Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Chris Zhong | 4557 | 82.72% | 5 | 29.41% |
Doug Anderson | 600 | 10.89% | 5 | 29.41% |
Enric Balletbò i Serra | 286 | 5.19% | 2 | 11.76% |
William Wu | 58 | 1.05% | 1 | 5.88% |
Rob Herring | 4 | 0.07% | 2 | 11.76% |
Thomas Gleixner | 2 | 0.04% | 1 | 5.88% |
Yue haibing | 2 | 0.04% | 1 | 5.88% |
Total | 5509 | 17 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) Fuzhou Rockchip Electronics Co.Ltd * Author: Chris Zhong <zyw@rock-chips.com> * Kever Yang <kever.yang@rock-chips.com> * * The ROCKCHIP Type-C PHY has two PLL clocks. The first PLL clock * is used for USB3, the second PLL clock is used for DP. This Type-C PHY has * 3 working modes: USB3 only mode, DP only mode, and USB3+DP mode. * At USB3 only mode, both PLL clocks need to be initialized, this allows the * PHY to switch mode between USB3 and USB3+DP, without disconnecting the USB * device. * In The DP only mode, only the DP PLL needs to be powered on, and the 4 lanes * are all used for DP. * * This driver gets extcon cable state and property, then decides which mode to * select: * * 1. USB3 only mode: * EXTCON_USB or EXTCON_USB_HOST state is true, and * EXTCON_PROP_USB_SS property is true. * EXTCON_DISP_DP state is false. * * 2. DP only mode: * EXTCON_DISP_DP state is true, and * EXTCON_PROP_USB_SS property is false. * If EXTCON_USB_HOST state is true, it is DP + USB2 mode, since the USB2 phy * is a separate phy, so this case is still DP only mode. * * 3. USB3+DP mode: * EXTCON_USB_HOST and EXTCON_DISP_DP are both true, and * EXTCON_PROP_USB_SS property is true. * * This Type-C PHY driver supports normal and flip orientation. The orientation * is reported by the EXTCON_PROP_USB_TYPEC_POLARITY property: true is flip * orientation, false is normal orientation. */ #include <linux/clk.h> #include <linux/clk-provider.h> #include <linux/delay.h> #include <linux/extcon.h> #include <linux/io.h> #include <linux/iopoll.h> #include <linux/kernel.h> #include <linux/module.h> #include <linux/mutex.h> #include <linux/of.h> #include <linux/of_address.h> #include <linux/of_platform.h> #include <linux/platform_device.h> #include <linux/regmap.h> #include <linux/reset.h> #include <linux/mfd/syscon.h> #include <linux/phy/phy.h> #define CMN_SSM_BANDGAP (0x21 << 2) #define CMN_SSM_BIAS (0x22 << 2) #define CMN_PLLSM0_PLLEN (0x29 << 2) #define CMN_PLLSM0_PLLPRE (0x2a << 2) #define CMN_PLLSM0_PLLVREF (0x2b << 2) #define CMN_PLLSM0_PLLLOCK (0x2c << 2) #define CMN_PLLSM1_PLLEN (0x31 << 2) #define CMN_PLLSM1_PLLPRE (0x32 << 2) #define CMN_PLLSM1_PLLVREF (0x33 << 2) #define CMN_PLLSM1_PLLLOCK (0x34 << 2) #define CMN_PLLSM1_USER_DEF_CTRL (0x37 << 2) #define CMN_ICAL_OVRD (0xc1 << 2) #define CMN_PLL0_VCOCAL_OVRD (0x83 << 2) #define CMN_PLL0_VCOCAL_INIT (0x84 << 2) #define CMN_PLL0_VCOCAL_ITER (0x85 << 2) #define CMN_PLL0_LOCK_REFCNT_START (0x90 << 2) #define CMN_PLL0_LOCK_PLLCNT_START (0x92 << 2) #define CMN_PLL0_LOCK_PLLCNT_THR (0x93 << 2) #define CMN_PLL0_INTDIV (0x94 << 2) #define CMN_PLL0_FRACDIV (0x95 << 2) #define CMN_PLL0_HIGH_THR (0x96 << 2) #define CMN_PLL0_DSM_DIAG (0x97 << 2) #define CMN_PLL0_SS_CTRL1 (0x98 << 2) #define CMN_PLL0_SS_CTRL2 (0x99 << 2) #define CMN_PLL1_VCOCAL_START (0xa1 << 2) #define CMN_PLL1_VCOCAL_OVRD (0xa3 << 2) #define CMN_PLL1_VCOCAL_INIT (0xa4 << 2) #define CMN_PLL1_VCOCAL_ITER (0xa5 << 2) #define CMN_PLL1_LOCK_REFCNT_START (0xb0 << 2) #define CMN_PLL1_LOCK_PLLCNT_START (0xb2 << 2) #define CMN_PLL1_LOCK_PLLCNT_THR (0xb3 << 2) #define CMN_PLL1_INTDIV (0xb4 << 2) #define CMN_PLL1_FRACDIV (0xb5 << 2) #define CMN_PLL1_HIGH_THR (0xb6 << 2) #define CMN_PLL1_DSM_DIAG (0xb7 << 2) #define CMN_PLL1_SS_CTRL1 (0xb8 << 2) #define CMN_PLL1_SS_CTRL2 (0xb9 << 2) #define CMN_RXCAL_OVRD (0xd1 << 2) #define CMN_TXPUCAL_CTRL (0xe0 << 2) #define CMN_TXPUCAL_OVRD (0xe1 << 2) #define CMN_TXPDCAL_CTRL (0xf0 << 2) #define CMN_TXPDCAL_OVRD (0xf1 << 2) /* For CMN_TXPUCAL_CTRL, CMN_TXPDCAL_CTRL */ #define CMN_TXPXCAL_START BIT(15) #define CMN_TXPXCAL_DONE BIT(14) #define CMN_TXPXCAL_NO_RESPONSE BIT(13) #define CMN_TXPXCAL_CURRENT_RESPONSE BIT(12) #define CMN_TXPU_ADJ_CTRL (0x108 << 2) #define CMN_TXPD_ADJ_CTRL (0x10c << 2) /* * For CMN_TXPUCAL_CTRL, CMN_TXPDCAL_CTRL, * CMN_TXPU_ADJ_CTRL, CMN_TXPDCAL_CTRL * * NOTE: some of these registers are documented to be 2's complement * signed numbers, but then documented to be always positive. Weird. * In such a case, using CMN_CALIB_CODE_POS() avoids the unnecessary * sign extension. */ #define CMN_CALIB_CODE_WIDTH 7 #define CMN_CALIB_CODE_OFFSET 0 #define CMN_CALIB_CODE_MASK GENMASK(CMN_CALIB_CODE_WIDTH, 0) #define CMN_CALIB_CODE(x) \ sign_extend32((x) >> CMN_CALIB_CODE_OFFSET, CMN_CALIB_CODE_WIDTH) #define CMN_CALIB_CODE_POS_MASK GENMASK(CMN_CALIB_CODE_WIDTH - 1, 0) #define CMN_CALIB_CODE_POS(x) \ (((x) >> CMN_CALIB_CODE_OFFSET) & CMN_CALIB_CODE_POS_MASK) #define CMN_DIAG_PLL0_FBH_OVRD (0x1c0 << 2) #define CMN_DIAG_PLL0_FBL_OVRD (0x1c1 << 2) #define CMN_DIAG_PLL0_OVRD (0x1c2 << 2) #define CMN_DIAG_PLL0_V2I_TUNE (0x1c5 << 2) #define CMN_DIAG_PLL0_CP_TUNE (0x1c6 << 2) #define CMN_DIAG_PLL0_LF_PROG (0x1c7 << 2) #define CMN_DIAG_PLL1_FBH_OVRD (0x1d0 << 2) #define CMN_DIAG_PLL1_FBL_OVRD (0x1d1 << 2) #define CMN_DIAG_PLL1_OVRD (0x1d2 << 2) #define CMN_DIAG_PLL1_V2I_TUNE (0x1d5 << 2) #define CMN_DIAG_PLL1_CP_TUNE (0x1d6 << 2) #define CMN_DIAG_PLL1_LF_PROG (0x1d7 << 2) #define CMN_DIAG_PLL1_PTATIS_TUNE1 (0x1d8 << 2) #define CMN_DIAG_PLL1_PTATIS_TUNE2 (0x1d9 << 2) #define CMN_DIAG_PLL1_INCLK_CTRL (0x1da << 2) #define CMN_DIAG_HSCLK_SEL (0x1e0 << 2) #define XCVR_PSM_RCTRL(n) ((0x4001 | ((n) << 9)) << 2) #define XCVR_PSM_CAL_TMR(n) ((0x4002 | ((n) << 9)) << 2) #define XCVR_PSM_A0IN_TMR(n) ((0x4003 | ((n) << 9)) << 2) #define TX_TXCC_CAL_SCLR_MULT(n) ((0x4047 | ((n) << 9)) << 2) #define TX_TXCC_CPOST_MULT_00(n) ((0x404c | ((n) << 9)) << 2) #define TX_TXCC_CPOST_MULT_01(n) ((0x404d | ((n) << 9)) << 2) #define TX_TXCC_CPOST_MULT_10(n) ((0x404e | ((n) << 9)) << 2) #define TX_TXCC_CPOST_MULT_11(n) ((0x404f | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_000(n) ((0x4050 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_001(n) ((0x4051 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_010(n) ((0x4052 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_011(n) ((0x4053 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_100(n) ((0x4054 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_101(n) ((0x4055 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_110(n) ((0x4056 | ((n) << 9)) << 2) #define TX_TXCC_MGNFS_MULT_111(n) ((0x4057 | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_000(n) ((0x4058 | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_001(n) ((0x4059 | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_010(n) ((0x405a | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_011(n) ((0x405b | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_100(n) ((0x405c | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_101(n) ((0x405d | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_110(n) ((0x405e | ((n) << 9)) << 2) #define TX_TXCC_MGNLS_MULT_111(n) ((0x405f | ((n) << 9)) << 2) #define XCVR_DIAG_PLLDRC_CTRL(n) ((0x40e0 | ((n) << 9)) << 2) #define XCVR_DIAG_BIDI_CTRL(n) ((0x40e8 | ((n) << 9)) << 2) #define XCVR_DIAG_LANE_FCM_EN_MGN(n) ((0x40f2 | ((n) << 9)) << 2) #define TX_PSC_A0(n) ((0x4100 | ((n) << 9)) << 2) #define TX_PSC_A1(n) ((0x4101 | ((n) << 9)) << 2) #define TX_PSC_A2(n) ((0x4102 | ((n) << 9)) << 2) #define TX_PSC_A3(n) ((0x4103 | ((n) << 9)) << 2) #define TX_RCVDET_CTRL(n) ((0x4120 | ((n) << 9)) << 2) #define TX_RCVDET_EN_TMR(n) ((0x4122 | ((n) << 9)) << 2) #define TX_RCVDET_ST_TMR(n) ((0x4123 | ((n) << 9)) << 2) #define TX_DIAG_TX_DRV(n) ((0x41e1 | ((n) << 9)) << 2) #define TX_DIAG_BGREF_PREDRV_DELAY (0x41e7 << 2) /* Use this for "n" in macros like "_MULT_XXX" to target the aux channel */ #define AUX_CH_LANE 8 #define TX_ANA_CTRL_REG_1 (0x5020 << 2) #define TXDA_DP_AUX_EN BIT(15) #define AUXDA_SE_EN BIT(14) #define TXDA_CAL_LATCH_EN BIT(13) #define AUXDA_POLARITY BIT(12) #define TXDA_DRV_POWER_ISOLATION_EN BIT(11) #define TXDA_DRV_POWER_EN_PH_2_N BIT(10) #define TXDA_DRV_POWER_EN_PH_1_N BIT(9) #define TXDA_BGREF_EN BIT(8) #define TXDA_DRV_LDO_EN BIT(7) #define TXDA_DECAP_EN_DEL BIT(6) #define TXDA_DECAP_EN BIT(5) #define TXDA_UPHY_SUPPLY_EN_DEL BIT(4) #define TXDA_UPHY_SUPPLY_EN BIT(3) #define TXDA_LOW_LEAKAGE_EN BIT(2) #define TXDA_DRV_IDLE_LOWI_EN BIT(1) #define TXDA_DRV_CMN_MODE_EN BIT(0) #define TX_ANA_CTRL_REG_2 (0x5021 << 2) #define AUXDA_DEBOUNCING_CLK BIT(15) #define TXDA_LPBK_RECOVERED_CLK_EN BIT(14) #define TXDA_LPBK_ISI_GEN_EN BIT(13) #define TXDA_LPBK_SERIAL_EN BIT(12) #define TXDA_LPBK_LINE_EN BIT(11) #define TXDA_DRV_LDO_REDC_SINKIQ BIT(10) #define XCVR_DECAP_EN_DEL BIT(9) #define XCVR_DECAP_EN BIT(8) #define TXDA_MPHY_ENABLE_HS_NT BIT(7) #define TXDA_MPHY_SA_MODE BIT(6) #define TXDA_DRV_LDO_RBYR_FB_EN BIT(5) #define TXDA_DRV_RST_PULL_DOWN BIT(4) #define TXDA_DRV_LDO_BG_FB_EN BIT(3) #define TXDA_DRV_LDO_BG_REF_EN BIT(2) #define TXDA_DRV_PREDRV_EN_DEL BIT(1) #define