2C_FORCE_XCVRSEL BIT(19)
#define P2C_FORCE_SUSPENDM BIT(18)
#define P2C_FORCE_TERMSEL BIT(17)
#define P2C_RG_DATAIN GENMASK(13, 10)
#define P2C_RG_DATAIN_VAL(x) ((0xf & (x)) << 10)
#define P2C_RG_DMPULLDOWN BIT(7)
#define P2C_RG_DPPULLDOWN BIT(6)
#define P2C_RG_XCVRSEL GENMASK(5, 4)
#define P2C_RG_XCVRSEL_VAL(x) ((0x3 & (x)) << 4)
#define P2C_RG_SUSPENDM BIT(3)
#define P2C_RG_TERMSEL BIT(2)
#define P2C_DTM0_PART_MASK \
(P2C_FORCE_DATAIN | P2C_FORCE_DM_PULLDOWN | \
P2C_FORCE_DP_PULLDOWN | P2C_FORCE_XCVRSEL | \
P2C_FORCE_TERMSEL | P2C_RG_DMPULLDOWN | \
P2C_RG_DPPULLDOWN | P2C_RG_TERMSEL)
#define U3P_U2PHYDTM1 0x06C
#define P2C_RG_UART_EN BIT(16)
#define P2C_FORCE_IDDIG BIT(9)
#define P2C_RG_VBUSVALID BIT(5)
#define P2C_RG_SESSEND BIT(4)
#define P2C_RG_AVALID BIT(2)
#define P2C_RG_IDDIG BIT(1)
#define U3P_U2PHYBC12C 0x080
#define P2C_RG_CHGDT_EN BIT(0)
#define U3P_U3_CHIP_GPIO_CTLD 0x0c
#define P3C_REG_IP_SW_RST BIT(31)
#define P3C_MCU_BUS_CK_GATE_EN BIT(30)
#define P3C_FORCE_IP_SW_RST BIT(29)
#define U3P_U3_CHIP_GPIO_CTLE 0x10
#define P3C_RG_SWRST_U3_PHYD BIT(25)
#define P3C_RG_SWRST_U3_PHYD_FORCE_EN BIT(24)
#define U3P_U3_PHYA_REG0 0x000
#define P3A_RG_CLKDRV_OFF GENMASK(3, 2)
#define P3A_RG_CLKDRV_OFF_VAL(x) ((0x3 & (x)) << 2)
#define U3P_U3_PHYA_REG1 0x004
#define P3A_RG_CLKDRV_AMP GENMASK(31, 29)
#define P3A_RG_CLKDRV_AMP_VAL(x) ((0x7 & (x)) << 29)
#define U3P_U3_PHYA_REG6 0x018
#define P3A_RG_TX_EIDLE_CM GENMASK(31, 28)
#define P3A_RG_TX_EIDLE_CM_VAL(x) ((0xf & (x)) << 28)
#define U3P_U3_PHYA_REG9 0x024
#define P3A_RG_RX_DAC_MUX GENMASK(5, 1)
#define P3A_RG_RX_DAC_MUX_VAL(x) ((0x1f & (x)) << 1)
#define U3P_U3_PHYA_DA_REG0 0x100
#define P3A_RG_XTAL_EXT_PE2H GENMASK(17, 16)
#define P3A_RG_XTAL_EXT_PE2H_VAL(x) ((0x3 & (x)) << 16)
#define P3A_RG_XTAL_EXT_PE1H GENMASK(13, 12)
#define P3A_RG_XTAL_EXT_PE1H_VAL(x) ((0x3 & (x)) << 12)
#define P3A_RG_XTAL_EXT_EN_U3 GENMASK(11, 10)
#define P3A_RG_XTAL_EXT_EN_U3_VAL(x) ((0x3 & (x)) << 10)
#define U3P_U3_PHYA_DA_REG4 0x108
#define P3A_RG_PLL_DIVEN_PE2H GENMASK(21, 19)
#define P3A_RG_PLL_BC_PE2H GENMASK(7, 6)
#define P3A_RG_PLL_BC_PE2H_VAL(x) ((0x3 & (x)) << 6)
#define U3P_U3_PHYA_DA_REG5 0x10c
#define P3A_RG_PLL_BR_PE2H GENMASK(29, 28)
#define P3A_RG_PLL_BR_PE2H_VAL(x) ((0x3 & (x)) << 28)
#define P3A_RG_PLL_IC_PE2H GENMASK(15, 12)
#define P3A_RG_PLL_IC_PE2H_VAL(x) ((0xf & (x)) << 12)
#define U3P_U3_PHYA_DA_REG6 0x110
#define P3A_RG_PLL_IR_PE2H GENMASK(19, 16)
#define P3A_RG_PLL_IR_PE2H_VAL(x) ((0xf & (x)) << 16)
#define U3P_U3_PHYA_DA_REG7 0x114
#define P3A_RG_PLL_BP_PE2H GENMASK(19, 16)
#define P3A_RG_PLL_BP_PE2H_VAL(x) ((0xf & (x)) << 16)
#define U3P_U3_PHYA_DA_REG20 0x13c
#define P3A_RG_PLL_DELTA1_PE2H GENMASK(31, 16)
#define P3A_RG_PLL_DELTA1_PE2H_VAL(x) ((0xffff & (x)) << 16)
#define U3P_U3_PHYA_DA_REG25 0x148
#define P3A_RG_PLL_DELTA_PE2H GENMASK(15, 0)
#define P3A_RG_PLL_DELTA_PE2H_VAL(x) (0xffff & (x))
#define U3P_U3_PHYD_LFPS1 0x00c
#define P3D_RG_FWAKE_TH GENMASK(21, 16)
#define P3D_RG_FWAKE_TH_VAL(x) ((0x3f & (x)) << 16)
#define U3P_U3_PHYD_CDR1 0x05c
#define P3D_RG_CDR_BIR_LTD1 GENMASK(28, 24)
#define P3D_RG_CDR_BIR_LTD1_VAL(x) ((0x1f & (x)) << 24)
#define P3D_RG_CDR_BIR_LTD0 GENMASK(12, 8)
#define P3D_RG_CDR_BIR_LTD0_VAL(x) ((0x1f & (x)) << 8)
#define U3P_U3_PHYD_RXDET1 0x128
#define P3D_RG_RXDET_STB2_SET GENMASK(17, 9)
#define P3D_RG_RXDET_STB2_SET_VAL(x) ((0x1ff & (x)) << 9)
#define U3P_U3_PHYD_RXDET2 0x12c
#define P3D_RG_RXDET_STB2_SET_P3 GENMASK(8, 0)
#define P3D_RG_RXDET_STB2_SET_P3_VAL(x) (0x1ff & (x))
#define U3P_SPLLC_XTALCTL3 0x018
#define XC3_RG_U3_XTAL_RX_PWD BIT(9)
#define XC3_RG_U3_FRC_XTAL_RX_PWD BIT(8)
#define U3P_U2FREQ_FMCR0 0x00
#define P2F_RG_MONCLK_SEL GENMASK(27, 26)
#define P2F_RG_MONCLK_SEL_VAL(x) ((0x3 & (x)) << 26)
#define P2F_RG_FREQDET_EN BIT(24)
#define P2F_RG_CYCLECNT GENMASK(23, 0)
#define P2F_RG_CYCLECNT_VAL(x) ((P2F_RG_CYCLECNT) & (x))
