Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Raphael GALLAIS-POU - foss | 5199 | 99.98% | 1 | 50.00% |
Linus Torvalds | 1 | 0.02% | 1 | 50.00% |
Total | 5200 | 2 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2023, STMicroelectronics - All Rights Reserved * Author(s): Raphaël GALLAIS-POU <raphael.gallais-pou@foss.st.com> for STMicroelectronics. */ #include <drm/drm_atomic_helper.h> #include <drm/drm_bridge.h> #include <drm/drm_device.h> #include <drm/drm_of.h> #include <drm/drm_panel.h> #include <drm/drm_print.h> #include <drm/drm_probe_helper.h> #include <linux/clk.h> #include <linux/clk-provider.h> #include <linux/io.h> #include <linux/iopoll.h> #include <linux/media-bus-format.h> #include <linux/module.h> #include <linux/of_device.h> #include <linux/platform_device.h> #include <linux/reset.h> /* LVDS Host registers */ #define LVDS_CR 0x0000 /* configuration register */ #define LVDS_DMLCR0 0x0004 /* data mapping lsb configuration register 0 */ #define LVDS_DMMCR0 0x0008 /* data mapping msb configuration register 0 */ #define LVDS_DMLCR1 0x000C /* data mapping lsb configuration register 1 */ #define LVDS_DMMCR1 0x0010 /* data mapping msb configuration register 1 */ #define LVDS_DMLCR2 0x0014 /* data mapping lsb configuration register 2 */ #define LVDS_DMMCR2 0x0018 /* data mapping msb configuration register 2 */ #define LVDS_DMLCR3 0x001C /* data mapping lsb configuration register 3 */ #define LVDS_DMMCR3 0x0020 /* data mapping msb configuration register 3 */ #define LVDS_DMLCR4 0x0024 /* data mapping lsb configuration register 4 */ #define LVDS_DMMCR4 0x0028 /* data mapping msb configuration register 4 */ #define LVDS_CDL1CR 0x002C /* channel distrib link 1 configuration register */ #define LVDS_CDL2CR 0x0030 /* channel distrib link 2 configuration register */ #define CDL1CR_DEFAULT 0x04321 /* Default value for CDL1CR */ #define CDL2CR_DEFAULT 0x59876 /* Default value for CDL2CR */ #define LVDS_DMLCR(bit) (LVDS_DMLCR0 + 0x8 * (bit)) #define LVDS_DMMCR(bit) (LVDS_DMMCR0 + 0x8 * (bit)) /* LVDS Wrapper registers */ #define LVDS_WCLKCR 0x11B0 /* Wrapper clock control register */ #define LVDS_HWCFGR 0x1FF0 /* HW configuration register */ #define LVDS_VERR 0x1FF4 /* Version register */ #define LVDS_IPIDR 0x1FF8 /* Identification register */ #define LVDS_SIDR 0x1FFC /* Size Identification register */ /* Bitfield description */ #define CR_LVDSEN BIT(0) /* LVDS PHY Enable */ #define CR_HSPOL BIT(1) /* Horizontal Synchronization Polarity */ #define CR_VSPOL BIT(2) /* Vertical Synchronization Polarity */ #define CR_DEPOL BIT(3) /* Data Enable Polarity */ #define CR_CI BIT(4) /* Control Internal (software controlled bit) */ #define CR_LKMOD BIT(5) /* Link Mode, for both Links */ #define CR_LKPHA BIT(6) /* Link Phase, for both Links */ #define CR_LK1POL GENMASK(20, 16) /* Link-1 output Polarity */ #define CR_LK2POL GENMASK(25, 21) /* Link-2 output Polarity */ #define DMMCR_MAP0 GENMASK(4, 0) /* Mapping for bit 0 of datalane x */ #define DMMCR_MAP1 GENMASK(9, 5) /* Mapping for bit 1 of datalane x */ #define DMMCR_MAP2 GENMASK(14, 10) /* Mapping for bit 2 of datalane x */ #define DMMCR_MAP3 GENMASK(19, 15) /* Mapping for bit 3 of datalane x */ #define DMLCR_MAP4 GENMASK(4, 0) /* Mapping for bit 4 of datalane x */ #define DMLCR_MAP5 GENMASK(9, 5) /* Mapping for bit 5 of datalane x */ #define DMLCR_MAP6 GENMASK(14, 10) /* Mapping for bit 6 of datalane x */ #define CDLCR_DISTR0 GENMASK(3, 0) /* Channel distribution for lane 0 */ #define CDLCR_DISTR1 GENMASK(7, 4) /* Channel distribution for lane 1 */ #define CDLCR_DISTR2 GENMASK(11, 8) /* Channel distribution for lane 2 */ #define CDLCR_DISTR3 GENMASK(15, 12) /* Channel distribution for lane 3 */ #define CDLCR_DISTR4 GENMASK(19, 16) /* Channel distribution for lane 4 */ #define PHY_GCR_BIT_CLK_OUT BIT(0) /* BIT clock enable */ #define PHY_GCR_LS_CLK_OUT BIT(4) /* LS clock enable */ #define PHY_GCR_DP_CLK_OUT BIT(8) /* DP clock enable */ #define PHY_GCR_RSTZ BIT(24) /* LVDS PHY digital reset */ #define PHY_GCR_DIV_RSTN BIT(25) /* Output divider reset */ #define PHY_SCR_TX_EN BIT(16) /* Transmission mode enable */ /* Current mode driver enable */ #define PHY_CMCR_CM_EN_DL (BIT(28) | BIT(20) | BIT(12) | BIT(4)) #define PHY_CMCR_CM_EN_DL4 