TXDA_DRV_PREDRV_EN BIT(0) #define TXDA_COEFF_CALC_CTRL (0x5022 << 2) #define TX_HIGH_Z BIT(6) #define TX_VMARGIN_OFFSET 3 #define TX_VMARGIN_MASK 0x7 #define LOW_POWER_SWING_EN BIT(2) #define TX_FCM_DRV_MAIN_EN BIT(1) #define TX_FCM_FULL_MARGIN BIT(0) #define TX_DIG_CTRL_REG_2 (0x5024 << 2) #define TX_HIGH_Z_TM_EN BIT(15) #define TX_RESCAL_CODE_OFFSET 0 #define TX_RESCAL_CODE_MASK 0x3f #define TXDA_CYA_AUXDA_CYA (0x5025 << 2) #define TX_ANA_CTRL_REG_3 (0x5026 << 2) #define TX_ANA_CTRL_REG_4 (0x5027 << 2) #define TX_ANA_CTRL_REG_5 (0x5029 << 2) #define RX_PSC_A0(n) ((0x8000 | ((n) << 9)) << 2) #define RX_PSC_A1(n) ((0x8001 | ((n) << 9)) << 2) #define RX_PSC_A2(n) ((0x8002 | ((n) << 9)) << 2) #define RX_PSC_A3(n) ((0x8003 | ((n) << 9)) << 2) #define RX_PSC_CAL(n) ((0x8006 | ((n) << 9)) << 2) #define RX_PSC_RDY(n) ((0x8007 | ((n) << 9)) << 2) #define RX_IQPI_ILL_CAL_OVRD (0x8023 << 2) #define RX_EPI_ILL_CAL_OVRD (0x8033 << 2) #define RX_SDCAL0_OVRD (0x8041 << 2) #define RX_SDCAL1_OVRD (0x8049 << 2) #define RX_SLC_INIT (0x806d << 2) #define RX_SLC_RUN (0x806e << 2) #define RX_CDRLF_CNFG2 (0x8081 << 2) #define RX_SIGDET_HL_FILT_TMR(n) ((0x8090 | ((n) << 9)) << 2) #define RX_SLC_IOP0_OVRD (0x8101 << 2) #define RX_SLC_IOP1_OVRD (0x8105 << 2) #define RX_SLC_QOP0_OVRD (0x8109 << 2) #define RX_SLC_QOP1_OVRD (0x810d << 2) #define RX_SLC_EOP0_OVRD (0x8111 << 2) #define RX_SLC_EOP1_OVRD (0x8115 << 2) #define RX_SLC_ION0_OVRD (0x8119 << 2) #define RX_SLC_ION1_OVRD (0x811d << 2) #define RX_SLC_QON0_OVRD (0x8121 << 2) #define RX_SLC_QON1_OVRD (0x8125 << 2) #define RX_SLC_EON0_OVRD (0x8129 << 2) #define RX_SLC_EON1_OVRD (0x812d << 2) #define RX_SLC_IEP0_OVRD (0x8131 << 2) #define RX_SLC_IEP1_OVRD (0x8135 << 2) #define RX_SLC_QEP0_OVRD (0x8139 << 2) #define RX_SLC_QEP1_OVRD (0x813d << 2) #define RX_SLC_EEP0_OVRD (0x8141 << 2) #define RX_SLC_EEP1_OVRD (0x8145 << 2) #define RX_SLC_IEN0_OVRD (0x8149 << 2) #define RX_SLC_IEN1_OVRD (0x814d << 2) #define RX_SLC_QEN0_OVRD (0x8151 << 2) #define RX_SLC_QEN1_OVRD (0x8155 << 2) #define RX_SLC_EEN0_OVRD (0x8159 << 2) #define RX_SLC_EEN1_OVRD (0x815d << 2) #define RX_REE_CTRL_DATA_MASK(n) ((0x81bb | ((n) << 9)) << 2) #define RX_DIAG_SIGDET_TUNE(n) ((0x81dc | ((n) << 9)) << 2) #define RX_DIAG_SC2C_DELAY (0x81e1 << 2) #define PMA_LANE_CFG (0xc000 << 2) #define PIPE_CMN_CTRL1 (0xc001 << 2) #define PIPE_CMN_CTRL2 (0xc002 << 2) #define PIPE_COM_LOCK_CFG1 (0xc003 << 2) #define PIPE_COM_LOCK_CFG2 (0xc004 << 2) #define PIPE_RCV_DET_INH (0xc005 << 2) #define DP_MODE_CTL (0xc008 << 2) #define DP_CLK_CTL (0xc009 << 2) #define STS (0xc00F << 2) #define PHY_ISO_CMN_CTRL (0xc010 << 2) #define PHY_DP_TX_CTL (0xc408 << 2) #define PMA_CMN_CTRL1 (0xc800 << 2) #define PHY_PMA_ISO_CMN_CTRL (0xc810 << 2) #define PHY_ISOLATION_CTRL (0xc81f << 2) #define PHY_PMA_ISO_XCVR_CTRL(n) ((0xcc11 | ((n) << 6)) << 2) #define PHY_PMA_ISO_LINK_MODE(n) ((0xcc12 | ((n) << 6)) << 2) #define PHY_PMA_ISO_PWRST_CTRL(n) ((0xcc13 | ((n) << 6)) << 2) #define PHY_PMA_ISO_TX_DATA_LO(n) ((0xcc14 | ((n) << 6)) << 2) #define PHY_PMA_ISO_TX_DATA_HI(n) ((0xcc15 | ((n) << 6)) << 2) #define PHY_PMA_ISO_RX_DATA_LO(n) ((0xcc16 | ((n) << 6)) << 2) #define PHY_PMA_ISO_RX_DATA_HI(n) ((0xcc17 | ((n) << 6)) << 2) #define TX_BIST_CTRL(n) ((0x4140 | ((n) << 9)) << 2) #define TX_BIST_UDDWR(n) ((0x4141 | ((n) << 9)) << 2) /* * Selects which PLL clock will be driven on the analog high speed * clock 0: PLL 0 div 1 * clock 1: PLL 1 div 2 */ #define CLK_PLL_CONFIG 0X30 #define CLK_PLL_MASK 0x33 #define CMN_READY BIT(0) #define DP_PLL_CLOCK_ENABLE BIT(2) #define DP_PLL_ENABLE BIT(0) #define DP_PLL_DATA_RATE_RBR ((2 << 12) | (4 << 8)) #define DP_PLL_DATA_RATE_HBR ((2 << 12) | (4 << 8)) #define DP_PLL_DATA_RATE_HBR2 ((1 << 12) | (2 << 8)) #define DP_MODE_A0 BIT(4) #define DP_MODE_A2 BIT(6) #define DP_MODE_ENTER_A0 0xc101 #define DP_MODE_ENTER_A2 0xc104 #define PHY_MODE_SET_TIMEOUT 100000 #define PIN_ASSIGN_C_E 0x51d9 #define PIN_ASSIGN_D_F 0x5100 #define MODE_DISCONNECT 0 #define MODE_UFP_USB BIT(0) #define MODE_DFP_USB BIT(1) #define MODE_DFP_DP BIT(2) struct usb3phy_reg { u32 offset; u32 enable_bit; u32 write_enable; }; /** * struct rockchip_usb3phy_port_cfg: usb3-phy port configuration. * @reg: the base address for usb3-phy config. * @typec_conn_dir: the register of type-c connector direction. * @usb3tousb2_en: the register of type-c force usb2 to usb2 enable. * @external_psm: the register of type-c phy external psm clock. * @pipe_status: the register of type-c phy pipe status. * @usb3_host_disable: the register of type-c usb3 host