#define U3P_U2FREQ_VALUE 0x0c
#define U3P_U2FREQ_FMMONR1 0x10
#define P2F_USB_FM_VALID BIT(0)
#define P2F_RG_FRCK_EN BIT(8)
#define U3P_REF_CLK 26 /* MHZ */
#define U3P_SLEW_RATE_COEF 28
#define U3P_SR_COEF_DIVISOR 1000
#define U3P_FM_DET_CYCLE_CNT 1024
/* SATA register setting */
#define PHYD_CTRL_SIGNAL_MODE4 0x1c
/* CDR Charge Pump P-path current adjustment */
#define RG_CDR_BICLTD1_GEN1_MSK GENMASK(23, 20)
#define RG_CDR_BICLTD1_GEN1_VAL(x) ((0xf & (x)) << 20)
#define RG_CDR_BICLTD0_GEN1_MSK GENMASK(11, 8)
#define RG_CDR_BICLTD0_GEN1_VAL(x) ((0xf & (x)) << 8)
#define PHYD_DESIGN_OPTION2 0x24
/* Symbol lock count selection */
#define RG_LOCK_CNT_SEL_MSK GENMASK(5, 4)
#define RG_LOCK_CNT_SEL_VAL(x) ((0x3 & (x)) << 4)
#define PHYD_DESIGN_OPTION9 0x40
/* COMWAK GAP width window */
#define RG_TG_MAX_MSK GENMASK(20, 16)
#define RG_TG_MAX_VAL(x) ((0x1f & (x)) << 16)
/* COMINIT GAP width window */
#define RG_T2_MAX_MSK GENMASK(13, 8)
#define RG_T2_MAX_VAL(x) ((0x3f & (x)) << 8)
/* COMWAK GAP width window */
#define RG_TG_MIN_MSK GENMASK(7, 5)
#define RG_TG_MIN_VAL(x) ((0x7 & (x)) << 5)
/* COMINIT GAP width window */
#define RG_T2_MIN_MSK GENMASK(4, 0)
#define RG_T2_MIN_VAL(x) (0x1f & (x))
#define ANA_RG_CTRL_SIGNAL1 0x4c
/* TX driver tail current control for 0dB de-empahsis mdoe for Gen1 speed */
#define RG_IDRV_0DB_GEN1_MSK GENMASK(13, 8)
#define RG_IDRV_0DB_GEN1_VAL(x) ((0x3f & (x)) << 8)
#define ANA_RG_CTRL_SIGNAL4 0x58
#define RG_CDR_BICLTR_GEN1_MSK GENMASK(23, 20)
#define RG_CDR_BICLTR_GEN1_VAL(x) ((0xf & (x)) << 20)
/* Loop filter R1 resistance adjustment for Gen1 speed */
#define RG_CDR_BR_GEN2_MSK GENMASK(10, 8)
#define RG_CDR_BR_GEN2_VAL(x) ((0x7 & (x)) << 8)
#define ANA_RG_CTRL_SIGNAL6 0x60
/* I-path capacitance adjustment for Gen1 */
#define RG_CDR_BC_GEN1_MSK GENMASK(28, 24)
#define RG_CDR_BC_GEN1_VAL(x) ((0x1f & (x)) << 24)
#define RG_CDR_BIRLTR_GEN1_MSK GENMASK(4, 0)
#define RG_CDR_BIRLTR_GEN1_VAL(x) (0x1f & (x))
#define ANA_EQ_EYE_CTRL_SIGNAL1 0x6c
/* RX Gen1 LEQ tuning step */
#define RG_EQ_DLEQ_LFI_GEN1_MSK GENMASK(11, 8)
#define RG_EQ_DLEQ_LFI_GEN1_VAL(x) ((0xf & (x)) << 8)
#define ANA_EQ_EYE_CTRL_SIGNAL4 0xd8
#define RG_CDR_BIRLTD0_GEN1_MSK GENMASK(20, 16)
#define RG_CDR_BIRLTD0_GEN1_VAL(x) ((0x1f & (x)) << 16)
#define ANA_EQ_EYE_CTRL_SIGNAL5 0xdc
#define RG_CDR_BIRLTD0_GEN3_MSK GENMASK(4, 0)
#define RG_CDR_BIRLTD0_GEN3_VAL(x) (0x1f & (x))
enum mtk_phy_version {
MTK_PHY_V1 = 1,
MTK_PHY_V2,
};
struct mtk_phy_pdata {
/* avoid RX sensitivity level degradation only for mt8173 */
bool avoid_rx_sen_degradation;
enum mtk_phy_version version;
};
struct u2phy_banks {
void __iomem *misc;
void __iomem *fmreg;
void __iomem *com;
};
struct u3phy_banks {
void __iomem *spllc;
void __iomem *chip;
void __iomem *phyd; /* include u3phyd_bank2 */
void __iomem *phya; /* include u3phya_da */
};
struct mtk_phy_instance {
struct phy *phy;
void __iomem *port_base;
union {
struct u2phy_banks u2_banks;
struct u3phy_banks u3_banks;
};
struct clk *ref_clk; /* reference clock of anolog phy */
u32 index;
u8 type;
int eye_src;
int eye_vrt;
int eye_term;
bool bc12_en;
};
struct mtk_tphy {
struct device *dev;
void __iomem *sif_base; /* only shared sif */
/* deprecated, use @ref_clk instead in phy instance */
struct clk *u3phya_ref; /* reference clock of usb3 anolog phy */
const struct mtk_phy_pdata *pdata;
struct mtk_phy_instance **phys;
int nphys;
int src_ref_clk; /* MHZ, reference clock for slew rate calibrate */
int src_coef; /* coefficient for slew rate calibrate */
};
static void hs_slew_rate_calibrate(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
void __iomem *fmreg = u2_banks->fmreg;
void __iomem *com = u2_banks->com;
int calibration_val;
int fm_out;
u32 tmp;
/* use force value */
if (instance->eye_src)
return;
/* enable USB ring oscillator */
tmp = readl(com + U3P_USBPHYACR5);
tmp |= PA5_RG_U2_HSTX_SRCAL_EN;
writel(tmp, com + U3P_USBPHYACR5);
