/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #define HAL_DSI_PHY_PLL_READY_TIMEOUT_MS 150 /* ~15 ms */ #define HAL_DSI_PHY_REFGEN_TIMEOUT_MS 150 /* ~15 ms */ #define DSI_MAX_REFRESH_RATE 95 #define DSI_MIN_REFRESH_RATE 15 #define HAL_DSI_PLL_VCO_MIN_MHZ_2_2_0 1000 #define S_DIV_ROUND_UP(n, d) \ (((n) >= 0) ? (((n) + (d) - 1) / (d)) : (((n) - (d) + 1) / (d))) #define mult_frac(x, numer, denom)( \ { \ typeof(x) quot = (x) / (denom); \ typeof(x) rem = (x) % (denom); \ (quot * (numer)) + ((rem * (numer)) / (denom)); \ } \ ) struct dsi_phy_divider_lut_entry_type { uint16_t pll_post_div; uint16_t phy_post_div; }; /* PLL divider LUTs */ static struct dsi_phy_divider_lut_entry_type pll_dividerlut_dphy[] = { /* pll post div will always be power of 2 */ { 2, 11 }, { 4, 5 }, { 2, 9 }, { 8, 2 }, { 1, 15 }, { 2, 7 }, { 1, 13 }, { 4, 3 }, { 1, 11 }, { 2, 5 }, { 1, 9 }, { 8, 1 }, { 1, 7 }, { 2, 3 }, { 1, 5 }, { 4, 1 }, { 1, 3 }, { 2, 1 }, { 1, 1 } }; enum dsi_laneid_type { DSI_LANEID_0 = 0, DSI_LANEID_1, DSI_LANEID_2, DSI_LANEID_3, DSI_LANEID_CLK, DSI_LANEID_MAX, DSI_LANEID_FORCE_32BIT = 0x7FFFFFFF }; struct dsi_phy_configtype { uint32_t desired_bitclk_freq; uint32_t bits_per_pixel; uint32_t num_data_lanes; uint32_t pclk_divnumerator; uint32_t pclk_divdenominator; /* pixel clk source select */ uint32_t phy_post_div; uint32_t pll_post_div; }; static inline s32 linear_inter(s32 tmax, s32 tmin, s32 percent, s32 min_result, bool even) { s32 v; v = (tmax - tmin) * percent; v = S_DIV_ROUND_UP(v, 100) + tmin; if (even && (v & 0x1)) return MAX(min_result, v - 1); return MAX(min_result, v); } static void mdss_dsi_phy_reset(void) { write32(&dsi0_phy->phy_cmn_ctrl1, 0x40); udelay(100); write32(&dsi0_phy->phy_cmn_ctrl1, 0x0); } static void mdss_dsi_power_down(void) { /* power up DIGTOP & PLL */ write32(&dsi0_phy->phy_cmn_ctrl0, 0x60); /* Disable PLL */ write32(&dsi0_phy->phy_cmn_pll_ctrl, 0x0); /* Resync re-time FIFO OFF*/ write32(&dsi0_phy->phy_cmn_rbuf_ctrl, 0x0); } static void mdss_dsi_phy_setup_lanephy(enum dsi_laneid_type lane) { uint32_t reg_val = 0; uint32_t lprx_ctrl = 0; uint32_t hstx_strength = 0x88; uint32_t data_strength_lp_n = 0x5; uint32_t data_strength_lp_p = 0x5; uint32_t pemph_bottom = 0; uint32_t pemph_top = 0; uint32_t strength_override = 0; uint32_t clk_lane = 0; if (lane == DSI_LANEID_CLK) clk_lane = 1; else clk_lane = 0; if (lane == DSI_LANEID_0) lprx_ctrl = 3; /* * DSIPHY_STR_LP_N * DSIPHY_STR_LP_P */ reg_val = ((data_strength_lp_n << 0x4) & 0xf0) | (data_strength_lp_p & 0x0f); write32(&dsi0_phy->phy_ln_regs[lane].dln0_lptx_str_ctrl, reg_val); /* * DSIPHY_LPRX_EN * DSIPHY_CDRX_EN * Transition from 0 to 1 for DLN0-3 CLKLN stays 0 */ write32(&dsi0_phy->phy_ln_regs[lane].dln0_lprx_ctrl, 0x0); write32(&dsi0_phy->phy_ln_regs[lane].dln0_lprx_ctrl, lprx_ctrl); /* Pin Swap */ write32(&dsi0_phy->phy_ln_regs[lane].dln0_pin_swap, 