disable. * @usb3_host_port: the register of type-c usb3 host port. * @uphy_dp_sel: the register of type-c phy DP select control. */ struct rockchip_usb3phy_port_cfg { unsigned int reg; struct usb3phy_reg typec_conn_dir; struct usb3phy_reg usb3tousb2_en; struct usb3phy_reg external_psm; struct usb3phy_reg pipe_status; struct usb3phy_reg usb3_host_disable; struct usb3phy_reg usb3_host_port; struct usb3phy_reg uphy_dp_sel; }; struct rockchip_typec_phy { struct device *dev; void __iomem *base; struct extcon_dev *extcon; struct regmap *grf_regs; struct clk *clk_core; struct clk *clk_ref; struct reset_control *uphy_rst; struct reset_control *pipe_rst; struct reset_control *tcphy_rst; const struct rockchip_usb3phy_port_cfg *port_cfgs; /* mutex to protect access to individual PHYs */ struct mutex lock; bool flip; u8 mode; }; struct phy_reg { u16 value; u32 addr; }; static struct phy_reg usb3_pll_cfg[] = { { 0xf0, CMN_PLL0_VCOCAL_INIT }, { 0x18, CMN_PLL0_VCOCAL_ITER }, { 0xd0, CMN_PLL0_INTDIV }, { 0x4a4a, CMN_PLL0_FRACDIV }, { 0x34, CMN_PLL0_HIGH_THR }, { 0x1ee, CMN_PLL0_SS_CTRL1 }, { 0x7f03, CMN_PLL0_SS_CTRL2 }, { 0x20, CMN_PLL0_DSM_DIAG }, { 0, CMN_DIAG_PLL0_OVRD }, { 0, CMN_DIAG_PLL0_FBH_OVRD }, { 0, CMN_DIAG_PLL0_FBL_OVRD }, { 0x7, CMN_DIAG_PLL0_V2I_TUNE }, { 0x45, CMN_DIAG_PLL0_CP_TUNE }, { 0x8, CMN_DIAG_PLL0_LF_PROG }, }; static struct phy_reg dp_pll_cfg[] = { { 0xf0, CMN_PLL1_VCOCAL_INIT }, { 0x18, CMN_PLL1_VCOCAL_ITER }, { 0x30b9, CMN_PLL1_VCOCAL_START }, { 0x21c, CMN_PLL1_INTDIV }, { 0, CMN_PLL1_FRACDIV }, { 0x5, CMN_PLL1_HIGH_THR }, { 0x35, CMN_PLL1_SS_CTRL1 }, { 0x7f1e, CMN_PLL1_SS_CTRL2 }, { 0x20, CMN_PLL1_DSM_DIAG }, { 0, CMN_PLLSM1_USER_DEF_CTRL }, { 0, CMN_DIAG_PLL1_OVRD }, { 0, CMN_DIAG_PLL1_FBH_OVRD }, { 0, CMN_DIAG_PLL1_FBL_OVRD }, { 0x6, CMN_DIAG_PLL1_V2I_TUNE }, { 0x45, CMN_DIAG_PLL1_CP_TUNE }, { 0x8, CMN_DIAG_PLL1_LF_PROG }, { 0x100, CMN_DIAG_PLL1_PTATIS_TUNE1 }, { 0x7, CMN_DIAG_PLL1_PTATIS_TUNE2 }, { 0x4, CMN_DIAG_PLL1_INCLK_CTRL }, }; static const struct rockchip_usb3phy_port_cfg rk3399_usb3phy_port_cfgs[] = { { .reg = 0xff7c0000, .typec_conn_dir = { 0xe580, 0, 16 }, .usb3tousb2_en = { 0xe580, 3, 19 }, .external_psm = { 0xe588, 14, 30 }, .pipe_status = { 0xe5c0, 0, 0 }, .usb3_host_disable = { 0x2434, 0, 16 }, .usb3_host_port = { 0x2434, 12, 28 }, .uphy_dp_sel = { 0x6268, 19, 19 }, }, { .reg = 0xff800000, .typec_conn_dir = { 0xe58c, 0, 16 }, .usb3tousb2_en = { 0xe58c, 3, 19 }, .external_psm = { 0xe594, 14, 30 }, .pipe_status = { 0xe5c0, 16, 16 }, .usb3_host_disable = { 0x2444, 0, 16 }, .usb3_host_port = { 0x2444, 12, 28 }, .uphy_dp_sel = { 0x6268, 3, 19 }, }, { /* sentinel */ } }; static void tcphy_cfg_24m(struct rockchip_typec_phy *tcphy) { u32 i, rdata; /* * cmn_ref_clk_sel = 3, select the 24Mhz for clk parent * cmn_psm_clk_dig_div = 2, set the clk division to 2 */ writel(0x830, tcphy->base + PMA_CMN_CTRL1); for (i = 0; i < 4; i++) { /* * The following PHY configuration assumes a 24 MHz reference * clock. */ writel(0x90, tcphy->base + XCVR_DIAG_LANE_FCM_EN_MGN(i)); writel(0x960, tcphy->base + TX_RCVDET_EN_TMR(i)); writel(0x30, tcphy->base + TX_RCVDET_ST_TMR(i)); } rdata = readl(tcphy->base + CMN_DIAG_HSCLK_SEL); rdata &= ~CLK_PLL_MASK; rdata |= CLK_PLL_CONFIG; writel(rdata, tcphy->base + CMN_DIAG_HSCLK_SEL); } static void tcphy_cfg_usb3_pll(struct rockchip_typec_phy *tcphy) { u32 i; /* load the configuration of PLL0 */ for (i = 0; i < ARRAY_SIZE(usb3_pll_cfg); i++) writel(usb3_pll_cfg[i].value, tcphy->base + usb3_pll_cfg[i].addr); } static void tcphy_cfg_dp_pll(struct rockchip_typec_phy *tcphy) { u32 i; /* set the default mode to RBR */ writel(DP_PLL_CLOCK_ENABLE | DP_PLL_ENABLE | DP_PLL_DATA_RATE_RBR, tcphy->base + DP_CLK_CTL); /* load the configuration of PLL1 */ for (i = 0; i < ARRAY_SIZE(dp_pll_cfg); i++) writel(dp_pll_cfg[i].value, tcphy->base + dp_pll_cfg[i].addr); } static void tcphy_tx_usb3_cfg_lane(struct rockchip_typec_phy *tcphy, u32 lane) { writel(0x7799, tcphy->base + TX_PSC_A0(lane)); writel(0x7798, tcphy->base + TX_PSC_A1(lane)); writel(0x5098, tcphy->base + TX_PSC_A2(lane)); writel(0x5098, tcphy->base + TX_PSC_A3(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_000(lane)); writel(0xbf, tcphy->base + XCVR_DIAG_BIDI_CTRL(lane)); } static void tcphy_rx_usb3_cfg_lane(struct rockchip_typec_phy *tcphy, u32 lane) { writel(0xa6fd, tcphy->base + RX_PSC_A0(lane)); writel(0xa6fd, tcphy->base + RX_PSC_A1(lane)); writel(0xa410, tcphy->base + RX_PSC_A2(lane)); writel(0x2410, tcphy->base + RX_PSC_A3(lane)); writel(0x23ff, tcphy->base + RX_PSC_CAL(lane)); writel(0x13, tcphy->base + RX_SIGDET_HL_FILT_TMR(lane)); writel(0x03e7, tcphy->base + RX_REE_CTRL_DATA_MASK(lane)); writel(0x1004, tcphy->base + RX_DIAG_SIGDET_TUNE(lane)); writel(0x2010, tcphy->base + RX_PSC_RDY(lane)); writel(0xfb, tcphy->base + XCVR_DIAG_BIDI_CTRL(lane)); } static void tcphy_dp_cfg_lane(struct rockchip_typec_phy *tcphy, u32 lane) { u16 rdata; writel(0xbefc, tcphy->base + XCVR_PSM_RCTRL(lane)); writel(0x6799, tcphy->base + TX_PSC_A0(lane)); writel(0x6798, tcphy->base + TX_PSC_A1(lane)); writel(0x98, tcphy->base + TX_PSC_A2(lane)); writel(0x98, tcphy->base + TX_PSC_A3(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_000(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_001(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_010(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_011(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_100(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_101(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_110(lane)); writel(0, tcphy->base + TX_TXCC_MGNFS_MULT_111(lane)); writel(0, tcphy->base + TX_TXCC_CPOST_MULT_10(lane)); writel(0, tcphy->base + TX_TXCC_CPOST_MULT_01(lane)); writel(0, tcphy->base + TX_TXCC_CPOST_MULT_00(lane)); writel(0, tcphy->base + TX_TXCC_CPOST_MULT_11(lane)); writel(0x128, tcphy->base + TX_TXCC_CAL_SCLR_MULT(lane)); writel(0x400, tcphy->base + TX_DIAG_TX_DRV(lane)); rdata = readl(tcphy->base + XCVR_DIAG_PLLDRC_CTRL(lane)); rdata = (rdata & 0x8fff) | 0x6000; writel(rdata, tcphy->base + XCVR_DIAG_PLLDRC_CTRL(lane)); } static inline int property_enable(struct rockchip_typec_phy *tcphy, const struct usb3phy_reg *reg, bool en) { u32 mask = 1 << reg->write_enable; u32 val = en << reg->enable_bit; return regmap_write(tcphy->grf_regs, reg->offset, val | mask); } static void tcphy_dp_aux_set_flip(struct rockchip_typec_phy *tcphy) { u16 tx_ana_ctrl_reg_1; /* * Select the polarity of the xcvr: * 1, Reverses the polarity (If TYPEC, Pulls ups aux_p and pull * down aux_m) * 0, Normal polarity (if TYPEC, pulls up aux_m and pulls down * aux_p) */ tx_ana_ctrl_reg_1 = readl(tcphy->base + TX_ANA_CTRL_REG_1); if (!tcphy->flip) tx_ana_ctrl_reg_1 |= AUXDA_POLARITY; else tx_ana_ctrl_reg_1 &= ~AUXDA_POLARITY; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); } static void tcphy_dp_aux_calibration(struct rockchip_typec_phy *tcphy) { u16 val; u16 tx_ana_ctrl_reg_1; u16 tx_ana_ctrl_reg_2; s32 pu_calib_code, pd_calib_code; s32 pu_adj, pd_adj; u16 calib; /* * Calculate calibration code as per docs: use an average of the * pull down and pull up. Then add in adjustments. */ val = readl(tcphy->base + CMN_TXPUCAL_CTRL); pu_calib_code = CMN_CALIB_CODE_POS(val); val = readl(tcphy->base + CMN_TXPDCAL_CTRL); pd_calib_code = CMN_CALIB_CODE_POS(val); val = readl(tcphy->base + CMN_TXPU_ADJ_CTRL); pu_adj = CMN_CALIB_CODE(val); val = readl(tcphy->base + CMN_TXPD_ADJ_CTRL); pd_adj = CMN_CALIB_CODE(val); calib = (pu_calib_code + pd_calib_code) / 2 + pu_adj + pd_adj; /* disable txda_cal_latch_en for rewrite the calibration values */ tx_ana_ctrl_reg_1 = readl(tcphy->base + TX_ANA_CTRL_REG_1); tx_ana_ctrl_reg_1 &= ~TXDA_CAL_LATCH_EN; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); /* write the calibration, then delay 10 ms as sample in docs */ val = readl(tcphy->base + TX_DIG_CTRL_REG_2); val &= ~(TX_RESCAL_CODE_MASK << TX_RESCAL_CODE_OFFSET); val |= calib << TX_RESCAL_CODE_OFFSET; writel(val, tcphy->base + TX_DIG_CTRL_REG_2); usleep_range(10000, 10050); /* * Enable signal for latch that sample and holds calibration values. * Activate this signal for 1 clock cycle to sample new calibration * values. */ tx_ana_ctrl_reg_1 |= TXDA_CAL_LATCH_EN; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); usleep_range(150, 200); /* set TX Voltage Level and TX Deemphasis to 0 */ writel(0, tcphy->base + PHY_DP_TX_CTL); /* re-enable decap */ tx_ana_ctrl_reg_2 = XCVR_DECAP_EN; writel(tx_ana_ctrl_reg_2, tcphy->base + TX_ANA_CTRL_REG_2); udelay(1); tx_ana_ctrl_reg_2 |= XCVR_DECAP_EN_DEL; writel(tx_ana_ctrl_reg_2, tcphy->base + TX_ANA_CTRL_REG_2); writel(0, tcphy->base + TX_ANA_CTRL_REG_3); tx_ana_ctrl_reg_1 |= TXDA_UPHY_SUPPLY_EN; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); udelay(1); tx_ana_ctrl_reg_1 |= TXDA_UPHY_SUPPLY_EN_DEL; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); writel(0, tcphy->base + TX_ANA_CTRL_REG_5); /* * Programs txda_drv_ldo_prog[15:0], Sets driver LDO * voltage 16'h1001 for DP-AUX-TX and RX */ writel(0x1001, tcphy->base + TX_ANA_CTRL_REG_4); /* re-enables Bandgap reference for LDO */ tx_ana_ctrl_reg_1 |= TXDA_DRV_LDO_EN; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); udelay(5); tx_ana_ctrl_reg_1 |= TXDA_BGREF_EN; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); /* * re-enables the transmitter pre-driver, driver data selection MUX, * and receiver detect circuits. */ tx_ana_ctrl_reg_2 |= TXDA_DRV_PREDRV_EN; writel(tx_ana_ctrl_reg_2, tcphy->base + TX_ANA_CTRL_REG_2); udelay(1); tx_ana_ctrl_reg_2 |= TXDA_DRV_PREDRV_EN_DEL; writel(tx_ana_ctrl_reg_2, tcphy->base + TX_ANA_CTRL_REG_2); /* * Do all the undocumented magic: * - Turn on TXDA_DP_AUX_EN, whatever that is, even though sample * never shows this going on. * - Turn on TXDA_DECAP_EN (and TXDA_DECAP_EN_DEL) even though * docs say for aux it's always 0. * - Turn off the LDO and BGREF, which we just spent time turning * on above (???). * * Without this magic, things seem worse. */ tx_ana_ctrl_reg_1 |= TXDA_DP_AUX_EN; tx_ana_ctrl_reg_1 |= TXDA_DECAP_EN; tx_ana_ctrl_reg_1 &= ~TXDA_DRV_LDO_EN; tx_ana_ctrl_reg_1 &= ~TXDA_BGREF_EN; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); udelay(1); tx_ana_ctrl_reg_1 |= TXDA_DECAP_EN_DEL; writel(tx_ana_ctrl_reg_1, tcphy->base + TX_ANA_CTRL_REG_1); /* * Undo the work we did to set the LDO voltage. * This doesn't seem to help nor hurt, but it kinda goes with the * undocumented magic above. */ writel(0, tcphy->base + TX_ANA_CTRL_REG_4); /* Don't set voltage swing to 400 mV peak to peak (differential) */ writel(0, tcphy->base + TXDA_COEFF_CALC_CTRL); /* Init TXDA_CYA_AUXDA_CYA for unknown magic reasons */ writel(0, tcphy->base + TXDA_CYA_AUXDA_CYA); /* * More undocumented magic, presumably the goal of which is to * make the "auxda_source_aux_oen" be ignored and instead to decide * about "high impedance state" based on what software puts in the * register TXDA_COEFF_CALC_CTRL (see TX_HIGH_Z). Since we only * program that register once and we don't set the bit TX_HIGH_Z, * presumably the goal here is that we should never put the analog * driver in high impedance state. */ val = readl(tcphy->base + TX_DIG_CTRL_REG_2); val |= TX_HIGH_Z_TM_EN; writel(val, tcphy->base + TX_DIG_CTRL_REG_2); } static int tcphy_phy_init(struct rockchip_typec_phy *tcphy, u8 mode) { const struct rockchip_usb3phy_port_cfg *cfg = tcphy->port_cfgs; int ret, i; u32 val; ret = clk_prepare_enable(tcphy->clk_core); if (ret) { dev_err(tcphy->dev, "Failed to prepare_enable core clock\n"); return ret; } ret = clk_prepare_enable(tcphy->clk_ref); if (ret) { dev_err(tcphy->dev, "Failed to prepare_enable ref clock\n"); goto err_clk_core; } reset_control_deassert(tcphy->tcphy_rst); property_enable(tcphy, &cfg->typec_conn_dir, tcphy->flip); tcphy_dp_aux_set_flip(tcphy); tcphy_cfg_24m(tcphy); if (mode == MODE_DFP_DP) { tcphy_cfg_dp_pll(tcphy); for (i = 0; i < 4; i++) tcphy_dp_cfg_lane(tcphy, i); writel(PIN_ASSIGN_C_E, tcphy->base + PMA_LANE_CFG); } else { tcphy_cfg_usb3_pll(tcphy); tcphy_cfg_dp_pll(tcphy); if (tcphy->flip) { tcphy_tx_usb3_cfg_lane(tcphy, 3); tcphy_rx_usb3_cfg_lane(tcphy, 2); tcphy_dp_cfg_lane(tcphy, 0); tcphy_dp_cfg_lane(tcphy, 1); } else { tcphy_tx_usb3_cfg_lane(tcphy, 0); tcphy_rx_usb3_cfg_lane(tcphy, 1); tcphy_dp_cfg_lane(tcphy, 2); tcphy_dp_cfg_lane(tcphy, 3); } writel(PIN_ASSIGN_D_F, tcphy->base + PMA_LANE_CFG); } writel(DP_MODE_ENTER_A2, tcphy->base + DP_MODE_CTL); reset_control_deassert(tcphy->uphy_rst); ret = readx_poll_timeout(readl, tcphy->base + PMA_CMN_CTRL1, val, val & CMN_READY, 10, PHY_MODE_SET_TIMEOUT); if (ret < 0) { dev_err(tcphy->dev, "wait pma ready timeout\n"); ret = -ETIMEDOUT; goto err_wait_pma; } reset_control_deassert(tcphy->pipe_rst); return 0; err_wait_pma: reset_control_assert(tcphy->uphy_rst); reset_control_assert(tcphy->tcphy_rst); clk_disable_unprepare(tcphy->clk_ref); err_clk_core: clk_disable_unprepare(tcphy->clk_core); return ret; } static void tcphy_phy_deinit(struct rockchip_typec_phy *tcphy) { reset_control_assert(tcphy->tcphy_rst); reset_control_assert(tcphy->uphy_rst); reset_control_assert(tcphy->pipe_rst); clk_disable_unprepare(tcphy->clk_core); clk_disable_unprepare(tcphy->clk_ref); } static int tcphy_get_mode(struct rockchip_typec_phy *tcphy) { struct extcon_dev *edev = tcphy->extcon; union extcon_property_value property; unsigned int id; bool ufp, dp; u8 mode; int ret; if (!edev) return MODE_DFP_USB; ufp = extcon_get_state(edev, EXTCON_USB); dp = extcon_get_state(edev, EXTCON_DISP_DP); mode = MODE_DFP_USB; id = EXTCON_USB_HOST; if (ufp) { mode = MODE_UFP_USB; id = EXTCON_USB; } else if (dp) { mode = MODE_DFP_DP; id = EXTCON_DISP_DP; ret = extcon_get_property(edev, id, EXTCON_PROP_USB_SS, &property); if (ret) { dev_err(tcphy->dev, "get superspeed property failed\n"); return ret; } if (property.intval) mode |= MODE_DFP_USB; } ret = extcon_get_property(edev, id, EXTCON_PROP_USB_TYPEC_POLARITY, &property); if (ret) { dev_err(tcphy->dev, "get polarity property failed\n"); return ret; } tcphy->flip = property.intval ? 