udelay(1);
/*enable free run clock */
tmp = readl(fmreg + U3P_U2FREQ_FMMONR1);
tmp |= P2F_RG_FRCK_EN;
writel(tmp, fmreg + U3P_U2FREQ_FMMONR1);
/* set cycle count as 1024, and select u2 channel */
tmp = readl(fmreg + U3P_U2FREQ_FMCR0);
tmp &= ~(P2F_RG_CYCLECNT | P2F_RG_MONCLK_SEL);
tmp |= P2F_RG_CYCLECNT_VAL(U3P_FM_DET_CYCLE_CNT);
if (tphy->pdata->version == MTK_PHY_V1)
tmp |= P2F_RG_MONCLK_SEL_VAL(instance->index >> 1);
writel(tmp, fmreg + U3P_U2FREQ_FMCR0);
/* enable frequency meter */
tmp = readl(fmreg + U3P_U2FREQ_FMCR0);
tmp |= P2F_RG_FREQDET_EN;
writel(tmp, fmreg + U3P_U2FREQ_FMCR0);
/* ignore return value */
readl_poll_timeout(fmreg + U3P_U2FREQ_FMMONR1, tmp,
(tmp & P2F_USB_FM_VALID), 10, 200);
fm_out = readl(fmreg + U3P_U2FREQ_VALUE);
/* disable frequency meter */
tmp = readl(fmreg + U3P_U2FREQ_FMCR0);
tmp &= ~P2F_RG_FREQDET_EN;
writel(tmp, fmreg + U3P_U2FREQ_FMCR0);
/*disable free run clock */
tmp = readl(fmreg + U3P_U2FREQ_FMMONR1);
tmp &= ~P2F_RG_FRCK_EN;
writel(tmp, fmreg + U3P_U2FREQ_FMMONR1);
if (fm_out) {
/* ( 1024 / FM_OUT ) x reference clock frequency x coef */
tmp = tphy->src_ref_clk * tphy->src_coef;
tmp = (tmp * U3P_FM_DET_CYCLE_CNT) / fm_out;
calibration_val = DIV_ROUND_CLOSEST(tmp, U3P_SR_COEF_DIVISOR);
} else {
/* if FM detection fail, set default value */
calibration_val = 4;
}
dev_dbg(tphy->dev, "phy:%d, fm_out:%d, calib:%d (clk:%d, coef:%d)\n",
instance->index, fm_out, calibration_val,
tphy->src_ref_clk, tphy->src_coef);
/* set HS slew rate */
tmp = readl(com + U3P_USBPHYACR5);
tmp &= ~PA5_RG_U2_HSTX_SRCTRL;
tmp |= PA5_RG_U2_HSTX_SRCTRL_VAL(calibration_val);
writel(tmp, com + U3P_USBPHYACR5);
/* disable USB ring oscillator */
tmp = readl(com + U3P_USBPHYACR5);
tmp &= ~PA5_RG_U2_HSTX_SRCAL_EN;
writel(tmp, com + U3P_USBPHYACR5);
}
static void u3_phy_instance_init(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u3phy_banks *u3_banks = &instance->u3_banks;
u32 tmp;
/* gating PCIe Analog XTAL clock */
tmp = readl(u3_banks->spllc + U3P_SPLLC_XTALCTL3);
tmp |= XC3_RG_U3_XTAL_RX_PWD | XC3_RG_U3_FRC_XTAL_RX_PWD;
writel(tmp, u3_banks->spllc + U3P_SPLLC_XTALCTL3);
/* gating XSQ */
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG0);
tmp &= ~P3A_RG_XTAL_EXT_EN_U3;
tmp |= P3A_RG_XTAL_EXT_EN_U3_VAL(2);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG0);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_REG9);
tmp &= ~P3A_RG_RX_DAC_MUX;
tmp |= P3A_RG_RX_DAC_MUX_VAL(4);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_REG9);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_REG6);
tmp &= ~P3A_RG_TX_EIDLE_CM;
tmp |= P3A_RG_TX_EIDLE_CM_VAL(0xe);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_REG6);
tmp = readl(u3_banks->phyd + U3P_U3_PHYD_CDR1);
tmp &= ~(P3D_RG_CDR_BIR_LTD0 | P3D_RG_CDR_BIR_LTD1);
tmp |= P3D_RG_CDR_BIR_LTD0_VAL(0xc) | P3D_RG_CDR_BIR_LTD1_VAL(0x3);
writel(tmp, u3_banks->phyd + U3P_U3_PHYD_CDR1);
tmp = readl(u3_banks->phyd + U3P_U3_PHYD_LFPS1);
tmp &= ~P3D_RG_FWAKE_TH;
tmp |= P3D_RG_FWAKE_TH_VAL(0x34);
writel(tmp, u3_banks->phyd + U3P_U3_PHYD_LFPS1);
tmp = readl(u3_banks->phyd + U3P_U3_PHYD_RXDET1);
tmp &= ~P3D_RG_RXDET_STB2_SET;
tmp |= P3D_RG_RXDET_STB2_SET_VAL(0x10);
writel(tmp, u3_banks->phyd + U3P_U3_PHYD_RXDET1);
tmp = readl(u3_banks->phyd + U3P_U3_PHYD_RXDET2);
tmp &= ~P3D_RG_RXDET_STB2_SET_P3;
tmp |= P3D_RG_RXDET_STB2_SET_P3_VAL(0x10);
writel(tmp, u3_banks->phyd + U3P_U3_PHYD_RXDET2);
dev_dbg(tphy->dev, "%s(%d)\n", __func__, instance->index);
}
static void u2_phy_instance_init(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
void __iomem *com = u2_banks->com;
u32 index = instance->index;
u32 tmp;
/* switch to USB function, and enable usb pll */
tmp = readl(com + U3P_U2PHYDTM0);
tmp &= ~(P2C_FORCE_UART_EN | P2C_FORCE_SUSPENDM);
tmp |= P2C_RG_XCVRSEL_VAL(1) | P2C_RG_DATAIN_VAL(0);
writel(tmp, com + U3P_U2PHYDTM0);
tmp = readl(com + U3P_U2PHYDTM1);
tmp &= ~P2C_RG_UART_EN;