0x0); /* * DSIPHY_HSTX_STR_HSTOP * DSIPHY_HSTX_STR_HSBOT */ write32(&dsi0_phy->phy_ln_regs[lane].dln0_hstx_str_ctrl, hstx_strength); /* PGM Delay */ write32(&dsi0_phy->phy_ln_regs[lane].dln0_cfg[0], 0x0); /* DLN0_CFG1 */ reg_val = (strength_override << 0x5) & 0x20; write32(&dsi0_phy->phy_ln_regs[lane].dln0_cfg[1], reg_val); /* DLN0_CFG2 */ reg_val = ((pemph_bottom << 0x04) & 0xf0) | (pemph_top & 0x0f); write32(&dsi0_phy->phy_ln_regs[lane].dln0_cfg[2], reg_val); write32(&dsi0_phy->phy_ln_regs[lane].dln0_offset_top_ctrl, 0x0); write32(&dsi0_phy->phy_ln_regs[lane].dln0_offset_bot_ctrl, 0x0); /* * DSIPHY_LPRX_DLY * IS_CKLANE */ reg_val = (clk_lane << 0x07) & 0x80; write32(&dsi0_phy->phy_ln_regs[lane].dln0_cfg[3], reg_val); reg_val = 0; if (lane == DSI_LANEID_CLK) reg_val = 1; write32(&dsi0_phy->phy_ln_regs[lane].dln0_tx_dctrl, reg_val); } static void mdss_dsi_calculate_phy_timings(struct msm_dsi_phy_ctrl *timing, struct dsi_phy_configtype *phy_cfg) { const unsigned long bit_rate = phy_cfg->desired_bitclk_freq; s32 ui, ui_x8; s32 tmax, tmin; s32 pcnt0 = 50; s32 pcnt1 = 50; s32 pcnt2 = 10; s32 pcnt3 = 30; s32 pcnt4 = 10; s32 pcnt5 = 2; s32 coeff = 1000; /* Precision, should avoid overflow */ s32 hb_en, hb_en_ckln; s32 temp; if (!bit_rate) return; hb_en = 0; timing->half_byte_clk_en = 0; hb_en_ckln = 0; ui = mult_frac(1000000, coeff, bit_rate / 1000); ui_x8 = ui << 3; temp = S_DIV_ROUND_UP(38 * coeff, ui_x8); tmin = MAX(temp, 0); temp = (95 * coeff) / ui_x8; tmax = MAX(temp, 0); timing->clk_prepare = linear_inter(tmax, tmin, pcnt0, 0, false); temp = 300 * coeff - (timing->clk_prepare << 3) * ui; tmin = S_DIV_ROUND_UP(temp, ui_x8) - 1; tmax = (tmin > 255) ? 511 : 255; timing->clk_zero = linear_inter(tmax, tmin, pcnt5, 0, false); tmin = DIV_ROUND_UP(60 * coeff + 3 * ui, ui_x8); temp = 105 * coeff + 12 * ui - 20 * coeff; tmax = (temp + 3 * ui) / ui_x8; timing->clk_trail = linear_inter(tmax, tmin, pcnt3, 0, false); temp = S_DIV_ROUND_UP(40 * coeff + 4 * ui, ui_x8); tmin = MAX(temp, 0); temp = (85 * coeff + 6 * ui) / ui_x8; tmax = MAX(temp, 0); timing->hs_prepare = linear_inter(tmax, tmin, pcnt1, 0, false); temp = 145 * coeff + 10 * ui - (timing->hs_prepare << 3) * ui; tmin = S_DIV_ROUND_UP(temp, ui_x8) - 1; tmax = 255; timing->hs_zero = linear_inter(tmax, tmin, pcnt4, 0, false); tmin = DIV_ROUND_UP(60 * coeff + 4 * ui, ui_x8) - 1; temp = 105 * coeff + 12 * ui - 20 * coeff; tmax = (temp / ui_x8) - 1; timing->hs_trail = linear_inter(tmax, tmin, pcnt3, 0, false); temp = 50 * coeff + ((hb_en << 2) - 8) * ui; timing->hs_rqst = S_DIV_ROUND_UP(temp, ui_x8); tmin = DIV_ROUND_UP(100 * coeff, ui_x8) - 1; tmax = 255; timing->hs_exit = linear_inter(tmax, tmin, pcnt2, 0, false); temp = 50 * coeff + ((hb_en_ckln << 2) - 8) * ui; timing->hs_rqst = S_DIV_ROUND_UP(temp, ui_x8); temp = 60 * coeff + 52 * ui - 43 * ui; tmin = DIV_ROUND_UP(temp, ui_x8) - 