1 : 0; return mode; } static int tcphy_cfg_usb3_to_usb2_only(struct rockchip_typec_phy *tcphy, bool value) { const struct rockchip_usb3phy_port_cfg *cfg = tcphy->port_cfgs; property_enable(tcphy, &cfg->usb3tousb2_en, value); property_enable(tcphy, &cfg->usb3_host_disable, value); property_enable(tcphy, &cfg->usb3_host_port, !value); return 0; } static int rockchip_usb3_phy_power_on(struct phy *phy) { struct rockchip_typec_phy *tcphy = phy_get_drvdata(phy); const struct rockchip_usb3phy_port_cfg *cfg = tcphy->port_cfgs; const struct usb3phy_reg *reg = &cfg->pipe_status; int timeout, new_mode, ret = 0; u32 val; mutex_lock(&tcphy->lock); new_mode = tcphy_get_mode(tcphy); if (new_mode < 0) { ret = new_mode; goto unlock_ret; } /* DP-only mode; fall back to USB2 */ if (!(new_mode & (MODE_DFP_USB | MODE_UFP_USB))) { tcphy_cfg_usb3_to_usb2_only(tcphy, true); goto unlock_ret; } if (tcphy->mode == new_mode) goto unlock_ret; if (tcphy->mode == MODE_DISCONNECT) { ret = tcphy_phy_init(tcphy, new_mode); if (ret) goto unlock_ret; } /* wait TCPHY for pipe ready */ for (timeout = 0; timeout < 100; timeout++) { regmap_read(tcphy->grf_regs, reg->offset, &val); if (!(val & BIT(reg->enable_bit))) { tcphy->mode |= new_mode & (MODE_DFP_USB | MODE_UFP_USB); /* enable usb3 host */ tcphy_cfg_usb3_to_usb2_only(tcphy, false); goto unlock_ret; } usleep_range(10, 20); } if (tcphy->mode == MODE_DISCONNECT) tcphy_phy_deinit(tcphy); ret = -ETIMEDOUT; unlock_ret: mutex_unlock(&tcphy->lock); return ret; } static int rockchip_usb3_phy_power_off(struct phy *phy) { struct rockchip_typec_phy *tcphy = phy_get_drvdata(phy); mutex_lock(&tcphy->lock); tcphy_cfg_usb3_to_usb2_only(tcphy, false); if (tcphy->mode == MODE_DISCONNECT) goto unlock; tcphy->mode &= ~(MODE_UFP_USB | MODE_DFP_USB); if (tcphy->mode == MODE_DISCONNECT) tcphy_phy_deinit(tcphy); unlock: mutex_unlock(&tcphy->lock); return 0; } static const struct phy_ops rockchip_usb3_phy_ops = { .power_on = rockchip_usb3_phy_power_on, .power_off = rockchip_usb3_phy_power_off, .owner = THIS_MODULE, }; static int rockchip_dp_phy_power_on(struct phy *phy) { struct rockchip_typec_phy *tcphy = phy_get_drvdata(phy); const struct rockchip_usb3phy_port_cfg *cfg = tcphy->port_cfgs; int new_mode, ret = 0; u32 val; mutex_lock(&tcphy->lock); new_mode = tcphy_get_mode(tcphy); if (new_mode < 0) { ret = new_mode; goto unlock_ret; } if (!(new_mode & MODE_DFP_DP)) { ret = -ENODEV; goto unlock_ret; } if (tcphy->mode == new_mode) goto unlock_ret; /* * If the PHY has been power on, but the mode is not DP only mode, * re-init the PHY for setting all of 4 lanes to DP. */ if (new_mode == MODE_DFP_DP && tcphy->mode != MODE_DISCONNECT) { tcphy_phy_deinit(tcphy); ret = tcphy_phy_init(tcphy, new_mode); } else if (tcphy->mode == MODE_DISCONNECT) { ret = tcphy_phy_init(tcphy, new_mode); } if (ret) goto unlock_ret; property_enable(tcphy, &cfg->uphy_dp_sel, 1); ret = readx_poll_timeout(readl, tcphy->base + DP_MODE_CTL, val, val & DP_MODE_A2, 1000, PHY_MODE_SET_TIMEOUT); if (ret < 0) { dev_err(tcphy->dev, "failed to wait TCPHY enter A2\n"); goto power_on_finish; } tcphy_dp_aux_calibration(tcphy); writel(DP_MODE_ENTER_A0, tcphy->base + DP_MODE_CTL); ret = readx_poll_timeout(readl, tcphy->base + DP_MODE_CTL, val, val & DP_MODE_A0, 1000, PHY_MODE_SET_TIMEOUT); if (ret < 0) { writel(DP_MODE_ENTER_A2, tcphy->base + DP_MODE_CTL); dev_err(tcphy->dev, "failed to wait TCPHY enter A0\n"); goto power_on_finish; } tcphy->mode |= MODE_DFP_DP; power_on_finish: if (tcphy->mode == MODE_DISCONNECT) tcphy_phy_deinit(tcphy); unlock_ret: mutex_unlock(&tcphy->lock); return ret; } static int rockchip_dp_phy_power_off(struct phy *phy) { struct rockchip_typec_phy *tcphy = phy_get_drvdata(phy); mutex_lock(&tcphy->lock); if (tcphy->mode == MODE_DISCONNECT) goto unlock; tcphy->mode &= ~MODE_DFP_DP; writel(DP_MODE_ENTER_A2, tcphy->base + DP_MODE_CTL); if (tcphy->mode == MODE_DISCONNECT) tcphy_phy_deinit(tcphy); unlock: mutex_unlock(&tcphy->lock); return 0; } static const struct phy_ops rockchip_dp_phy_ops = { .power_on = rockchip_dp_phy_power_on, .power_off = rockchip_dp_phy_power_off, .owner = THIS_MODULE, }; static int tcphy_parse_dt(struct rockchip_typec_phy *tcphy, struct