// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2015-2020, The Linux Foundation. All rights reserved. */ #include #include #include "dsi_hw.h" #include "dsi_phy_hw.h" #define DSIPHY_CMN_REVISION_ID0 0x0000 #define DSIPHY_CMN_REVISION_ID1 0x0004 #define DSIPHY_CMN_REVISION_ID2 0x0008 #define DSIPHY_CMN_REVISION_ID3 0x000C #define DSIPHY_CMN_CLK_CFG0 0x0010 #define DSIPHY_CMN_CLK_CFG1 0x0014 #define DSIPHY_CMN_GLBL_TEST_CTRL 0x0018 #define DSIPHY_CMN_CTRL_0 0x001C #define DSIPHY_CMN_CTRL_1 0x0020 #define DSIPHY_CMN_CAL_HW_TRIGGER 0x0024 #define DSIPHY_CMN_CAL_SW_CFG0 0x0028 #define DSIPHY_CMN_CAL_SW_CFG1 0x002C #define DSIPHY_CMN_CAL_SW_CFG2 0x0030 #define DSIPHY_CMN_CAL_HW_CFG0 0x0034 #define DSIPHY_CMN_CAL_HW_CFG1 0x0038 #define DSIPHY_CMN_CAL_HW_CFG2 0x003C #define DSIPHY_CMN_CAL_HW_CFG3 0x0040 #define DSIPHY_CMN_CAL_HW_CFG4 0x0044 #define DSIPHY_CMN_PLL_CNTRL 0x0048 #define DSIPHY_CMN_LDO_CNTRL 0x004C #define DSIPHY_CMN_REGULATOR_CAL_STATUS0 0x0064 #define DSIPHY_CMN_REGULATOR_CAL_STATUS1 0x0068 #define DSI_MDP_ULPS_CLAMP_ENABLE_OFF 0x0054 /* n = 0..3 for data lanes and n = 4 for clock lane * t for count per lane */ #define DSIPHY_DLNX_CFG(n, t) \ (0x100 + ((t) * 0x04) + ((n) * 0x80)) #define DSIPHY_DLNX_TIMING_CTRL(n, t) \ (0x118 + ((t) * 0x04) + ((n) * 0x80)) #define DSIPHY_DLNX_STRENGTH_CTRL(n, t) \ (0x138 + ((t) * 0x04) + ((n) * 0x80)) #define DSIPHY_DLNX_TEST_DATAPATH(n) (0x110 + ((n) * 0x80)) #define DSIPHY_DLNX_TEST_STR(n) (0x114 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_POLY(n) (0x140 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_SEED0(n) (0x144 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_SEED1(n) (0x148 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_HEAD(n) (0x14C + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_SOT(n) (0x150 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_CTRL0(n) (0x154 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_CTRL1(n) (0x158 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_CTRL2(n) (0x15C + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_CTRL3(n) (0x160 + ((n) * 0x80)) #define DSIPHY_DLNX_VREG_CNTRL(n) (0x164 + ((n) * 0x80)) #define DSIPHY_DLNX_HSTX_STR_STATUS(n) (0x168 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_STATUS0(n) (0x16C + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_STATUS1(n) (0x170 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_STATUS2(n) (0x174 + ((n) * 0x80)) #define DSIPHY_DLNX_BIST_STATUS3(n) (0x178 + ((n) * 0x80)) #define DSIPHY_DLNX_MISR_STATUS(n) (0x17C + ((n) * 0x80)) #define DSIPHY_PLL_CLKBUFLR_EN 0x041C #define DSIPHY_PLL_PLL_BANDGAP 0x0508 /* dynamic refresh control registers */ #define DSI_DYN_REFRESH_CTRL 0x000 #define DSI_DYN_REFRESH_PIPE_DELAY 0x004 #define DSI_DYN_REFRESH_PIPE_DELAY2 0x008 #define DSI_DYN_REFRESH_PLL_DELAY 0x00C #define DSI_DYN_REFRESH_STATUS 0x010 #define