writel(tmp, com + U3P_U2PHYDTM1);
tmp = readl(com + U3P_USBPHYACR0);
tmp |= PA0_RG_USB20_INTR_EN;
writel(tmp, com + U3P_USBPHYACR0);
/* disable switch 100uA current to SSUSB */
tmp = readl(com + U3P_USBPHYACR5);
tmp &= ~PA5_RG_U2_HS_100U_U3_EN;
writel(tmp, com + U3P_USBPHYACR5);
if (!index) {
tmp = readl(com + U3P_U2PHYACR4);
tmp &= ~P2C_U2_GPIO_CTR_MSK;
writel(tmp, com + U3P_U2PHYACR4);
}
if (tphy->pdata->avoid_rx_sen_degradation) {
if (!index) {
tmp = readl(com + U3P_USBPHYACR2);
tmp |= PA2_RG_SIF_U2PLL_FORCE_EN;
writel(tmp, com + U3P_USBPHYACR2);
tmp = readl(com + U3D_U2PHYDCR0);
tmp &= ~P2C_RG_SIF_U2PLL_FORCE_ON;
writel(tmp, com + U3D_U2PHYDCR0);
} else {
tmp = readl(com + U3D_U2PHYDCR0);
tmp |= P2C_RG_SIF_U2PLL_FORCE_ON;
writel(tmp, com + U3D_U2PHYDCR0);
tmp = readl(com + U3P_U2PHYDTM0);
tmp |= P2C_RG_SUSPENDM | P2C_FORCE_SUSPENDM;
writel(tmp, com + U3P_U2PHYDTM0);
}
}
tmp = readl(com + U3P_USBPHYACR6);
tmp &= ~PA6_RG_U2_BC11_SW_EN; /* DP/DM BC1.1 path Disable */
tmp &= ~PA6_RG_U2_SQTH;
tmp |= PA6_RG_U2_SQTH_VAL(2);
writel(tmp, com + U3P_USBPHYACR6);
dev_dbg(tphy->dev, "%s(%d)\n", __func__, index);
}
static void u2_phy_instance_power_on(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
void __iomem *com = u2_banks->com;
u32 index = instance->index;
u32 tmp;
tmp = readl(com + U3P_U2PHYDTM0);
tmp &= ~(P2C_RG_XCVRSEL | P2C_RG_DATAIN | P2C_DTM0_PART_MASK);
writel(tmp, com + U3P_U2PHYDTM0);
/* OTG Enable */
tmp = readl(com + U3P_USBPHYACR6);
tmp |= PA6_RG_U2_OTG_VBUSCMP_EN;
writel(tmp, com + U3P_USBPHYACR6);
tmp = readl(com + U3P_U2PHYDTM1);
tmp |= P2C_RG_VBUSVALID | P2C_RG_AVALID;
tmp &= ~P2C_RG_SESSEND;
writel(tmp, com + U3P_U2PHYDTM1);
if (tphy->pdata->avoid_rx_sen_degradation && index) {
tmp = readl(com + U3D_U2PHYDCR0);
tmp |= P2C_RG_SIF_U2PLL_FORCE_ON;
writel(tmp, com + U3D_U2PHYDCR0);
tmp = readl(com + U3P_U2PHYDTM0);
tmp |= P2C_RG_SUSPENDM | P2C_FORCE_SUSPENDM;
writel(tmp, com + U3P_U2PHYDTM0);
}
dev_dbg(tphy->dev, "%s(%d)\n", __func__, index);
}
static void u2_phy_instance_power_off(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
void __iomem *com = u2_banks->com;
u32 index = instance->index;
u32 tmp;
tmp = readl(com + U3P_U2PHYDTM0);
tmp &= ~(P2C_RG_XCVRSEL | P2C_RG_DATAIN);
writel(tmp, com + U3P_U2PHYDTM0);
/* OTG Disable */
tmp = readl(com + U3P_USBPHYACR6);
tmp &= ~PA6_RG_U2_OTG_VBUSCMP_EN;
writel(tmp, com + U3P_USBPHYACR6);
tmp = readl(com + U3P_U2PHYDTM1);
tmp &= ~(P2C_RG_VBUSVALID | P2C_RG_AVALID);
tmp |= P2C_RG_SESSEND;
writel(tmp, com + U3P_U2PHYDTM1);
if (tphy->pdata->avoid_rx_sen_degradation && index) {
tmp = readl(com + U3P_U2PHYDTM0);
tmp &= ~(P2C_RG_SUSPENDM | P2C_FORCE_SUSPENDM);
writel(tmp, com + U3P_U2PHYDTM0);
tmp = readl(com + U3D_U2PHYDCR0);
tmp &= ~P2C_RG_SIF_U2PLL_FORCE_ON;
writel(tmp, com + U3D_U2PHYDCR0);
}
dev_dbg(tphy->dev, "%s(%d)\n", __func__, index);
}
static void u2_phy_instance_exit(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
void __iomem *com = u2_banks->com;
u32 index = instance->index;
u32 tmp;
if (tphy->pdata->avoid_rx_sen_degradation && index) {
tmp = readl(com + U3D_U2PHYDCR0);
tmp &= ~P2C_RG_SIF_U2PLL_FORCE_ON;
writel(tmp, com + U3D_U2PHYDCR0);
tmp = readl(com + U3P_U2PHYDTM0);
tmp &= ~P2C_FORCE_SUSPENDM;
writel(tmp, com + U3P_U2PHYDTM0);
}
}
static void u2_phy_instance_set_mode(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance,
enum phy_mode mode)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
u32 tmp;
tmp = readl(u2_banks->com + U3P_U2PHYDTM1);
switch (mode) {
case PHY_MODE_USB_DEVICE:
tmp |= P2C_FORCE_IDDIG | P2C_RG_IDDIG;
break;
case PHY_MODE_USB_HOST:
tmp |= P2C_FORCE_IDDIG;
tmp &= ~P2C_RG_IDDIG;
break;
case PHY_MODE_USB_OTG:
tmp &= ~(P2C_FORCE_IDDIG | P2C_RG_IDDIG);
break;
default:
return;
}
writel(tmp, u2_banks->com + U3P_U2PHYDTM1);
}
static void pcie_phy_instance_init(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u3phy_banks *u3_banks = &instance->u3_banks;