device *dev) { tcphy->grf_regs = syscon_regmap_lookup_by_phandle(dev->of_node, "rockchip,grf"); if (IS_ERR(tcphy->grf_regs)) { dev_err(dev, "could not find grf dt node\n"); return PTR_ERR(tcphy->grf_regs); } tcphy->clk_core = devm_clk_get(dev, "tcpdcore"); if (IS_ERR(tcphy->clk_core)) { dev_err(dev, "could not get uphy core clock\n"); return PTR_ERR(tcphy->clk_core); } tcphy->clk_ref = devm_clk_get(dev, "tcpdphy-ref"); if (IS_ERR(tcphy->clk_ref)) { dev_err(dev, "could not get uphy ref clock\n"); return PTR_ERR(tcphy->clk_ref); } tcphy->uphy_rst = devm_reset_control_get(dev, "uphy"); if (IS_ERR(tcphy->uphy_rst)) { dev_err(dev, "no uphy_rst reset control found\n"); return PTR_ERR(tcphy->uphy_rst); } tcphy->pipe_rst = devm_reset_control_get(dev, "uphy-pipe"); if (IS_ERR(tcphy->pipe_rst)) { dev_err(dev, "no pipe_rst reset control found\n"); return PTR_ERR(tcphy->pipe_rst); } tcphy->tcphy_rst = devm_reset_control_get(dev, "uphy-tcphy"); if (IS_ERR(tcphy->tcphy_rst)) { dev_err(dev, "no tcphy_rst reset control found\n"); return PTR_ERR(tcphy->tcphy_rst); } return 0; } static void typec_phy_pre_init(struct rockchip_typec_phy *tcphy) { const struct rockchip_usb3phy_port_cfg *cfg = tcphy->port_cfgs; reset_control_assert(tcphy->tcphy_rst); reset_control_assert(tcphy->uphy_rst); reset_control_assert(tcphy->pipe_rst); /* select external psm clock */ property_enable(tcphy, &cfg->external_psm, 1); property_enable(tcphy, &cfg->usb3tousb2_en, 0); tcphy->mode = MODE_DISCONNECT; } static int rockchip_typec_phy_probe(struct platform_device *pdev) { struct device *dev = &pdev->dev; struct device_node *np = dev->of_node; struct device_node *child_np; struct rockchip_typec_phy *tcphy; struct phy_provider *phy_provider; struct resource *res; const struct rockchip_usb3phy_port_cfg *phy_cfgs; const struct of_device_id *match; int index, ret; tcphy = devm_kzalloc(dev, sizeof(*tcphy), GFP_KERNEL); if (!tcphy) return -ENOMEM; match = of_match_device(dev->driver->of_match_table, dev); if (!match || !match->data) { dev_err(dev, "phy configs are not assigned!\n"); return -EINVAL; } res = platform_get_resource(pdev, IORESOURCE_MEM, 0); tcphy->base = devm_ioremap_resource(dev, res); if (IS_ERR(tcphy->base)) return PTR_ERR(tcphy->base); phy_cfgs = match->data; /* find out a proper config which can be matched with dt. */ index = 0; while (phy_cfgs[index].reg) { if (phy_cfgs[index].reg == res->start) { tcphy->port_cfgs = &phy_cfgs[index]; break; } ++index; } if (!tcphy->port_cfgs) { dev_err(dev, "no phy-config can be matched with %pOFn node\n", np); return -EINVAL; } ret = tcphy_parse_dt(tcphy, dev); if (ret) return ret; tcphy->dev = dev; platform_set_drvdata(pdev, tcphy); mutex_init(&tcphy->lock); typec_phy_pre_init(tcphy); tcphy->extcon = extcon_get_edev_by_phandle(dev, 0); if (IS_ERR(tcphy->extcon)) { if (PTR_ERR(tcphy->extcon) == -ENODEV) { tcphy->extcon = NULL; } else { if (PTR_ERR(tcphy->extcon) != -EPROBE_DEFER) dev_err(dev, "Invalid or missing extcon\n"); return PTR_ERR(tcphy->extcon); } } pm_runtime_enable(dev); for_each_available_child_of_node(np, child_np) { struct phy *phy; if (of_node_name_eq(child_np, "dp-port")) phy = devm_phy_create(dev, child_np, &rockchip_dp_phy_ops); else if (of_node_name_eq(child_np, "usb3-port")) phy = devm_phy_create(dev, child_np, &rockchip_usb3_phy_ops); else continue; if (IS_ERR(phy)) { dev_err(dev, "failed to create phy: %pOFn\n", child_np); pm_runtime_disable(dev); return PTR_ERR(phy); } phy_set_drvdata(phy, tcphy); } phy_provider = devm_of_phy_provider_register(dev, of_phy_simple_xlate); if (IS_ERR(phy_provider)) { dev_err(dev, "Failed to register phy provider\n"); pm_runtime_disable(dev); return PTR_ERR(phy_provider); } return 0; } static int rockchip_typec_phy_remove(struct platform_device *pdev) { pm_runtime_disable(&pdev->dev); return 0; } static const struct of_device_id rockchip_typec_phy_dt_ids[] = { { .compatible = "rockchip,rk3399-typec-phy", .data = &rk3399_usb3phy_port_cfgs }, { /* sentinel */ } }; MODULE_DEVICE_TABLE(of, rockchip_typec_phy_dt_ids); static struct platform_driver rockchip_typec_phy_driver = { .probe = rockchip_typec_phy_probe, .remove = rockchip_typec_phy_remove, .driver = { .name = "rockchip-typec-phy", .of_match_table = rockchip_typec_phy_dt_ids, }, }; module_platform_driver(rockchip_typec_phy_driver); MODULE_AUTHOR("Chris Zhong <zyw@rock-chips.com>"); MODULE_AUTHOR("Kever Yang <kever.yang@rock-chips.com>"); MODULE_DESCRIPTION("Rockchip USB TYPE-C PHY driver"); MODULE_LICENSE("GPL v2");
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