BIT(4) /* Bias enable */ #define PHY_BCR1_EN_BIAS_DL (BIT(16) | BIT(12) | BIT(8) | BIT(4) | BIT(0)) #define PHY_BCR2_BIAS_EN BIT(28) /* Voltage mode driver enable */ #define PHY_BCR3_VM_EN_DL (BIT(16) | BIT(12) | BIT(8) | BIT(4) | BIT(0)) #define PHY_DCR_POWER_OK BIT(12) #define PHY_CFGCR_EN_DIG_DL GENMASK(4, 0) /* LVDS PHY digital lane enable */ #define PHY_PLLCR1_PLL_EN BIT(0) /* LVDS PHY PLL enable */ #define PHY_PLLCR1_EN_SD BIT(1) /* LVDS PHY PLL sigma-delta signal enable */ #define PHY_PLLCR1_EN_TWG BIT(2) /* LVDS PHY PLL triangular wave generator enable */ #define PHY_PLLCR1_DIV_EN BIT(8) /* LVDS PHY PLL dividers enable */ #define PHY_PLLCR2_NDIV GENMASK(25, 16) /* NDIV mask value */ #define PHY_PLLCR2_BDIV GENMASK(9, 0) /* BDIV mask value */ #define PHY_PLLSR_PLL_LOCK BIT(0) /* LVDS PHY PLL lock status */ #define PHY_PLLSDCR1_MDIV GENMASK(9, 0) /* MDIV mask value */ #define PHY_PLLTESTCR_TDIV GENMASK(25, 16) /* TDIV mask value */ #define PHY_PLLTESTCR_CLK_EN BIT(0) /* Test clock enable */ #define PHY_PLLTESTCR_EN BIT(8) /* Test divider output enable */ #define WCLKCR_SECND_CLKPIX_SEL BIT(0) /* Pixel clock selection */ #define WCLKCR_SRCSEL BIT(8) /* Source selection for the pixel clock */ /* Sleep & timeout for pll lock/unlock */ #define SLEEP_US 1000 #define TIMEOUT_US 200000 /* * The link phase defines whether an ODD pixel is carried over together with * the next EVEN pixel or together with the previous EVEN pixel. * * LVDS_DUAL_LINK_EVEN_ODD_PIXELS (LKPHA = 0) * * ,--------. ,--------. ,--------. ,--------. ,---------. * | ODD LK \/ PIXEL 3 \/ PIXEL 1 \/ PIXEL' 1 \/ PIXEL' 3 | * | EVEN LK /\ PIXEL 2 /\ PIXEL' 0 /\ PIXEL' 2 /\ PIXEL' 4 | * `--------' `--------' `--------' `--------' `---------' * * LVDS_DUAL_LINK_ODD_EVEN_PIXELS (LKPHA = 1) * * ,--------. ,--------. ,--------. ,--------. ,---------. * | ODD LK \/ PIXEL 3 \/ PIXEL 1 \/ PIXEL' 1 \/ PIXEL' 3 | * | EVEN LK /\ PIXEL 4 /\ PIXEL 2 /\ PIXEL' 0 /\ PIXEL' 2 | * `--------' `--------' `--------' `--------' `---------' * */ enum lvds_link_type { LVDS_SINGLE_LINK_PRIMARY = 0, LVDS_SINGLE_LINK_SECONDARY, LVDS_DUAL_LINK_EVEN_ODD_PIXELS, LVDS_DUAL_LINK_ODD_EVEN_PIXELS, }; enum lvds_pixel { PIX_R_0 = 0, PIX_R_1, PIX_R_2, PIX_R_3, PIX_R_4, PIX_R_5, PIX_R_6, PIX_R_7, PIX_G_0, PIX_G_1, PIX_G_2, PIX_G_3, PIX_G_4, PIX_G_5, PIX_G_6, PIX_G_7, PIX_B_0, PIX_B_1, PIX_B_2, PIX_B_3, PIX_B_4, PIX_B_5, PIX_B_6, PIX_B_7, PIX_H_S, PIX_V_S, PIX_D_E, PIX_C_E, PIX_C_I, PIX_TOG, PIX_ONE, PIX_ZER, }; struct phy_reg_offsets { u32 GCR; /* Global Control Register */ u32 CMCR1; /* Current Mode Control Register 1 */ u32 CMCR2; /* Current Mode Control Register 2 */ u32 SCR; /* Serial Control Register */ u32 BCR1; /* Bias Control Register 1 */ u32 BCR2; /* Bias Control Register 2 */ u32 BCR3; /* Bias Control Register 3 */ u32 MPLCR; /* Monitor PLL Lock Control Register */ u32 DCR; /* Debug Control Register */ u32 SSR1; /* Spare Status Register 1 */ u32 CFGCR; /* Configuration Control Register */ u32 PLLCR1; /* PLL_MODE 1 Control Register */ u32 PLLCR2; /* PLL_MODE 2 Control Register */ u32 PLLSR; /* PLL Status Register */ u32 PLLSDCR1; /* PLL_SD_1 Control Register */ u32 PLLSDCR2; /* PLL_SD_2 Control Register */ u32 PLLTWGCR1;/* PLL_TWG_1 Control Register */ u32 PLLTWGCR2;/* PLL_TWG_2 Control Register */ u32 PLLCPCR; /* PLL_CP Control Register */ u32 PLLTESTCR;/* PLL_TEST Control Register */ }; struct lvds_phy_info { u32 base; struct phy_reg_offsets ofs; }; static struct lvds_phy_info lvds_phy_16ff_primary = { .base = 0x1000, .ofs = { .GCR = 0x0, .CMCR1 = 0xC, .CMCR2 = 0x10, .SCR = 0x20, .BCR1 = 0x2C, .BCR2 = 0x30, .BCR3 = 0x34, .MPLCR = 0x64, .DCR = 0x84, .SSR1 = 0x88, .CFGCR = 0xA0, .PLLCR1 = 0xC0, .PLLCR2 = 0xC4, .PLLSR = 0xC8, .PLLSDCR1 = 0xCC, .PLLSDCR2 = 0xD0, .PLLTWGCR1 = 0xD4, .PLLTWGCR2 = 0xD8, .PLLCPCR = 0xE0, .PLLTESTCR = 0xE8, } }; static struct lvds_phy_info lvds_phy_16ff_secondary = { .base = 0x1100, .ofs = { .GCR = 0x0, .CMCR1 = 0xC, .CMCR2 = 0x10, .SCR = 0x20, .BCR1 = 0x2C, .BCR2 = 0x30, .BCR3 = 0x34, .MPLCR = 0x64, .DCR = 0x84, .SSR1 = 0x88, .CFGCR = 0xA0, .PLLCR1 = 0xC0, .PLLCR2 = 0xC4, .PLLSR = 0xC8, .PLLSDCR1 = 0xCC, .PLLSDCR2 = 0xD0, .PLLTWGCR1 = 0xD4, .PLLTWGCR2 = 0xD8, .PLLCPCR = 0xE0, .PLLTESTCR = 0xE8, } }; struct stm_lvds { void __iomem *base; struct device *dev; struct clk *pclk; /* APB peripheral clock */ struct clk *pllref_clk; /* Reference clock for the internal PLL */ struct clk_hw lvds_ck_px; /* Pixel clock */ u32 pixel_clock_rate; /* Pixel clock rate */ struct lvds_phy_info *primary; struct lvds_phy_info *secondary; struct drm_bridge lvds_bridge; struct drm_bridge *next_bridge; struct drm_connector connector; struct drm_encoder *encoder; struct drm_panel *panel; u32 hw_version; u32 link_type; }; #define bridge_to_stm_lvds(b) \ container_of(b, struct stm_lvds, lvds_bridge) #define connector_to_stm_lvds(c) \ container_of(c, struct stm_lvds, connector) #define lvds_is_dual_link(lvds) \ ({ \ typeof(lvds) __lvds = (lvds); \ __lvds == LVDS_DUAL_LINK_EVEN_ODD_PIXELS || \ __lvds == LVDS_DUAL_LINK_ODD_EVEN_PIXELS; \ }) static inline void lvds_write(struct stm_lvds *lvds, u32 reg, u32 val) { writel(val, lvds->base + reg); } static inline u32 lvds_read(struct stm_lvds *lvds, u32 reg) { return readl(lvds->base + reg); } static inline void lvds_set(struct stm_lvds *lvds, u32 reg, u32 mask) { lvds_write(lvds, reg, lvds_read(lvds, reg) | mask); } static inline void lvds_clear(struct stm_lvds *lvds, u32 reg, u32 mask) { lvds_write(lvds, reg, lvds_read(lvds, reg) & ~mask); } /* * Expected JEIDA-RGB888 data to be sent in LSB format * bit6 ............................bit0 * CHAN0 {ONE, ONE, ZERO, ZERO, ZERO, ONE, ONE} * CHAN1 {G2, R7, R6, R5, R4, R3, R2} * CHAN2 {B3, B2, G7, G6, G5, G4, G3} * CHAN3 {DE, VS, HS, B7, B6, B5, B4} * CHAN4 {CE, B1, B0, G1, G0, R1, R0} */ static enum lvds_pixel lvds_bitmap_jeida_rgb888[5][7] = { { PIX_ONE, PIX_ONE, PIX_ZER, PIX_ZER, PIX_ZER, PIX_ONE, PIX_ONE }, { PIX_G_2, PIX_R_7, PIX_R_6, PIX_R_5, PIX_R_4, PIX_R_3, PIX_R_2 }, { PIX_B_3, PIX_B_2, PIX_G_7, PIX_G_6, PIX_G_5, PIX_G_4, PIX_G_3 }, { PIX_D_E, PIX_V_S, PIX_H_S, PIX_B_7, PIX_B_6, PIX_B_5, PIX_B_4 }, { PIX_C_E, PIX_B_1, PIX_B_0, PIX_G_1, PIX_G_0, PIX_R_1, PIX_R_0 } }; /* * Expected VESA-RGB888 data to be sent in LSB format * bit6 ............................bit0 * CHAN0 {ONE, ONE, ZERO, ZERO, ZERO, ONE, ONE} * CHAN1 {G0, R5, R4, R3, R2, R1, R0} * CHAN2 {B1, B0, G5, G4, G3, G2, G1} * CHAN3 {DE, VS, HS, B5, B4, B3, B2} * CHAN4 {CE, B7, B6, G7, G6, R7, R6} */ static enum lvds_pixel lvds_bitmap_vesa_rgb888[5][7] = { { PIX_ONE, PIX_ONE, PIX_ZER, PIX_ZER, PIX_ZER, PIX_ONE, PIX_ONE }, { PIX_G_0, PIX_R_5, PIX_R_4, PIX_R_3, PIX_R_2, PIX_R_1, PIX_R_0 }, { PIX_B_1, PIX_B_0, PIX_G_5, PIX_G_4, PIX_G_3, PIX_G_2, PIX_G_1 }, { PIX_D_E, PIX_V_S, PIX_H_S, PIX_B_5, PIX_B_4, PIX_B_3, PIX_B_2 }, { PIX_C_E, PIX_B_7, PIX_B_6, PIX_G_7, PIX_G_6, PIX_R_7, PIX_R_6 } }; /* * Clocks and PHY related functions */ static int lvds_pll_enable(struct stm_lvds *lvds, struct lvds_phy_info *phy) { struct drm_device *drm = lvds->lvds_bridge.dev; u32 lvds_gcr; int val, ret; /* * PLL lock timing control for the monitor unmask after startup (pll_en) * Adjusted value so that the masking window is opened at start-up */ lvds_write(lvds, phy->base + phy->ofs.MPLCR, (0x200 - 0x160) << 16); /* Enable bias */ lvds_write(lvds, phy->base + phy->ofs.BCR2, PHY_BCR2_BIAS_EN); /* Enable DP, LS, BIT clock output */ lvds_gcr = PHY_GCR_DP_CLK_OUT | PHY_GCR_LS_CLK_OUT | PHY_GCR_BIT_CLK_OUT; lvds_set(lvds, phy->base + phy->ofs.GCR, lvds_gcr); /* Power up all output dividers */ lvds_set(lvds, phy->base + phy->ofs.PLLTESTCR, PHY_PLLTESTCR_EN); lvds_set(lvds, phy->base + phy->ofs.PLLCR1, PHY_PLLCR1_DIV_EN); /* Set PHY in serial transmission mode */ lvds_set(lvds, phy->base + phy->ofs.SCR, PHY_SCR_TX_EN); /* Enable the LVDS PLL & wait for its lock */ lvds_set(lvds, phy->base + phy->ofs.PLLCR1, PHY_PLLCR1_PLL_EN); ret = readl_poll_timeout_atomic(lvds->base + phy->base + phy->ofs.PLLSR, val, val & PHY_PLLSR_PLL_LOCK, SLEEP_US, TIMEOUT_US); if (ret) drm_err(drm, "!TIMEOUT! waiting PLL, let's continue\n"); /* WCLKCR_SECND_CLKPIX_SEL is for dual link */ lvds_write(lvds, LVDS_WCLKCR, WCLKCR_SECND_CLKPIX_SEL); lvds_set(lvds, phy->ofs.PLLTESTCR, PHY_PLLTESTCR_CLK_EN); return ret; } static int pll_get_clkout_khz(int clkin_khz, int bdiv, int mdiv, int ndiv) { int divisor = ndiv * bdiv; /* Prevents from division by 0 */ if (!divisor) return 0; return clkin_khz * mdiv / divisor; } #define TDIV 70 #define NDIV_MIN 2 #define