u32 tmp;
if (tphy->pdata->version != MTK_PHY_V1)
return;
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG0);
tmp &= ~(P3A_RG_XTAL_EXT_PE1H | P3A_RG_XTAL_EXT_PE2H);
tmp |= P3A_RG_XTAL_EXT_PE1H_VAL(0x2) | P3A_RG_XTAL_EXT_PE2H_VAL(0x2);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG0);
/* ref clk drive */
tmp = readl(u3_banks->phya + U3P_U3_PHYA_REG1);
tmp &= ~P3A_RG_CLKDRV_AMP;
tmp |= P3A_RG_CLKDRV_AMP_VAL(0x4);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_REG1);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_REG0);
tmp &= ~P3A_RG_CLKDRV_OFF;
tmp |= P3A_RG_CLKDRV_OFF_VAL(0x1);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_REG0);
/* SSC delta -5000ppm */
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG20);
tmp &= ~P3A_RG_PLL_DELTA1_PE2H;
tmp |= P3A_RG_PLL_DELTA1_PE2H_VAL(0x3c);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG20);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG25);
tmp &= ~P3A_RG_PLL_DELTA_PE2H;
tmp |= P3A_RG_PLL_DELTA_PE2H_VAL(0x36);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG25);
/* change pll BW 0.6M */
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG5);
tmp &= ~(P3A_RG_PLL_BR_PE2H | P3A_RG_PLL_IC_PE2H);
tmp |= P3A_RG_PLL_BR_PE2H_VAL(0x1) | P3A_RG_PLL_IC_PE2H_VAL(0x1);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG5);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG4);
tmp &= ~(P3A_RG_PLL_DIVEN_PE2H | P3A_RG_PLL_BC_PE2H);
tmp |= P3A_RG_PLL_BC_PE2H_VAL(0x3);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG4);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG6);
tmp &= ~P3A_RG_PLL_IR_PE2H;
tmp |= P3A_RG_PLL_IR_PE2H_VAL(0x2);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG6);
tmp = readl(u3_banks->phya + U3P_U3_PHYA_DA_REG7);
tmp &= ~P3A_RG_PLL_BP_PE2H;
tmp |= P3A_RG_PLL_BP_PE2H_VAL(0xa);
writel(tmp, u3_banks->phya + U3P_U3_PHYA_DA_REG7);
/* Tx Detect Rx Timing: 10us -> 5us */
tmp = readl(u3_banks->phyd + U3P_U3_PHYD_RXDET1);
tmp &= ~P3D_RG_RXDET_STB2_SET;
tmp |= P3D_RG_RXDET_STB2_SET_VAL(0x10);
writel(tmp, u3_banks->phyd + U3P_U3_PHYD_RXDET1);
tmp = readl(u3_banks->phyd + U3P_U3_PHYD_RXDET2);
tmp &= ~P3D_RG_RXDET_STB2_SET_P3;
tmp |= P3D_RG_RXDET_STB2_SET_P3_VAL(0x10);
writel(tmp, u3_banks->phyd + U3P_U3_PHYD_RXDET2);
/* wait for PCIe subsys register to active */
usleep_range(2500, 3000);
dev_dbg(tphy->dev, "%s(%d)\n", __func__, instance->index);
}
static void pcie_phy_instance_power_on(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u3phy_banks *bank = &instance->u3_banks;
u32 tmp;
tmp = readl(bank->chip + U3P_U3_CHIP_GPIO_CTLD);
tmp &= ~(P3C_FORCE_IP_SW_RST | P3C_REG_IP_SW_RST);
writel(tmp, bank->chip + U3P_U3_CHIP_GPIO_CTLD);
tmp = readl(bank->chip + U3P_U3_CHIP_GPIO_CTLE);
tmp &= ~(P3C_RG_SWRST_U3_PHYD_FORCE_EN | P3C_RG_SWRST_U3_PHYD);
writel(tmp, bank->chip + U3P_U3_CHIP_GPIO_CTLE);
}
static void pcie_phy_instance_power_off(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u3phy_banks *bank = &instance->u3_banks;
u32 tmp;
tmp = readl(bank->chip + U3P_U3_CHIP_GPIO_CTLD);
tmp |= P3C_FORCE_IP_SW_RST | P3C_REG_IP_SW_RST;
writel(tmp, bank->chip + U3P_U3_CHIP_GPIO_CTLD);
tmp = readl(bank->chip + U3P_U3_CHIP_GPIO_CTLE);
tmp |= P3C_RG_SWRST_U3_PHYD_FORCE_EN | P3C_RG_SWRST_U3_PHYD;
writel(tmp, bank->chip + U3P_U3_CHIP_GPIO_CTLE);
}
static void sata_phy_instance_init(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u3phy_banks *u3_banks = &instance->u3_banks;
void __iomem *phyd = u3_banks->phyd;
u32 tmp;
/* charge current adjustment */
tmp = readl(phyd + ANA_RG_CTRL_SIGNAL6);
tmp &= ~(RG_CDR_BIRLTR_GEN1_MSK | RG_CDR_BC_GEN1_MSK);
tmp |= RG_CDR_BIRLTR_GEN1_VAL(0x6) | RG_CDR_BC_GEN1_VAL(0x1a);
writel(tmp, phyd + ANA_RG_CTRL_SIGNAL6);
tmp = readl(phyd + ANA_EQ_EYE_CTRL_SIGNAL4);
tmp &= ~RG_CDR_BIRLTD0_GEN1_MSK;
tmp |= RG_CDR_BIRLTD0_GEN1_VAL(0x18);
writel(tmp, phyd + ANA_EQ_EYE_CTRL_SIGNAL4);