1; tmax = 63; timing->clk_post = linear_inter(tmax, tmin, pcnt2, 0, false); temp = 8 * ui + (timing->clk_prepare << 3) * ui; temp += (((timing->clk_zero + 3) << 3) + 11) * ui; temp += hb_en_ckln ? (((timing->hs_rqst << 3) + 4) * ui) : (((timing->hs_rqst << 3) + 8) * ui); tmin = S_DIV_ROUND_UP(temp, ui_x8) - 1; tmax = 63; if (tmin > tmax) { temp = linear_inter(tmax << 1, tmin, pcnt2, 0, false); timing->clk_pre = temp >> 1; timing->clk_pre_inc_by_2 = 1; } else { timing->clk_pre = linear_inter(tmax, tmin, pcnt2, 0, false); timing->clk_pre_inc_by_2 = 0; } timing->ta_go = 3; timing->ta_sure = 0; timing->ta_get = 4; printk(BIOS_INFO, "PHY timings: %d, %d, %d, %d, %d, %d, %d, %d, %d, %d, %d\n", timing->clk_pre, timing->clk_post, timing->clk_pre_inc_by_2, timing->clk_zero, timing->clk_trail, timing->clk_prepare, timing->hs_exit, timing->hs_zero, timing->hs_prepare, timing->hs_trail, timing->hs_rqst); } static enum cb_err mdss_dsi_phy_timings(struct msm_dsi_phy_ctrl *phy_timings) { uint32_t reg_val = 0; /* * Step 4 Common block including GlobalTiming Parameters * BYTECLK_SEL */ reg_val = (0x02 << 3) & 0x18; write32(&dsi0_phy->phy_cmn_glbl_ctrl, reg_val); /* VREG_CTRL */ write32(&dsi0_phy->phy_cmn_vreg_ctrl, 0x59); /*HALFBYTECLK_EN*/ write32(&dsi0_phy->phy_cmn_timing_ctrl[0], phy_timings->half_byte_clk_en); /* T_CLK_ZERO */ write32(&dsi0_phy->phy_cmn_timing_ctrl[1], phy_timings->clk_zero); /* T_CLK_PREPARE */ write32(&dsi0_phy->phy_cmn_timing_ctrl[2], phy_timings->clk_prepare); /* T_CLK_TRAIL */ write32(&dsi0_phy->phy_cmn_timing_ctrl[3], phy_timings->clk_trail); /* T_HS_EXIT */ write32(&dsi0_phy->phy_cmn_timing_ctrl[4], phy_timings->hs_exit); /* T_HS_ZERO */ write32(&dsi0_phy->phy_cmn_timing_ctrl[5], phy_timings->hs_zero); /* T_HS_PREPARE */ write32(&dsi0_phy->phy_cmn_timing_ctrl[6], phy_timings->hs_prepare); /* T_HS_TRAIL */ write32(&dsi0_phy->phy_cmn_timing_ctrl[7], phy_timings->hs_trail); /* T_HS_RQST */ write32(&dsi0_phy->phy_cmn_timing_ctrl[8], phy_timings->hs_rqst); /* T_TA_GO & T_TA_SURE */ write32(&dsi0_phy->phy_cmn_timing_ctrl[9], phy_timings->ta_sure << 3 | phy_timings->ta_go); /* T_TA_GET */ write32(&dsi0_phy->phy_cmn_timing_ctrl[10], phy_timings->ta_get); /*DSIPHY_TRIG3_CMD*/ write32(&dsi0_phy->phy_cmn_timing_ctrl[11], 0x0); /* DSI clock out timing ctrl T_CLK_PRE & T_CLK_POST*/ reg_val = ((phy_timings->clk_post << 8) | phy_timings->clk_pre); write32(&dsi0->clkout_timing_ctrl, reg_val); /* DCTRL */ write32(&dsi0_phy->phy_cmn_ctrl2, 0x40); return CB_SUCCESS; } static enum cb_err dsi_phy_waitforrefgen(void) { uint32_t timeout = HAL_DSI_PHY_REFGEN_TIMEOUT_MS; uint32_t refgen = 0; enum cb_err ret = CB_SUCCESS; while (!refgen) { refgen = (read32(&dsi0_phy->phy_cmn_phy_status) & 0x1); if (!refgen) { udelay(100); timeout--; if (!timeout) { /* timeout while polling the lock status */ ret = CB_ERR; break; } } } return