NDIV_MAX 6 #define BDIV_MIN 2 #define BDIV_MAX 6 #define MDIV_MIN 1 #define MDIV_MAX 1023 static int lvds_pll_get_params(struct stm_lvds *lvds, unsigned int clkin_khz, unsigned int clkout_khz, unsigned int *bdiv, unsigned int *mdiv, unsigned int *ndiv) { int delta, best_delta; /* all in khz */ int i, o, n; /* Early checks preventing division by 0 & odd results */ if (clkin_khz <= 0 || clkout_khz <= 0) return -EINVAL; best_delta = 1000000; /* big started value (1000000khz) */ for (i = NDIV_MIN; i <= NDIV_MAX; i++) { for (o = BDIV_MIN; o <= BDIV_MAX; o++) { n = DIV_ROUND_CLOSEST(i * o * clkout_khz, clkin_khz); /* Check ndiv according to vco range */ if (n < MDIV_MIN || n > MDIV_MAX) continue; /* Check if new delta is better & saves parameters */ delta = pll_get_clkout_khz(clkin_khz, i, n, o) - clkout_khz; if (delta < 0) delta = -delta; if (delta < best_delta) { *ndiv = i; *mdiv = n; *bdiv = o; best_delta = delta; } /* fast return in case of "perfect result" */ if (!delta) return 0; } } return 0; } static void lvds_pll_config(struct stm_lvds *lvds, struct lvds_phy_info *phy) { unsigned int pll_in_khz, bdiv = 0, mdiv = 0, ndiv = 0; struct clk_hw *hwclk; int multiplier; /* * The LVDS PHY includes a low power low jitter high performance and * highly configuration Phase Locked Loop supporting integer and * fractional multiplication ratios and Spread Spectrum Clocking. In * integer mode, the only software supported feature for now, the PLL is * made of a pre-divider NDIV, a feedback multiplier MDIV, followed by * several post-dividers, each one with a specific application. * * ,------. ,-----. ,-----. * Fref --> | NDIV | -Fpdf-> | PFD | --> | VCO | --------> Fvco * `------' ,-> | | `-----' | * | `-----' | * | ,------. | * `-------- | MDIV | <-----' * `------' * * From the output of the VCO, the clock can be optionally extracted on * the RCC clock observer, with a divider TDIV, for testing purpose, or * is passed through a programmable post-divider BDIV. Finally, the * frequency can be divided further with two fixed dividers. * * ,--------. * ,-----> | DP div | ----------------> Fdp * ,------. | `--------' * Fvco --> | BDIV | ------------------------------------> Fbit * | `------' ,------. | * `-------------> | TDIV | --.---------------------> ClkObs * '------' | ,--------. * `--> | LS div | ------> Fls * '--------' * * The LS and DP clock dividers operate at a fixed ratio of 7 and 3.5 * respectively with regards to fbit. LS divider converts the bit clock * to a pixel clock per lane per clock sample (Fls). This is useful * when used to generate a dot clock for the display unit RGB output, * and DP divider is. */ hwclk = __clk_get_hw(lvds->pllref_clk); if (!hwclk) return; pll_in_khz = clk_hw_get_rate(hwclk) / 1000; if (lvds_is_dual_link(lvds->link_type)) multiplier = 2; else multiplier = 1; lvds_pll_get_params(lvds, pll_in_khz, lvds->pixel_clock_rate * 7 / 1000 / multiplier, &bdiv, &mdiv, &ndiv); /* Set BDIV, MDIV and NDIV */ lvds_write(lvds, phy->base + phy->ofs.PLLCR2, ndiv << 16); lvds_set(lvds, phy->base + phy->ofs.PLLCR2, bdiv); lvds_write(lvds, phy->base + phy->ofs.PLLSDCR1, mdiv); /* Hardcode TDIV as dynamic values are not yet implemented */ lvds_write(lvds, phy->base + phy->ofs.PLLTESTCR, TDIV << 16); /* * For now, PLL just needs to be in integer mode * Fractional and spread spectrum clocking are not yet implemented * * PLL integer mode: * - PMRY_PLL_TWG_STEP = PMRY_PLL_SD_INT_RATIO * - EN_TWG = 0 * - EN_SD = 0 * - DOWN_SPREAD = 0 * * PLL fractional mode: * - EN_TWG = 0 * - EN_SD = 1 * - DOWN_SPREAD = 0 * * Spread Spectrum Clocking * - EN_TWG = 1 * - EN_SD = 1 */ /* Disable TWG and SD */ lvds_clear(lvds, phy->base + phy->ofs.PLLCR1, PHY_PLLCR1_EN_TWG | PHY_PLLCR1_EN_SD); /* Power up bias and PLL dividers */ lvds_set(lvds, phy->base + phy->ofs.DCR, PHY_DCR_POWER_OK); lvds_set(lvds, phy->base + phy->ofs.CMCR1, PHY_CMCR_CM_EN_DL); lvds_set(lvds, phy->base + phy->ofs.CMCR2, PHY_CMCR_CM_EN_DL4); /* Set up voltage mode */ lvds_set(lvds, phy->base + phy->ofs.PLLCPCR, 0x1); lvds_set(lvds, phy->base + phy->ofs.BCR3, PHY_BCR3_VM_EN_DL); lvds_set(lvds, phy->base + phy->ofs.BCR1, PHY_BCR1_EN_BIAS_DL); /* Enable digital datalanes */ lvds_set(lvds, phy->base + phy->ofs.CFGCR, PHY_CFGCR_EN_DIG_DL); } static