tmp = readl(phyd + ANA_EQ_EYE_CTRL_SIGNAL5);
tmp &= ~RG_CDR_BIRLTD0_GEN3_MSK;
tmp |= RG_CDR_BIRLTD0_GEN3_VAL(0x06);
writel(tmp, phyd + ANA_EQ_EYE_CTRL_SIGNAL5);
tmp = readl(phyd + ANA_RG_CTRL_SIGNAL4);
tmp &= ~(RG_CDR_BICLTR_GEN1_MSK | RG_CDR_BR_GEN2_MSK);
tmp |= RG_CDR_BICLTR_GEN1_VAL(0x0c) | RG_CDR_BR_GEN2_VAL(0x07);
writel(tmp, phyd + ANA_RG_CTRL_SIGNAL4);
tmp = readl(phyd + PHYD_CTRL_SIGNAL_MODE4);
tmp &= ~(RG_CDR_BICLTD0_GEN1_MSK | RG_CDR_BICLTD1_GEN1_MSK);
tmp |= RG_CDR_BICLTD0_GEN1_VAL(0x08) | RG_CDR_BICLTD1_GEN1_VAL(0x02);
writel(tmp, phyd + PHYD_CTRL_SIGNAL_MODE4);
tmp = readl(phyd + PHYD_DESIGN_OPTION2);
tmp &= ~RG_LOCK_CNT_SEL_MSK;
tmp |= RG_LOCK_CNT_SEL_VAL(0x02);
writel(tmp, phyd + PHYD_DESIGN_OPTION2);
tmp = readl(phyd + PHYD_DESIGN_OPTION9);
tmp &= ~(RG_T2_MIN_MSK | RG_TG_MIN_MSK |
RG_T2_MAX_MSK | RG_TG_MAX_MSK);
tmp |= RG_T2_MIN_VAL(0x12) | RG_TG_MIN_VAL(0x04) |
RG_T2_MAX_VAL(0x31) | RG_TG_MAX_VAL(0x0e);
writel(tmp, phyd + PHYD_DESIGN_OPTION9);
tmp = readl(phyd + ANA_RG_CTRL_SIGNAL1);
tmp &= ~RG_IDRV_0DB_GEN1_MSK;
tmp |= RG_IDRV_0DB_GEN1_VAL(0x20);
writel(tmp, phyd + ANA_RG_CTRL_SIGNAL1);
tmp = readl(phyd + ANA_EQ_EYE_CTRL_SIGNAL1);
tmp &= ~RG_EQ_DLEQ_LFI_GEN1_MSK;
tmp |= RG_EQ_DLEQ_LFI_GEN1_VAL(0x03);
writel(tmp, phyd + ANA_EQ_EYE_CTRL_SIGNAL1);
dev_dbg(tphy->dev, "%s(%d)\n", __func__, instance->index);
}
static void phy_v1_banks_init(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
struct u3phy_banks *u3_banks = &instance->u3_banks;
switch (instance->type) {
case PHY_TYPE_USB2:
u2_banks->misc = NULL;
u2_banks->fmreg = tphy->sif_base + SSUSB_SIFSLV_V1_U2FREQ;
u2_banks->com = instance->port_base + SSUSB_SIFSLV_V1_U2PHY_COM;
break;
case PHY_TYPE_USB3:
case PHY_TYPE_PCIE:
u3_banks->spllc = tphy->sif_base + SSUSB_SIFSLV_V1_SPLLC;
u3_banks->chip = tphy->sif_base + SSUSB_SIFSLV_V1_CHIP;
u3_banks->phyd = instance->port_base + SSUSB_SIFSLV_V1_U3PHYD;
u3_banks->phya = instance->port_base + SSUSB_SIFSLV_V1_U3PHYA;
break;
case PHY_TYPE_SATA:
u3_banks->phyd = instance->port_base + SSUSB_SIFSLV_V1_U3PHYD;
break;
default:
dev_err(tphy->dev, "incompatible PHY type\n");
return;
}
}
static void phy_v2_banks_init(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
struct u3phy_banks *u3_banks = &instance->u3_banks;
switch (instance->type) {
case PHY_TYPE_USB2:
u2_banks->misc = instance->port_base + SSUSB_SIFSLV_V2_MISC;
u2_banks->fmreg = instance->port_base + SSUSB_SIFSLV_V2_U2FREQ;
u2_banks->com = instance->port_base + SSUSB_SIFSLV_V2_U2PHY_COM;
break;
case PHY_TYPE_USB3:
case PHY_TYPE_PCIE:
u3_banks->spllc = instance->port_base + SSUSB_SIFSLV_V2_SPLLC;
u3_banks->chip = instance->port_base + SSUSB_SIFSLV_V2_CHIP;
u3_banks->phyd = instance->port_base + SSUSB_SIFSLV_V2_U3PHYD;
u3_banks->phya = instance->port_base + SSUSB_SIFSLV_V2_U3PHYA;
break;
default:
dev_err(tphy->dev, "incompatible PHY type\n");
return;
}
}
static void phy_parse_property(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct device *dev = &instance->phy->dev;
if (instance->type != PHY_TYPE_USB2)
return;
instance->bc12_en = device_property_read_bool(dev, "mediatek,bc12");
device_property_read_u32(dev, "mediatek,eye-src",
&instance->eye_src);
device_property_read_u32(dev, "mediatek,eye-vrt",
&instance->eye_vrt);
device_property_read_u32(dev, "mediatek,eye-term",
&instance->eye_term);
dev_dbg(dev, "bc12:%d, src:%d, vrt:%d, term:%d\n",
instance->bc12_en, instance->eye_src,
instance->eye_vrt, instance->eye_term);
}
static void u2_phy_props_set(struct mtk_tphy *tphy,
struct mtk_phy_instance *instance)
{
struct u2phy_banks *u2_banks = &instance->u2_banks;
void __iomem *com = u2_banks->com;
u32 tmp;
if (instance->bc12_en) {
tmp = readl(com + U3P_U2PHYBC12C);
tmp |= P2C_RG_CHGDT_EN; /* BC1.2 path Enable */
writel(tmp, com + U3P_U2PHYBC12C);
}
if (instance->eye_src) {
tmp = readl(com + U3P_USBPHYACR5);
tmp &= ~PA5_RG_U2_HSTX_SRCTRL;
tmp |= PA5_RG_U2_HSTX_SRCTRL_VAL(instance->eye_src);