ret; } static enum cb_err mdss_dsi_phy_commit(void) { enum cb_err ret = CB_SUCCESS; ret = dsi_phy_waitforrefgen(); if (ret) { printk(BIOS_ERR, "%s: waitforrefgen error\n", __func__); return ret; } mdss_dsi_power_down(); /* Remove PLL, DIG and all lanes from pwrdn */ write32(&dsi0_phy->phy_cmn_ctrl0, 0x7F); /* Lane enable */ write32(&dsi0_phy->phy_cmn_dsi_lane_ctrl0, 0x1F); mdss_dsi_phy_setup_lanephy(DSI_LANEID_0); mdss_dsi_phy_setup_lanephy(DSI_LANEID_1); mdss_dsi_phy_setup_lanephy(DSI_LANEID_2); mdss_dsi_phy_setup_lanephy(DSI_LANEID_3); mdss_dsi_phy_setup_lanephy(DSI_LANEID_CLK); return ret; } static void mdss_dsi_phy_setup(void) { /* First reset phy */ mdss_dsi_phy_reset(); /* commit phy settings */ mdss_dsi_phy_commit(); } static void dsi_phy_resync_fifo(void) { /* Resync FIFO*/ write32(&dsi0_phy->phy_cmn_rbuf_ctrl, 0x1); } static void dsi_phy_pll_global_clk_enable(bool enable) { uint32_t clk_cfg = read32(&dsi0_phy->phy_cmn_clk_cfg1); uint32_t clk_enable = 0; /* Set CLK_EN */ if (enable) clk_enable = 1; clk_cfg &= ~0x20; clk_cfg |= ((clk_enable << 0x5) & 0x20); /* clk cfg1 */ write32(&dsi0_phy->phy_cmn_clk_cfg1, clk_cfg); } static enum cb_err dsi_phy_pll_lock_detect(void) { enum cb_err ret = CB_SUCCESS; /* Enable PLL */ write32(&dsi0_phy->phy_cmn_pll_ctrl, 0x1); /* Wait for Lock */ if (!wait_us(15000, read32(&phy_pll_qlink->pll_common_status_one) & 0x1)) { /* timeout while polling the lock status */ ret = CB_ERR; printk(BIOS_ERR, "dsi pll lock detect timedout, error.\n"); } return ret; } static void dsi_phy_toggle_dln3_tx_dctrl(void) { uint32_t reg_val = 0; reg_val = read32(&dsi0_phy->phy_ln_regs[DSI_LANEID_3].dln0_tx_dctrl); /* clear bit 0 and keep all other bits including bit 2 */ reg_val &= ~0x01; /* toggle bit 0 */ write32(&dsi0_phy->phy_ln_regs[DSI_LANEID_3].dln0_tx_dctrl, (0x01 | reg_val)); write32(&dsi0_phy->phy_ln_regs[DSI_LANEID_3].dln0_tx_dctrl, 0x4); } static void dsi_phy_pll_set_source(void) { uint32_t clk_cfg = read32(&dsi0_phy->phy_cmn_clk_cfg1); uint32_t dsi_clksel = 1; clk_cfg &= ~0x03; clk_cfg |= ((dsi_clksel) & 0x3); /* clk cfg1 */ write32(&dsi0_phy->phy_cmn_clk_cfg1, clk_cfg); } static void dsi_phy_pll_bias_enable(bool enable) { uint32_t reg_val = 0; /* Set BIAS_EN_MUX, BIAS_EN */ if (enable) reg_val = (0x01 << 6) | (0x01 << 7); /* pll system muxes */ write32(&phy_pll_qlink->pll_system_muxes, reg_val); } static void dsi_phy_mnd_divider(struct dsi_phy_configtype *phy_cfg) { uint32_t m_val = 1; uint32_t n_val = 1; if (phy_cfg->bits_per_pixel == 18) { switch (phy_cfg->num_data_lanes) { case 1: case 2: m_val = 2; n_val = 3; break; case 4: m_val = 4; n_val = 9; break; default: break; } } else if ((phy_cfg->bits_per_pixel == 16) && (phy_cfg->num_data_lanes == 3)) { m_val = 3; n_val = 8; } else if ((phy_cfg->bits_per_pixel == 30) && (phy_cfg->num_data_lanes == 4)) { m_val = 2; n_val = 3; } /*Save M/N info */ phy_cfg->pclk_divnumerator = m_val; phy_cfg->pclk_divdenominator = n_val; } static uint32_t dsi_phy_dsiclk_divider(struct dsi_phy_configtype *phy_cfg) { uint32_t m_val = phy_cfg->pclk_divnumerator; uint32_t n_val = phy_cfg->pclk_divdenominator; uint32_t div_ctrl = 0; div_ctrl = (m_val * phy_cfg->bits_per_pixel) / (n_val * phy_cfg->num_data_lanes * 2); return div_ctrl; } static unsigned long dsi_phy_calc_clk_divider(struct dsi_phy_configtype *phy_cfg) { bool div_found = false; uint32_t m_val = 1; uint32_t n_val = 1; uint32_t div_ctrl = 0; uint32_t reg_val = 0; uint32_t pll_post_div = 0; uint32_t phy_post_div = 0; uint64_t vco_freq_hz = 0; uint64_t fval = 0; uint64_t pll_output_freq_hz; uint64_t desired_bitclk_hz; uint64_t min_vco_freq_hz = 0; uint32_t lut_max; int i; struct dsi_phy_divider_lut_entry_type *lut; /* use 1000Mhz */ min_vco_freq_hz = (HAL_DSI_PLL_VCO_MIN_MHZ_2_2_0 * 1000000); dsi_phy_mnd_divider(phy_cfg); m_val = phy_cfg->pclk_divnumerator; n_val = phy_cfg->pclk_divdenominator; /* Desired clock in MHz */ desired_bitclk_hz = (uint64_t)phy_cfg->desired_bitclk_freq; /* D Phy */ lut = pll_dividerlut_dphy; lut_max = sizeof(pll_dividerlut_dphy) / sizeof(*lut); lut += (lut_max - 1); /* PLL Post Div - from LUT * Check the LUT in reverse order */ for (i = lut_max - 1; i >= 0; i--, lut--) { fval = (uint64_t)lut->phy_post_div * (uint64_t)lut->pll_post_div; if (fval) { if ((desired_bitclk_hz * fval) > min_vco_freq_hz) { /* Range found */ pll_post_div = lut->pll_post_div; phy_post_div = lut->phy_post_div; div_found = true; break; } } } if (div_found) { phy_cfg->pll_post_div = pll_post_div; phy_cfg->phy_post_div = phy_post_div; /*div_ctrl_7_4 */ div_ctrl = dsi_phy_dsiclk_divider(phy_cfg); /* DIV_CTRL_7_4 DIV_CTRL_3_0 * (DIV_CTRL_3_0 = PHY post divider ratio) */ reg_val = (div_ctrl << 0x04) & 0xf0; reg_val |= (phy_post_div & 0x0f); write32(&dsi0_phy->phy_cmn_clk_cfg0, reg_val); /* PLL output frequency = desired_bitclk_hz * phy_post_div */ pll_output_freq_hz = desired_bitclk_hz * phy_post_div; /* VCO output freq*/ vco_freq_hz = pll_output_freq_hz * pll_post_div; } return (unsigned long)vco_freq_hz; } static void dsi_phy_pll_outputdiv_rate(struct dsi_phy_configtype *pll_cfg) { /* Output divider */ uint32_t pll_post_div = 0; uint32_t reg_val = 0; pll_post_div = log2(pll_cfg->pll_post_div); reg_val = pll_post_div & 0x3; write32(&phy_pll_qlink->pll_outdiv_rate, reg_val); } static enum cb_err dsi_phy_pll_calcandcommit(struct dsi_phy_configtype *phy_cfg) { unsigned long vco_freq_hz; enum cb_err ret = CB_SUCCESS; /* validate input parameters */ if (!phy_cfg) { return CB_ERR; } else if ((phy_cfg->bits_per_pixel != 16) && (phy_cfg->bits_per_pixel != 18) && (phy_cfg->bits_per_pixel != 24)) { /* Unsupported pixel bit depth */ return CB_ERR; } else if ((phy_cfg->num_data_lanes == 0) || (phy_cfg->num_data_lanes > 4)) { /* Illegal number of DSI