int lvds_pixel_clk_enable(struct clk_hw *hw) { struct stm_lvds *lvds = container_of(hw, struct stm_lvds, lvds_ck_px); struct drm_device *drm = lvds->lvds_bridge.dev; struct lvds_phy_info *phy; int ret; ret = clk_prepare_enable(lvds->pclk); if (ret) { drm_err(drm, "Failed to enable lvds peripheral clk\n"); return ret; } ret = clk_prepare_enable(lvds->pllref_clk); if (ret) { drm_err(drm, "Failed to enable lvds reference clk\n"); clk_disable_unprepare(lvds->pclk); return ret; } /* In case we are operating in dual link the second PHY is set before the primary PHY. */ if (lvds->secondary) { phy = lvds->secondary; /* Release LVDS PHY from reset mode */ lvds_set(lvds, phy->base + phy->ofs.GCR, PHY_GCR_DIV_RSTN | PHY_GCR_RSTZ); lvds_pll_config(lvds, phy); ret = lvds_pll_enable(lvds, phy); if (ret) { drm_err(drm, "Failed to enable secondary PHY PLL: %d\n", ret); return ret; } } if (lvds->primary) { phy = lvds->primary; /* Release LVDS PHY from reset mode */ lvds_set(lvds, phy->base + phy->ofs.GCR, PHY_GCR_DIV_RSTN | PHY_GCR_RSTZ); lvds_pll_config(lvds, phy); ret = lvds_pll_enable(lvds, phy); if (ret) { drm_err(drm, "Failed to enable primary PHY PLL: %d\n", ret); return ret; } } return 0; } static void lvds_pixel_clk_disable(struct clk_hw *hw) { struct stm_lvds *lvds = container_of(hw, struct stm_lvds, lvds_ck_px); /* * For each PHY: * Disable DP, LS, BIT clock outputs * Shutdown the PLL * Assert LVDS PHY in reset mode */ if (lvds->primary) { lvds_clear(lvds, lvds->primary->base + lvds->primary->ofs.GCR, (PHY_GCR_DP_CLK_OUT | PHY_GCR_LS_CLK_OUT | PHY_GCR_BIT_CLK_OUT)); lvds_clear(lvds, lvds->primary->base + lvds->primary->ofs.PLLCR1, PHY_PLLCR1_PLL_EN); lvds_clear(lvds, lvds->primary->base + lvds->primary->ofs.GCR, PHY_GCR_DIV_RSTN | PHY_GCR_RSTZ); } if (lvds->secondary) { lvds_clear(lvds, lvds->secondary->base + lvds->secondary->ofs.GCR, (PHY_GCR_DP_CLK_OUT | PHY_GCR_LS_CLK_OUT | PHY_GCR_BIT_CLK_OUT)); lvds_clear(lvds, lvds->secondary->base + lvds->secondary->ofs.PLLCR1, PHY_PLLCR1_PLL_EN); lvds_clear(lvds, lvds->secondary->base + lvds->secondary->ofs.GCR, PHY_GCR_DIV_RSTN | PHY_GCR_RSTZ); } clk_disable_unprepare(lvds->pllref_clk); clk_disable_unprepare(lvds->pclk); } static unsigned long lvds_pixel_clk_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct stm_lvds *lvds = container_of(hw, struct stm_lvds, lvds_ck_px); struct drm_device *drm = lvds->lvds_bridge.dev; unsigned int pll_in_khz, bdiv, mdiv, ndiv; int ret, multiplier, pll_out_khz; u32 val; ret = clk_prepare_enable(lvds->pclk); if (ret) { drm_err(drm, "Failed to enable lvds peripheral clk\n"); return 0; } if (lvds_is_dual_link(lvds->link_type)) multiplier = 2; else multiplier = 1; val = lvds_read(lvds, lvds->primary->base + lvds->primary->ofs.PLLCR2); ndiv = (val & PHY_PLLCR2_NDIV) >> 16; bdiv = (val & PHY_PLLCR2_BDIV) >> 0; mdiv = (unsigned int)lvds_read(lvds, lvds->primary->base + lvds->primary->ofs.PLLSDCR1); pll_in_khz = (unsigned int)(parent_rate / 1000); /* Compute values if not yet accessible */ if (val == 0 || mdiv == 0) { lvds_pll_get_params(lvds, pll_in_khz, lvds->pixel_clock_rate * 7 / 1000 / multiplier, &bdiv, &mdiv, &ndiv); } pll_out_khz = pll_get_clkout_khz(pll_in_khz, bdiv, mdiv, ndiv); drm_dbg(drm, "ndiv %d , bdiv %d, mdiv %d, pll_out_khz %d\n", ndiv, bdiv, mdiv, pll_out_khz); /* * 1/7 because for each pixel in 1 lane there is 7 bits * We want pixclk, not bitclk */ lvds->pixel_clock_rate = pll_out_khz * 1000 * multiplier / 7; clk_disable_unprepare(lvds->pclk); return (unsigned long)lvds->pixel_clock_rate; } static long lvds_pixel_clk_round_rate(struct clk_hw *hw, unsigned long rate, unsigned long *parent_rate) { struct stm_lvds *lvds = container_of(hw, struct stm_lvds, lvds_ck_px); unsigned int pll_in_khz, bdiv = 0, mdiv = 0, ndiv = 0; const struct drm_connector *connector; const struct drm_display_mode *mode; int multiplier; connector = &lvds->connector; if (!connector) return -EINVAL; if (list_empty(&connector->modes)) { drm_dbg(connector->dev, "connector: empty modes list\n"); return -EINVAL; } mode = list_first_entry(&connector->modes, struct drm_display_mode, head); pll_in_khz = (unsigned int)(*parent_rate / 1000); if (lvds_is_dual_link(lvds->link_type)) multiplier = 2; else multiplier = 