writel(tmp, com + U3P_USBPHYACR5);
}
if (instance->eye_vrt) {
tmp = readl(com + U3P_USBPHYACR1);
tmp &= ~PA1_RG_VRT_SEL;
tmp |= PA1_RG_VRT_SEL_VAL(instance->eye_vrt);
writel(tmp, com + U3P_USBPHYACR1);
}
if (instance->eye_term) {
tmp = readl(com + U3P_USBPHYACR1);
tmp &= ~PA1_RG_TERM_SEL;
tmp |= PA1_RG_TERM_SEL_VAL(instance->eye_term);
writel(tmp, com + U3P_USBPHYACR1);
}
}
static int mtk_phy_init(struct phy *phy)
{
struct mtk_phy_instance *instance = phy_get_drvdata(phy);
struct mtk_tphy *tphy = dev_get_drvdata(phy->dev.parent);
int ret;
ret = clk_prepare_enable(tphy->u3phya_ref);
if (ret) {
dev_err(tphy->dev, "failed to enable u3phya_ref\n");
return ret;
}
ret = clk_prepare_enable(instance->ref_clk);
if (ret) {
dev_err(tphy->dev, "failed to enable ref_clk\n");
return ret;
}
switch (instance->type) {
case PHY_TYPE_USB2:
u2_phy_instance_init(tphy, instance);
u2_phy_props_set(tphy, instance);
break;
case PHY_TYPE_USB3:
u3_phy_instance_init(tphy, instance);
break;
case PHY_TYPE_PCIE:
pcie_phy_instance_init(tphy, instance);
break;
case PHY_TYPE_SATA:
sata_phy_instance_init(tphy, instance);
break;
default:
dev_err(tphy->dev, "incompatible PHY type\n");
return -EINVAL;
}
return 0;
}
static int mtk_phy_power_on(struct phy *phy)
{
struct mtk_phy_instance *instance = phy_get_drvdata(phy);
struct mtk_tphy *tphy = dev_get_drvdata(phy->dev.parent);
if (instance->type == PHY_TYPE_USB2) {
u2_phy_instance_power_on(tphy, instance);
hs_slew_rate_calibrate(tphy, instance);
} else if (instance->type == PHY_TYPE_PCIE) {
pcie_phy_instance_power_on(tphy, instance);
}
return 0;
}
static int mtk_phy_power_off(struct phy *phy)
{
struct mtk_phy_instance *instance = phy_get_drvdata(phy);
struct mtk_tphy *tphy = dev_get_drvdata(phy->dev.parent);
if (instance->type == PHY_TYPE_USB2)
u2_phy_instance_power_off(tphy, instance);
else if (instance->type == PHY_TYPE_PCIE)
pcie_phy_instance_power_off(tphy, instance);
return 0;
}
static int mtk_phy_exit(struct phy *phy)
{
struct mtk_phy_instance *instance = phy_get_drvdata(phy);
struct mtk_tphy *tphy = dev_get_drvdata(phy->dev.parent);
if (instance->type == PHY_TYPE_USB2)
u2_phy_instance_exit(tphy, instance);
clk_disable_unprepare(instance->ref_clk);
clk_disable_unprepare(tphy->u3phya_ref);
return 0;
}
static int mtk_phy_set_mode(struct phy *phy, enum phy_mode mode)
{
struct mtk_phy_instance *instance = phy_get_drvdata(phy);
struct mtk_tphy *tphy = dev_get_drvdata(phy->dev.parent);
if (instance->type == PHY_TYPE_USB2)
u2_phy_instance_set_mode(tphy, instance, mode);
return 0;
}
static struct phy *mtk_phy_xlate(struct device *dev,
struct of_phandle_args *args)
{
struct mtk_tphy *tphy = dev_get_drvdata(dev);
struct mtk_phy_instance *instance = NULL;
struct device_node *phy_np = args->np;
int index;
if (args->args_count != 1) {
dev_err(dev, "invalid number of cells in 'phy' property\n");
return ERR_PTR(-EINVAL);
}
for (index = 0; index < tphy->nphys; index++)
if (phy_np == tphy->phys[index]->phy->dev.of_node) {
instance = tphy->phys[index];
break;
}
if (!instance) {
dev_err(dev, "failed to find appropriate phy\n");
return ERR_PTR(-EINVAL);
}
instance->type = args->args[0];
if (!(instance->type == PHY_TYPE_USB2 ||
instance->type == PHY_TYPE_USB3 ||
instance->type == PHY_TYPE_PCIE ||
instance->type == PHY_TYPE_SATA)) {
dev_err(dev, "unsupported device type: %d\n", instance->type);
return ERR_PTR(-EINVAL);
}
if (tphy->pdata->version == MTK_PHY_V1) {
phy_v1_banks_init(tphy, instance);
} else if (tphy->pdata->version == MTK_PHY_V2) {
phy_v2_banks_init(tphy, instance);
} else {
dev_err(dev, "phy version is not supported\n");
return ERR_PTR(-EINVAL);
}
phy_parse_property(tphy, instance);
return instance->phy;
}
static const struct phy_ops mtk_tphy_ops = {
.init = mtk_phy_init,
.exit = mtk_phy_exit,
.power_on = mtk_phy_power_on,
.power_off = mtk_phy_power_off,
.set_mode = mtk_phy_set_mode,
.owner = THIS_MODULE,
};