data lanes */ return CB_ERR; } vco_freq_hz = dsi_phy_calc_clk_divider(phy_cfg); if (!vco_freq_hz) { /* bitclock too low - unsupported */ printk(BIOS_ERR, "vco_freq_hz is 0, unsupported\n"); return CB_ERR; } /* Enable PLL bias */ dsi_phy_pll_bias_enable(true); /* Set byte clk source */ dsi_phy_pll_set_source(); dsi_phy_pll_outputdiv_rate(phy_cfg); dsi_phy_pll_vco_10nm_set_rate(vco_freq_hz); dsi_phy_toggle_dln3_tx_dctrl(); /* Steps 6,7 Start PLL & Lock */ if (ret == CB_SUCCESS) ret = dsi_phy_pll_lock_detect(); /* Step 8 - Resync Data Paths */ if (ret == CB_SUCCESS) { /* Global clock enable */ dsi_phy_pll_global_clk_enable(true); /* Resync FIFOs */ dsi_phy_resync_fifo(); } return ret; } static uint32_t dsi_calc_desired_bitclk(struct edid *edid, uint32_t num_lines, uint32_t bpp) { uint64_t desired_bclk = 0; uint32_t pixel_clock_in_hz; pixel_clock_in_hz = edid->mode.pixel_clock * KHz; if (num_lines) { desired_bclk = pixel_clock_in_hz * (uint64_t)bpp; desired_bclk = desired_bclk/(uint64_t)(num_lines); } printk(BIOS_INFO, "Desired bitclock: %uHz\n", (uint32_t)desired_bclk); return (uint32_t)desired_bclk; } static enum cb_err mdss_dsi_phy_pll_setup(struct edid *edid, uint32_t num_of_lanes, uint32_t bpp) { struct dsi_phy_configtype phy_cfg; struct msm_dsi_phy_ctrl phy_timings; enum cb_err ret; /* Setup the PhyStructure */ memset(&phy_cfg, 0, sizeof(struct dsi_phy_configtype)); memset(&phy_timings, 0, sizeof(struct msm_dsi_phy_ctrl)); phy_cfg.bits_per_pixel = bpp; phy_cfg.num_data_lanes = num_of_lanes; /* desired DSI PLL bit clk freq in Hz */ phy_cfg.desired_bitclk_freq = dsi_calc_desired_bitclk(edid, num_of_lanes, bpp); ret = dsi_phy_pll_calcandcommit(&phy_cfg); if (ret) return ret; mdss_dsi_calculate_phy_timings(&phy_timings, &phy_cfg); ret = mdss_dsi_phy_timings(&phy_timings); return ret; } static enum cb_err enable_dsi_clk(void) { enum cb_err ret; uint32_t i = 0; struct mdp_external_clock_entry clks[] = { {.clk_type = MDSS_CLK_ESC0, .clk_secondary_source = 1}, {.clk_type = MDSS_CLK_PCLK0, .clk_source = 1}, {.clk_type = MDSS_CLK_BYTE0, .clk_source = 1}, {.clk_type = MDSS_CLK_BYTE0_INTF, .clk_source = 1, .clk_div = 2, .source_div = 2}, }; for (i = 0; i < ARRAY_SIZE(clks); i++) { /* Set Ext Source */ ret = mdss_clock_configure(clks[i].clk_type, clks[i].clk_source, clks[i].clk_div, clks[i].clk_pll_m, clks[i].clk_pll_n, clks[i].clk_pll_2d); if (ret) { printk(BIOS_ERR, "mdss_clock_configure failed for %u\n", clks[i].clk_type); return CB_ERR; } ret = mdss_clock_enable(clks[i].clk_type); if (ret) { printk(BIOS_ERR, "mdss_clock_enable failed for %u\n", clks[i].clk_type); return CB_ERR; } } return ret; } enum cb_err mdss_dsi_phy_10nm_init(struct edid *edid, uint32_t num_of_lanes, uint32_t bpp) { enum cb_err ret; /* Phy set up */ mdss_dsi_phy_setup(); ret = mdss_dsi_phy_pll_setup(edid, num_of_lanes, bpp); enable_dsi_clk(); return ret; }