1; lvds_pll_get_params(lvds, pll_in_khz, mode->clock * 7 / multiplier, &bdiv, &mdiv, &ndiv); /* * 1/7 because for each pixel in 1 lane there is 7 bits * We want pixclk, not bitclk */ lvds->pixel_clock_rate = (unsigned long)pll_get_clkout_khz(pll_in_khz, bdiv, mdiv, ndiv) * 1000 * multiplier / 7; return lvds->pixel_clock_rate; } static const struct clk_ops lvds_pixel_clk_ops = { .enable = lvds_pixel_clk_enable, .disable = lvds_pixel_clk_disable, .recalc_rate = lvds_pixel_clk_recalc_rate, .round_rate = lvds_pixel_clk_round_rate, }; static const struct clk_init_data clk_data = { .name = "clk_pix_lvds", .ops = &lvds_pixel_clk_ops, .parent_names = (const char * []) {"ck_ker_lvdsphy"}, .num_parents = 1, .flags = CLK_IGNORE_UNUSED, }; static void lvds_pixel_clk_unregister(void *data) { struct stm_lvds *lvds = data; of_clk_del_provider(lvds->dev->of_node); clk_hw_unregister(&lvds->lvds_ck_px); } static int lvds_pixel_clk_register(struct stm_lvds *lvds) { struct device_node *node = lvds->dev->of_node; int ret; lvds->lvds_ck_px.init = &clk_data; /* set the rate by default at 148500000 */ lvds->pixel_clock_rate = 148500000; ret = clk_hw_register(lvds->dev, &lvds->lvds_ck_px); if (ret) return ret; ret = of_clk_add_hw_provider(node, of_clk_hw_simple_get, &lvds->lvds_ck_px); if (ret) clk_hw_unregister(&lvds->lvds_ck_px); return ret; } /* * Host configuration related */ static void lvds_config_data_mapping(struct stm_lvds *lvds) { struct drm_device *drm = lvds->lvds_bridge.dev; const struct drm_display_info *info; enum lvds_pixel (*bitmap)[7]; u32 lvds_dmlcr, lvds_dmmcr; int i; info = &(&lvds->connector)->display_info; if (!info->num_bus_formats || !info->bus_formats) { drm_warn(drm, "No LVDS bus format reported\n"); return; } switch (info->bus_formats[0]) { case MEDIA_BUS_FMT_RGB666_1X7X3_SPWG: /* VESA-RGB666 */ drm_warn(drm, "Pixel format with data mapping not yet supported.\n"); return; case MEDIA_BUS_FMT_RGB888_1X7X4_SPWG: /* VESA-RGB888 */ bitmap = lvds_bitmap_vesa_rgb888; break; case MEDIA_BUS_FMT_RGB888_1X7X4_JEIDA: /* JEIDA-RGB888 */ bitmap = lvds_bitmap_jeida_rgb888; break; default: drm_warn(drm, "Unsupported LVDS bus format 0x%04x\n", info->bus_formats[0]); return; } /* Set bitmap for each lane */ for (i = 0; i < 5; i++) { lvds_dmlcr = ((bitmap[i][0]) + (bitmap[i][1] << 5) + (bitmap[i][2] << 10) + (bitmap[i][3] << 15)); lvds_dmmcr = ((bitmap[i][4]) + (bitmap[i][5] << 5) + (bitmap[i][6] << 10)); lvds_write(lvds, LVDS_DMLCR(i), lvds_dmlcr); lvds_write(lvds, LVDS_DMMCR(i), lvds_dmmcr); } } static void lvds_config_mode(struct stm_lvds *lvds) { u32 bus_flags, lvds_cr = 0, lvds_cdl1cr = 0, lvds_cdl2cr = 0; const struct drm_display_mode *mode; const struct drm_connector *connector; connector = &lvds->connector; if (!connector) return; if (list_empty(&connector->modes)) { drm_dbg(connector->dev, "connector: empty modes list\n"); return; } bus_flags = connector->display_info.bus_flags; mode = list_first_entry(&connector->modes, struct drm_display_mode, head); lvds_clear(lvds, LVDS_CR, CR_LKMOD); lvds_clear(lvds, LVDS_CDL1CR, CDLCR_DISTR0 | CDLCR_DISTR1 | CDLCR_DISTR2 | CDLCR_DISTR3 | CDLCR_DISTR4); lvds_clear(lvds, LVDS_CDL2CR, CDLCR_DISTR0 | CDLCR_DISTR1 | CDLCR_DISTR2 | CDLCR_DISTR3 | CDLCR_DISTR4); /* Set channel distribution */ if (lvds->primary) lvds_cdl1cr = CDL1CR_DEFAULT; if (lvds->secondary) { lvds_cr |= CR_LKMOD; lvds_cdl2cr = CDL2CR_DEFAULT; } /* Set signal polarity */ if (bus_flags & DRM_BUS_FLAG_DE_LOW) lvds_cr |= CR_DEPOL; if (mode->flags & DRM_MODE_FLAG_NHSYNC) lvds_cr |= CR_HSPOL; if (mode->flags & DRM_MODE_FLAG_NVSYNC) lvds_cr |= CR_VSPOL; switch (lvds->link_type) { case LVDS_DUAL_LINK_EVEN_ODD_PIXELS: /* LKPHA = 0 */ lvds_cr &= ~CR_LKPHA; break; case LVDS_DUAL_LINK_ODD_EVEN_PIXELS: /* LKPHA = 1 */ lvds_cr |= CR_LKPHA; break; default: drm_notice(lvds->lvds_bridge.dev, "No phase precised, setting default\n"); lvds_cr &= ~CR_LKPHA; break; } /* Write config to registers */ lvds_set(lvds, LVDS_CR, lvds_cr); lvds_write(lvds, LVDS_CDL1CR, lvds_cdl1cr); lvds_write(lvds, LVDS_CDL2CR, lvds_cdl2cr); } static int lvds_connector_get_modes(struct drm_connector *connector) { struct stm_lvds *lvds = connector_to_stm_lvds(connector); return drm_panel_get_modes(lvds->panel, connector); } static int lvds_connector_atomic_check(struct