static const struct mtk_phy_pdata tphy_v1_pdata = {
.avoid_rx_sen_degradation = false,
.version = MTK_PHY_V1,
};
static const struct mtk_phy_pdata tphy_v2_pdata = {
.avoid_rx_sen_degradation = false,
.version = MTK_PHY_V2,
};
static const struct mtk_phy_pdata mt8173_pdata = {
.avoid_rx_sen_degradation = true,
.version = MTK_PHY_V1,
};
static const struct of_device_id mtk_tphy_id_table[] = {
{ .compatible = "mediatek,mt2701-u3phy", .data = &tphy_v1_pdata },
{ .compatible = "mediatek,mt2712-u3phy", .data = &tphy_v2_pdata },
{ .compatible = "mediatek,mt8173-u3phy", .data = &mt8173_pdata },
{ .compatible = "mediatek,generic-tphy-v1", .data = &tphy_v1_pdata },
{ .compatible = "mediatek,generic-tphy-v2", .data = &tphy_v2_pdata },
{ },
};
MODULE_DEVICE_TABLE(of, mtk_tphy_id_table);
static int mtk_tphy_probe(struct platform_device *pdev)
{
struct device *dev = &pdev->dev;
struct device_node *np = dev->of_node;
struct device_node *child_np;
struct phy_provider *provider;
struct resource *sif_res;
struct mtk_tphy *tphy;
struct resource res;
int port, retval;
tphy = devm_kzalloc(dev, sizeof(*tphy), GFP_KERNEL);
if (!tphy)
return -ENOMEM;
tphy->pdata = of_device_get_match_data(dev);
if (!tphy->pdata)
return -EINVAL;
tphy->nphys = of_get_child_count(np);
tphy->phys = devm_kcalloc(dev, tphy->nphys,
sizeof(*tphy->phys), GFP_KERNEL);
if (!tphy->phys)
return -ENOMEM;
tphy->dev = dev;
platform_set_drvdata(pdev, tphy);
sif_res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
/* SATA phy of V1 needn't it if not shared with PCIe or USB */
if (sif_res && tphy->pdata->version == MTK_PHY_V1) {
/* get banks shared by multiple phys */
tphy->sif_base = devm_ioremap_resource(dev, sif_res);
if (IS_ERR(tphy->sif_base)) {
dev_err(dev, "failed to remap sif regs\n");
return PTR_ERR(tphy->sif_base);
}
}
/* it's deprecated, make it optional for backward compatibility */
tphy->u3phya_ref = devm_clk_get(dev, "u3phya_ref");
if (IS_ERR(tphy->u3phya_ref)) {
if (PTR_ERR(tphy->u3phya_ref) == -EPROBE_DEFER)
return -EPROBE_DEFER;
tphy->u3phya_ref = NULL;
}
tphy->src_ref_clk = U3P_REF_CLK;
tphy->src_coef = U3P_SLEW_RATE_COEF;
/* update parameters of slew rate calibrate if exist */
device_property_read_u32(dev, "mediatek,src-ref-clk-mhz",
&tphy->src_ref_clk);
device_property_read_u32(dev, "mediatek,src-coef", &tphy->src_coef);
port = 0;
for_each_child_of_node(np, child_np) {
struct mtk_phy_instance *instance;
struct phy *phy;
instance = devm_kzalloc(dev, sizeof(*instance), GFP_KERNEL);
if (!instance) {
retval = -ENOMEM;
goto put_child;
}
tphy->phys[port] = instance;
phy = devm_phy_create(dev, child_np, &mtk_tphy_ops);
if (IS_ERR(phy)) {
dev_err(dev, "failed to create phy\n");
retval = PTR_ERR(phy);
goto put_child;
}
retval = of_address_to_resource(child_np, 0, &res);
if (retval) {
dev_err(dev, "failed to get address resource(id-%d)\n",
port);
goto put_child;
}
instance->port_base = devm_ioremap_resource(&phy->dev, &res);
if (IS_ERR(instance->port_base)) {
dev_err(dev, "failed to remap phy regs\n");
retval = PTR_ERR(instance->port_base);
goto put_child;
}
instance->phy = phy;
instance->index = port;
phy_set_drvdata(phy, instance);
port++;
/* if deprecated clock is provided, ignore instance's one */
if (tphy->u3phya_ref)
continue;
instance->ref_clk = devm_clk_get(&phy->dev, "ref");
if (IS_ERR(instance->ref_clk)) {
dev_err(dev, "failed to get ref_clk(id-%d)\n", port);
retval = PTR_ERR(instance->ref_clk);
goto put_child;
}
}
provider = devm_of_phy_provider_register(dev, mtk_phy_xlate);
return PTR_ERR_OR_ZERO(provider);
put_child:
of_node_put(child_np);
return retval;
}
static struct platform_driver mtk_tphy_driver = {
.probe = mtk_tphy_probe,
.driver = {
.name = "mtk-tphy",
.of_match_table = mtk_tphy_id_table,
},
};
module_platform_driver(mtk_tphy_driver);
MODULE_AUTHOR("Chunfeng Yun <chunfeng.yun@mediatek.com>");
MODULE_DESCRIPTION("MediaTek T-PHY driver");
MODULE_LICENSE("GPL v2");