DSI_DYN_REFRESH_PLL_CTRL0 0x014 #define DSI_DYN_REFRESH_PLL_CTRL1 0x018 #define DSI_DYN_REFRESH_PLL_CTRL2 0x01C #define DSI_DYN_REFRESH_PLL_CTRL3 0x020 #define DSI_DYN_REFRESH_PLL_CTRL4 0x024 #define DSI_DYN_REFRESH_PLL_CTRL5 0x028 #define DSI_DYN_REFRESH_PLL_CTRL6 0x02C #define DSI_DYN_REFRESH_PLL_CTRL7 0x030 #define DSI_DYN_REFRESH_PLL_CTRL8 0x034 #define DSI_DYN_REFRESH_PLL_CTRL9 0x038 #define DSI_DYN_REFRESH_PLL_CTRL10 0x03C #define DSI_DYN_REFRESH_PLL_CTRL11 0x040 #define DSI_DYN_REFRESH_PLL_CTRL12 0x044 #define DSI_DYN_REFRESH_PLL_CTRL13 0x048 #define DSI_DYN_REFRESH_PLL_CTRL14 0x04C #define DSI_DYN_REFRESH_PLL_CTRL15 0x050 #define DSI_DYN_REFRESH_PLL_CTRL16 0x054 #define DSI_DYN_REFRESH_PLL_CTRL17 0x058 #define DSI_DYN_REFRESH_PLL_CTRL18 0x05C #define DSI_DYN_REFRESH_PLL_CTRL19 0x060 #define DSI_DYN_REFRESH_PLL_CTRL20 0x064 #define DSI_DYN_REFRESH_PLL_CTRL21 0x068 #define DSI_DYN_REFRESH_PLL_CTRL22 0x06C #define DSI_DYN_REFRESH_PLL_CTRL23 0x070 #define DSI_DYN_REFRESH_PLL_CTRL24 0x074 #define DSI_DYN_REFRESH_PLL_CTRL25 0x078 #define DSI_DYN_REFRESH_PLL_CTRL26 0x07C #define DSI_DYN_REFRESH_PLL_CTRL27 0x080 #define DSI_DYN_REFRESH_PLL_CTRL28 0x084 #define DSI_DYN_REFRESH_PLL_CTRL29 0x088 #define DSI_DYN_REFRESH_PLL_CTRL30 0x08C #define DSI_DYN_REFRESH_PLL_CTRL31 0x090 #define DSI_DYN_REFRESH_PLL_UPPER_ADDR 0x094 #define DSI_DYN_REFRESH_PLL_UPPER_ADDR2 0x098 #define DSIPHY_DLN0_CFG1 0x0104 #define DSIPHY_DLN0_TIMING_CTRL_4 0x0118 #define DSIPHY_DLN0_TIMING_CTRL_5 0x011C #define DSIPHY_DLN0_TIMING_CTRL_6 0x0120 #define DSIPHY_DLN0_TIMING_CTRL_7 0x0124 #define DSIPHY_DLN0_TIMING_CTRL_8 0x0128 #define DSIPHY_DLN1_CFG1 0x0184 #define DSIPHY_DLN1_TIMING_CTRL_4 0x0198 #define DSIPHY_DLN1_TIMING_CTRL_5 0x019C #define DSIPHY_DLN1_TIMING_CTRL_6 0x01A0 #define DSIPHY_DLN1_TIMING_CTRL_7 0x01A4 #define DSIPHY_DLN1_TIMING_CTRL_8 0x01A8 #define DSIPHY_DLN2_CFG1 0x0204 #define DSIPHY_DLN2_TIMING_CTRL_4 0x0218 #define DSIPHY_DLN2_TIMING_CTRL_5 0x021C #define DSIPHY_DLN2_TIMING_CTRL_6 0x0220 #define DSIPHY_DLN2_TIMING_CTRL_7 0x0224 #define DSIPHY_DLN2_TIMING_CTRL_8 0x0228 #define DSIPHY_DLN3_CFG1 0x0284 #define DSIPHY_DLN3_TIMING_CTRL_4 0x0298 #define DSIPHY_DLN3_TIMING_CTRL_5 0x029C #define DSIPHY_DLN3_TIMING_CTRL_6 0x02A0 #define DSIPHY_DLN3_TIMING_CTRL_7 0x02A4 #define DSIPHY_DLN3_TIMING_CTRL_8 0x02A8 #define DSIPHY_CKLN_CFG1 0x0304 #define DSIPHY_CKLN_TIMING_CTRL_4 0x0318 #define DSIPHY_CKLN_TIMING_CTRL_5 0x031C #define DSIPHY_CKLN_TIMING_CTRL_6 0x0320 #define DSIPHY_CKLN_TIMING_CTRL_7 0x0324 #define DSIPHY_CKLN_TIMING_CTRL_8 0x0328 #define DSIPHY_PLL_RESETSM_CNTRL5 0x043c /** * regulator_enable() - enable regulators for DSI PHY * @phy: Pointer to DSI PHY hardware object. * @reg_cfg: Regulator configuration for all DSI lanes. */ void dsi_phy_hw_v2_0_regulator_enable(struct dsi_phy_hw *phy, struct dsi_phy_per_lane_cfgs *reg_cfg) { int i; bool is_split_link = test_bit(DSI_PHY_SPLIT_LINK, phy->feature_map); for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) DSI_W32(phy, DSIPHY_DLNX_VREG_CNTRL(i), reg_cfg->lane[i][0]); if (is_split_link) DSI_W32(phy, DSIPHY_DLNX_VREG_CNTRL(DSI_LOGICAL_CLOCK_LANE+1), reg_cfg->lane[DSI_LOGICAL_CLOCK_LANE][0]); /* make sure all values are written to hardware */ wmb(); DSI_PHY_DBG(phy, "Phy regulators enabled\n"); } /** * regulator_disable() - disable regulators * @phy: Pointer to DSI PHY hardware object. */ void dsi_phy_hw_v2_0_regulator_disable(struct dsi_phy_hw *phy) { DSI_PHY_DBG(phy, "Phy regulators disabled\n"); } /** * enable() - Enable PHY hardware * @phy: Pointer to DSI PHY hardware object. * @cfg: Per lane configurations for timing, strength and lane * configurations. */ void dsi_phy_hw_v2_0_enable(struct dsi_phy_hw *phy, struct dsi_phy_cfg *cfg) { int i, j; struct dsi_phy_per_lane_cfgs *lanecfg = &cfg->lanecfg; struct dsi_phy_per_lane_cfgs *timing = &cfg->timing; struct dsi_phy_per_lane_cfgs *strength = &cfg->strength; u32 data; bool is_split_link = test_bit(DSI_PHY_SPLIT_LINK, phy->feature_map); DSI_W32(phy, DSIPHY_CMN_LDO_CNTRL, 0x1C); DSI_W32(phy, DSIPHY_CMN_GLBL_TEST_CTRL, 0x1); for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) { for (j = 0; j < lanecfg->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_CFG(i, j), lanecfg->lane[i][j]); DSI_W32(phy, DSIPHY_DLNX_TEST_STR(i), 0x88); for (j = 0; j < timing->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_TIMING_CTRL(i, j), timing->lane[i][j]); for (j = 0; j < strength->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_STRENGTH_CTRL(i, j), strength->lane[i][j]); } if (is_split_link) { i = DSI_LOGICAL_CLOCK_LANE; for (j = 0; j < lanecfg->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_CFG(i+1, j), lanecfg->lane[i][j]); DSI_W32(phy, DSIPHY_DLNX_TEST_STR(i+1), 0x0); DSI_W32(phy, DSIPHY_DLNX_TEST_DATAPATH(i+1), 0x88); for (j = 0; j < timing->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_TIMING_CTRL(i+1, j), timing->lane[i][j]); for (j = 0; j < strength->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_STRENGTH_CTRL(i+1, j), strength->lane[i][j]); /* enable split link for cmn clk cfg1 */ data = DSI_R32(phy, DSIPHY_CMN_CLK_CFG1); data |= BIT(1); DSI_W32(phy, DSIPHY_CMN_CLK_CFG1, data); } /* make sure all values are written to hardware before enabling phy */ wmb(); DSI_W32(phy, DSIPHY_CMN_CTRL_1, 0x80); udelay(100); DSI_W32(phy, DSIPHY_CMN_CTRL_1, 0x00); data = DSI_R32(phy, DSIPHY_CMN_GLBL_TEST_CTRL); switch (cfg->pll_source) { case DSI_PLL_SOURCE_STANDALONE: DSI_W32(phy, DSIPHY_PLL_CLKBUFLR_EN, 0x01); data &= ~BIT(2); break; case DSI_PLL_SOURCE_NATIVE: DSI_W32(phy, DSIPHY_PLL_CLKBUFLR_EN, 0x03); data &= ~BIT(2); break; case DSI_PLL_SOURCE_NON_NATIVE: DSI_W32(phy, DSIPHY_PLL_CLKBUFLR_EN, 0x00); data |= BIT(2); break; default: break; } DSI_W32(phy, DSIPHY_CMN_GLBL_TEST_CTRL, data); /* Enable