drm_connector *connector, struct drm_atomic_state *state) { const struct drm_display_mode *panel_mode; struct drm_connector_state *conn_state; struct drm_crtc_state *crtc_state; conn_state = drm_atomic_get_new_connector_state(state, connector); if (!conn_state) return -EINVAL; if (list_empty(&connector->modes)) { drm_dbg(connector->dev, "connector: empty modes list\n"); return -EINVAL; } if (!conn_state->crtc) return -EINVAL; panel_mode = list_first_entry(&connector->modes, struct drm_display_mode, head); /* We're not allowed to modify the resolution. */ crtc_state = drm_atomic_get_crtc_state(state, conn_state->crtc); if (IS_ERR(crtc_state)) return PTR_ERR(crtc_state); if (crtc_state->mode.hdisplay != panel_mode->hdisplay || crtc_state->mode.vdisplay != panel_mode->vdisplay) return -EINVAL; /* The flat panel mode is fixed, just copy it to the adjusted mode. */ drm_mode_copy(&crtc_state->adjusted_mode, panel_mode); return 0; } static const struct drm_connector_helper_funcs lvds_conn_helper_funcs = { .get_modes = lvds_connector_get_modes, .atomic_check = lvds_connector_atomic_check, }; static const struct drm_connector_funcs lvds_conn_funcs = { .reset = drm_atomic_helper_connector_reset, .fill_modes = drm_helper_probe_single_connector_modes, .destroy = drm_connector_cleanup, .atomic_duplicate_state = drm_atomic_helper_connector_duplicate_state, .atomic_destroy_state = drm_atomic_helper_connector_destroy_state, }; static int lvds_attach(struct drm_bridge *bridge, enum drm_bridge_attach_flags flags) { struct stm_lvds *lvds = bridge_to_stm_lvds(bridge); struct drm_connector *connector = &lvds->connector; struct drm_encoder *encoder = bridge->encoder; int ret; if (!bridge->encoder) { drm_err(bridge->dev, "Parent encoder object not found\n"); return -ENODEV; } /* Set the encoder type as caller does not know it */ bridge->encoder->encoder_type = DRM_MODE_ENCODER_LVDS; /* No cloning support */ bridge->encoder->possible_clones = 0; /* If we have a next bridge just attach it. */ if (lvds->next_bridge) return drm_bridge_attach(bridge->encoder, lvds->next_bridge, bridge, flags); if (flags & DRM_BRIDGE_ATTACH_NO_CONNECTOR) { drm_err(bridge->dev, "Fix bridge driver to make connector optional!"); return -EINVAL; } /* Otherwise if we have a panel, create a connector. */ if (!lvds->panel) return 0; ret = drm_connector_init(bridge->dev, connector, &lvds_conn_funcs, DRM_MODE_CONNECTOR_LVDS); if (ret < 0) return ret; drm_connector_helper_add(connector, &lvds_conn_helper_funcs); ret = drm_connector_attach_encoder(connector, encoder); return ret; } static void lvds_atomic_enable(struct drm_bridge *bridge, struct drm_bridge_state *old_bridge_state) { struct drm_atomic_state *state = old_bridge_state->base.state; struct stm_lvds *lvds = bridge_to_stm_lvds(bridge); struct drm_connector_state *conn_state; struct drm_connector *connector; int ret; ret = clk_prepare_enable(lvds->pclk); if (ret) { drm_err(bridge->dev, "Failed to enable lvds peripheral clk\n"); return; } connector = drm_atomic_get_new_connector_for_encoder(state, bridge->encoder); if (!connector) return; conn_state = drm_atomic_get_new_connector_state(state, connector); if (!conn_state) return; lvds_config_mode(lvds); /* Set Data Mapping */ lvds_config_data_mapping(lvds); /* Turn the output on. */ lvds_set(lvds, LVDS_CR, CR_LVDSEN); if (lvds->panel) { drm_panel_prepare(lvds->panel); drm_panel_enable(lvds->panel); } } static void lvds_atomic_disable(struct drm_bridge *bridge, struct drm_bridge_state *old_bridge_state) { struct stm_lvds *lvds = bridge_to_stm_lvds(bridge); if (lvds->panel) { drm_panel_disable(lvds->panel); drm_panel_unprepare(lvds->panel); } /* Disable LVDS module */ lvds_clear(lvds, LVDS_CR, CR_LVDSEN); clk_disable_unprepare(lvds->pclk); } static const struct drm_bridge_funcs lvds_bridge_funcs = { .attach = lvds_attach, .atomic_enable = lvds_atomic_enable, .atomic_disable = lvds_atomic_disable, .atomic_duplicate_state = drm_atomic_helper_bridge_duplicate_state, .atomic_destroy_state = drm_atomic_helper_bridge_destroy_state, .atomic_reset = drm_atomic_helper_bridge_reset, }; static int lvds_probe(struct platform_device *pdev) { struct device_node *port1, *port2, *remote; struct device *dev = &pdev->dev; struct reset_control *rstc; struct stm_lvds *lvds; int ret, dual_link; dev_dbg(dev, "Probing LVDS driver...\n"); lvds = devm_kzalloc(dev, sizeof(*lvds), GFP_KERNEL); if (!lvds) return -ENOMEM; lvds->dev = dev; ret = drm_of_find_panel_or_bridge(dev->of_node, 1, 0, &lvds->panel, &lvds->next_bridge); if (ret) { dev_err_probe(dev, ret, "Panel not found\n"); return ret; } lvds->base = devm_platform_ioremap_resource(pdev, 0); if (IS_ERR(lvds->base)) { ret = PTR_ERR(lvds->base); dev_err(dev, "Unable to get regs %d\n", ret); return ret; } lvds->pclk = devm_clk_get(dev, "pclk"); if (IS_ERR(lvds->pclk)) { ret = PTR_ERR(lvds->pclk); dev_err(dev, "Unable to get peripheral clock: %d\n", ret); return ret; } ret = clk_prepare_enable(lvds->pclk); if (ret) { dev_err(dev, "%s: Failed to enable peripheral clk\n", __func__); return ret; } rstc = devm_reset_control_get_exclusive(dev, NULL); if (IS_ERR(rstc)) { ret = PTR_ERR(rstc); goto err_lvds_probe; } reset_control_assert(rstc); usleep_range(10, 20); reset_control_deassert(rstc); port1 = of_graph_get_port_by_id(dev->of_node, 1); port2 = of_graph_get_port_by_id(dev->of_node, 2); dual_link = drm_of_lvds_get_dual_link_pixel_order(port1, port2); switch (dual_link) { case DRM_LVDS_DUAL_LINK_ODD_EVEN_PIXELS: lvds->link_type = LVDS_DUAL_LINK_ODD_EVEN_PIXELS; lvds->primary = &lvds_phy_16ff_primary; lvds->secondary = &lvds_phy_16ff_secondary; break; case DRM_LVDS_DUAL_LINK_EVEN_ODD_PIXELS: lvds->link_type = LVDS_DUAL_LINK_EVEN_ODD_PIXELS; lvds->primary = &lvds_phy_16ff_primary; lvds->secondary = &lvds_phy_16ff_secondary; break; case -EINVAL: /* * drm_of_lvds_get_dual_pixel_order returns 4 possible values. * In the case where the returned value is an error, it can be * either ENODEV or EINVAL. Seeing the structure of this * function, EINVAL means that either port1 or port2 is not * present in the device tree. * In that case, the lvds panel can be a single link panel, or * there is a semantical error in the device tree code. */ remote = of_get_next_available_child(port1, NULL); if (remote) { if (of_graph_get_remote_endpoint(remote)) { lvds->link_type = LVDS_SINGLE_LINK_PRIMARY; lvds->primary = &lvds_phy_16ff_primary; lvds->secondary = NULL; } else { ret = -EINVAL; } of_node_put(remote); } remote = of_get_next_available_child(port2, NULL); if (remote) { if (of_graph_get_remote_endpoint(remote)) { lvds->link_type = LVDS_SINGLE_LINK_SECONDARY; lvds->primary = NULL; lvds->secondary = &lvds_phy_16ff_secondary; } else { ret = (ret == -EINVAL) ? -EINVAL : 0; } of_node_put(remote); } break; default: ret = -EINVAL; goto err_lvds_probe; } of_node_put(port1); of_node_put(port2); lvds->pllref_clk = devm_clk_get(dev, "ref"); if (IS_ERR(lvds->pllref_clk)) { ret = PTR_ERR(lvds->pllref_clk); dev_err(dev, "Unable to get reference clock: %d\n", ret); goto err_lvds_probe; } ret = lvds_pixel_clk_register(lvds); if (ret) { dev_err(dev, "Failed to register LVDS pixel clock: %d\n", ret); goto err_lvds_probe; } lvds->lvds_bridge.funcs = &lvds_bridge_funcs; lvds->lvds_bridge.of_node = dev->of_node; lvds->hw_version = lvds_read(lvds, LVDS_VERR); dev_info(dev, "version 0x%02x initialized\n", lvds->hw_version); drm_bridge_add(&lvds->lvds_bridge); platform_set_drvdata(pdev, lvds); clk_disable_unprepare(lvds->pclk); return 0; err_lvds_probe: clk_disable_unprepare(lvds->pclk); return ret; } static void lvds_remove(struct platform_device *pdev) { struct stm_lvds *lvds = platform_get_drvdata(pdev); lvds_pixel_clk_unregister(lvds); drm_bridge_remove(&lvds->lvds_bridge); } static const struct of_device_id lvds_dt_ids[] = { { .compatible = "st,stm32mp25-lvds", .data = NULL }, { /* sentinel */ } }; MODULE_DEVICE_TABLE(of, lvds_dt_ids); static struct platform_driver lvds_platform_driver = { .probe = lvds_probe, .remove = lvds_remove, .driver = { .name = "stm32-display-lvds", .owner = THIS_MODULE, .of_match_table = lvds_dt_ids, }, }; module_platform_driver(lvds_platform_driver); MODULE_AUTHOR("Raphaël Gallais-Pou <raphael.gallais-pou@foss.st.com>"); MODULE_AUTHOR("Philippe Cornu <philippe.cornu@foss.st.com>"); MODULE_AUTHOR("Yannick Fertre <yannick.fertre@foss.st.com>"); MODULE_DESCRIPTION("STMicroelectronics LVDS Display Interface Transmitter DRM driver"); MODULE_LICENSE("GPL");
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