bias current for pll1 during split display case */ if (cfg->pll_source == DSI_PLL_SOURCE_NON_NATIVE) DSI_W32(phy, DSIPHY_PLL_PLL_BANDGAP, 0x3); DSI_PHY_DBG(phy, "Phy enabled\n"); } /** * disable() - Disable PHY hardware * @phy: Pointer to DSI PHY hardware object. */ void dsi_phy_hw_v2_0_disable(struct dsi_phy_hw *phy, struct dsi_phy_cfg *cfg) { DSI_W32(phy, DSIPHY_PLL_CLKBUFLR_EN, 0); DSI_W32(phy, DSIPHY_CMN_GLBL_TEST_CTRL, 0); DSI_W32(phy, DSIPHY_CMN_CTRL_0, 0); DSI_PHY_DBG(phy, "Phy disabled\n"); } /** * dsi_phy_hw_v2_0_idle_on() - Enable DSI PHY hardware during idle screen * @phy: Pointer to DSI PHY hardware object. */ void dsi_phy_hw_v2_0_idle_on(struct dsi_phy_hw *phy, struct dsi_phy_cfg *cfg) { int i = 0, j; struct dsi_phy_per_lane_cfgs *strength = &cfg->strength; bool is_split_link = test_bit(DSI_PHY_SPLIT_LINK, phy->feature_map); for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) { for (j = 0; j < strength->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_STRENGTH_CTRL(i, j), strength->lane[i][j]); } if (is_split_link) { i = DSI_LOGICAL_CLOCK_LANE; for (j = 0; j < strength->count_per_lane; j++) DSI_W32(phy, DSIPHY_DLNX_STRENGTH_CTRL(i+1, j), strength->lane[i][j]); } wmb(); /* make sure write happens */ DSI_PHY_DBG(phy, "Phy enabled out of idle screen\n"); } /** * dsi_phy_hw_v2_0_idle_off() - Disable DSI PHY hardware during idle screen * @phy: Pointer to DSI PHY hardware object. */ void dsi_phy_hw_v2_0_idle_off(struct dsi_phy_hw *phy) { int i = 0; bool is_split_link = test_bit(DSI_PHY_SPLIT_LINK, phy->feature_map); DSI_W32(phy, DSIPHY_CMN_CTRL_0, 0x7f); for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) DSI_W32(phy, DSIPHY_DLNX_VREG_CNTRL(i), 0x1c); if (is_split_link) DSI_W32(phy, DSIPHY_DLNX_VREG_CNTRL(DSI_LOGICAL_CLOCK_LANE+1), 0x1c); DSI_W32(phy, DSIPHY_CMN_LDO_CNTRL, 0x1C); for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) DSI_W32(phy, DSIPHY_DLNX_STRENGTH_CTRL(i, 1), 0x0); if (is_split_link) DSI_W32(phy, DSIPHY_DLNX_STRENGTH_CTRL(DSI_LOGICAL_CLOCK_LANE+1, 1), 0x0); wmb(); /* make sure write happens */ DSI_PHY_DBG(phy, "Phy disabled during idle screen\n"); } int dsi_phy_hw_timing_val_v2_0(struct dsi_phy_per_lane_cfgs *timing_cfg, u32 *timing_val, u32 size) { int i = 0, j = 0; if (size != (DSI_LANE_MAX * DSI_MAX_SETTINGS)) { DSI_ERR("Unexpected timing array size %d\n", size); return -EINVAL; } for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) { for (j = 0; j < DSI_MAX_SETTINGS; j++) { timing_cfg->lane[i][j] = *timing_val; timing_val++; } } return 0; } void dsi_phy_hw_v2_0_clamp_ctrl(struct dsi_phy_hw *phy, bool enable) { u32 clamp_reg = 0; if (!phy->phy_clamp_base) { DSI_PHY_DBG(phy, "phy_clamp_base NULL\n"); return; } if (enable) { clamp_reg |= BIT(0); DSI_MISC_W32(phy, DSI_MDP_ULPS_CLAMP_ENABLE_OFF, clamp_reg); DSI_PHY_DBG(phy, "clamp enabled\n"); } else { clamp_reg &= ~BIT(0); DSI_MISC_W32(phy, DSI_MDP_ULPS_CLAMP_ENABLE_OFF, clamp_reg); DSI_PHY_DBG(phy, "clamp disabled\n"); } } void dsi_phy_hw_v2_0_dyn_refresh_config(struct dsi_phy_hw *phy, struct dsi_phy_cfg *cfg, bool is_master) { u32 glbl_tst_cntrl; if (is_master) { glbl_tst_cntrl = DSI_R32(phy, DSIPHY_CMN_GLBL_TEST_CTRL); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL0, DSIPHY_CMN_GLBL_TEST_CTRL, DSIPHY_PLL_PLL_BANDGAP, glbl_tst_cntrl | BIT(1), 0x1); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL1, DSIPHY_PLL_RESETSM_CNTRL5, DSIPHY_PLL_PLL_BANDGAP, 0x0D, 0x03); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL2, DSIPHY_PLL_RESETSM_CNTRL5, DSIPHY_CMN_PLL_CNTRL, 0x1D, 0x00); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL3, DSIPHY_CMN_CTRL_1, DSIPHY_DLN0_CFG1, 0x20, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL4, DSIPHY_DLN1_CFG1, DSIPHY_DLN2_CFG1, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL5, DSIPHY_DLN3_CFG1, DSIPHY_CKLN_CFG1, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL6, DSIPHY_DLN0_TIMING_CTRL_4, DSIPHY_DLN1_TIMING_CTRL_4, cfg->timing.lane[0][0], cfg->timing.lane[1][0]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL7, DSIPHY_DLN2_TIMING_CTRL_4, DSIPHY_DLN3_TIMING_CTRL_4, cfg->timing.lane[2][0], cfg->timing.lane[3][0]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL8, DSIPHY_CKLN_TIMING_CTRL_4, DSIPHY_DLN0_TIMING_CTRL_5, cfg->timing.lane[4][0], cfg->timing.lane[0][1]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL9, DSIPHY_DLN1_TIMING_CTRL_5, DSIPHY_DLN2_TIMING_CTRL_5, cfg->timing.lane[1][1], cfg->timing.lane[2][1]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL10, DSIPHY_DLN3_TIMING_CTRL_5, DSIPHY_CKLN_TIMING_CTRL_5, cfg->timing.lane[3][1], cfg->timing.lane[4][1]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL11, DSIPHY_DLN0_TIMING_CTRL_6, DSIPHY_DLN1_TIMING_CTRL_6, cfg->timing.lane[0][2], cfg->timing.lane[1][2]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL12, DSIPHY_DLN2_TIMING_CTRL_6, DSIPHY_DLN3_TIMING_CTRL_6, cfg->timing.lane[2][2], cfg->timing.lane[3][2]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL13, DSIPHY_CKLN_TIMING_CTRL_6, DSIPHY_DLN0_TIMING_CTRL_7, cfg->timing.lane[4][2], cfg->timing.lane[0][3]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL14, DSIPHY_DLN1_TIMING_CTRL_7, DSIPHY_DLN2_TIMING_CTRL_7, cfg->timing.lane[1][3], cfg->timing.lane[2][3]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL15, DSIPHY_DLN3_TIMING_CTRL_7, DSIPHY_CKLN_TIMING_CTRL_7, cfg->timing.lane[3][3], cfg->timing.lane[4][3]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL16, DSIPHY_DLN0_TIMING_CTRL_8, DSIPHY_DLN1_TIMING_CTRL_8, cfg->timing.lane[0][4], cfg->timing.lane[1][4]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL17, DSIPHY_DLN2_TIMING_CTRL_8, DSIPHY_DLN3_TIMING_CTRL_8, cfg->timing.lane[2][4], cfg->timing.lane[3][4]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL18, DSIPHY_CKLN_TIMING_CTRL_8, DSIPHY_CMN_CTRL_1, cfg->timing.lane[4][4], 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL30, DSIPHY_CMN_GLBL_TEST_CTRL, DSIPHY_CMN_GLBL_TEST_CTRL, ((glbl_tst_cntrl) & (~BIT(2))), ((glbl_tst_cntrl) & (~BIT(2)))); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL31, DSIPHY_CMN_GLBL_TEST_CTRL, DSIPHY_CMN_GLBL_TEST_CTRL, ((glbl_tst_cntrl) & (~BIT(2))), ((glbl_tst_cntrl) & (~BIT(2)))); } else { DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL0, DSIPHY_DLN0_CFG1, DSIPHY_DLN1_CFG1, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL1, DSIPHY_DLN2_CFG1, DSIPHY_DLN3_CFG1, 0x0, 0x0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL2, DSIPHY_CKLN_CFG1, DSIPHY_DLN0_TIMING_CTRL_4, 0x0, cfg->timing.lane[0][0]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL3, DSIPHY_DLN1_TIMING_CTRL_4, DSIPHY_DLN2_TIMING_CTRL_4, cfg->timing.lane[1][0], cfg->timing.lane[2][0]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL4, DSIPHY_DLN3_TIMING_CTRL_4, DSIPHY_CKLN_TIMING_CTRL_4, cfg->timing.lane[3][0], cfg->timing.lane[4][0]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL5, DSIPHY_DLN0_TIMING_CTRL_5, DSIPHY_DLN1_TIMING_CTRL_5, cfg->timing.lane[0][1], cfg->timing.lane[1][1]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL6, DSIPHY_DLN2_TIMING_CTRL_5, DSIPHY_DLN3_TIMING_CTRL_5, cfg->timing.lane[2][1], cfg->timing.lane[3][1]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL7, DSIPHY_CKLN_TIMING_CTRL_5, DSIPHY_DLN0_TIMING_CTRL_6, cfg->timing.lane[4][1], cfg->timing.lane[0][2]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL8, DSIPHY_DLN1_TIMING_CTRL_6, DSIPHY_DLN2_TIMING_CTRL_6, cfg->timing.lane[1][2], cfg->timing.lane[2][2]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL9, DSIPHY_DLN3_TIMING_CTRL_6, DSIPHY_CKLN_TIMING_CTRL_6, cfg->timing.lane[3][2], cfg->timing.lane[4][2]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL10, DSIPHY_DLN0_TIMING_CTRL_7, DSIPHY_DLN1_TIMING_CTRL_7, cfg->timing.lane[0][3], cfg->timing.lane[1][3]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL11, DSIPHY_DLN2_TIMING_CTRL_7, DSIPHY_DLN3_TIMING_CTRL_7, cfg->timing.lane[2][3], cfg->timing.lane[3][3]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL12, DSIPHY_CKLN_TIMING_CTRL_7, DSIPHY_DLN0_TIMING_CTRL_8, cfg->timing.lane[4][3], cfg->timing.lane[0][4]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL13, DSIPHY_DLN1_TIMING_CTRL_8, DSIPHY_DLN2_TIMING_CTRL_8, cfg->timing.lane[1][4], cfg->timing.lane[2][4]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL14, DSIPHY_DLN3_TIMING_CTRL_8, DSIPHY_CKLN_TIMING_CTRL_8, cfg->timing.lane[3][4], cfg->timing.lane[4][4]); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL15, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL16, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL17, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL18, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL19, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL20, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL21, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL22, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL23, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL24, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL25, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL26, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL27, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL28, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL29, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL30, 0x0110, 0x0110, 0, 0); DSI_DYN_REF_REG_W(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_CTRL31, 0x0110, 0x0110, 0, 0); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_UPPER_ADDR, 0x0); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_UPPER_ADDR2, 0x0); } wmb(); /* make sure phy timings are updated*/ } void dsi_phy_hw_v2_0_dyn_refresh_pipe_delay(struct dsi_phy_hw *phy, struct dsi_dyn_clk_delay *delay) { if (!delay) return; DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_PIPE_DELAY, delay->pipe_delay); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_PIPE_DELAY2, delay->pipe_delay2); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_PLL_DELAY, delay->pll_delay); } void dsi_phy_hw_v2_0_dyn_refresh_helper(struct dsi_phy_hw *phy, u32 offset) { u32 reg; /* * if no offset is mentioned then this means we want to clear * the dynamic refresh ctrl register which is the last step * of dynamic refresh sequence. */ if (!offset) { reg = DSI_GEN_R32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL); reg &= ~(BIT(0) | BIT(8)); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL, reg); wmb(); /* ensure dynamic fps is cleared */ return; } if (offset & BIT(DYN_REFRESH_INTF_SEL)) { reg = DSI_GEN_R32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL); reg |= BIT(13); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL, reg); } if (offset & BIT(DYN_REFRESH_SWI_CTRL)) { reg = DSI_GEN_R32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL); reg |= BIT(0); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL, reg); } if (offset & BIT(DYN_REFRESH_SW_TRIGGER)) { reg = DSI_GEN_R32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL); reg |= BIT(8); DSI_GEN_W32(phy->dyn_pll_base, DSI_DYN_REFRESH_CTRL, reg); wmb(); /* ensure dynamic fps is triggered */ } } int dsi_phy_hw_v2_0_cache_phy_timings(struct dsi_phy_per_lane_cfgs *timings, u32 *dst, u32 size) { int i, j, count = 0; if (!timings || !dst || !size) return -EINVAL; if (size != (DSI_LANE_MAX * DSI_MAX_SETTINGS)) { pr_err("size mis-match\n"); return -EINVAL; } for (i = DSI_LOGICAL_LANE_0; i < DSI_LANE_MAX; i++) { for (j = 0; j < DSI_MAX_SETTINGS; j++) { dst[count] = timings->lane[i][j]; count++; } } return 0; }