Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Chandan Uddaraju | 3640 | 62.23% | 1 | 2.22% |
Abhinav Kumar | 533 | 9.11% | 2 | 4.44% |
Björn Andersson | 499 | 8.53% | 9 | 20.00% |
Kuogee Hsieh | 374 | 6.39% | 9 | 20.00% |
Paloma Arellano | 325 | 5.56% | 3 | 6.67% |
Vinod Polimera | 184 | 3.15% | 1 | 2.22% |
Dmitry Eremin-Solenikov | 59 | 1.01% | 2 | 4.44% |
Tanmay Shah | 53 | 0.91% | 1 | 2.22% |
Sankeerth Billakanti | 51 | 0.87% | 2 | 4.44% |
Jeykumar Sankaran | 40 | 0.68% | 1 | 2.22% |
Maitreyee Rao | 30 | 0.51% | 1 | 2.22% |
Rob Clark | 18 | 0.31% | 1 | 2.22% |
Stephen Boyd | 15 | 0.26% | 2 | 4.44% |
Doug Anderson | 12 | 0.21% | 2 | 4.44% |
Archit Taneja | 8 | 0.14% | 3 | 6.67% |
Sean Paul | 4 | 0.07% | 1 | 2.22% |
ChenTao | 1 | 0.02% | 1 | 2.22% |
Thomas Zimmermann | 1 | 0.02% | 1 | 2.22% |
Lee Jones | 1 | 0.02% | 1 | 2.22% |
Thomas Gleixner | 1 | 0.02% | 1 | 2.22% |
Total | 5849 | 45 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2017-2020, The Linux Foundation. All rights reserved. */ #define pr_fmt(fmt) "[drm-dp] %s: " fmt, __func__ #include <linux/delay.h> #include <linux/iopoll.h> #include <linux/platform_device.h> #include <linux/rational.h> #include <drm/display/drm_dp_helper.h> #include <drm/drm_print.h> #include "dp_catalog.h" #include "dp_reg.h" #define POLLING_SLEEP_US 1000 #define POLLING_TIMEOUT_US 10000 #define SCRAMBLER_RESET_COUNT_VALUE 0xFC #define DP_INTERRUPT_STATUS_ACK_SHIFT 1 #define DP_INTERRUPT_STATUS_MASK_SHIFT 2 #define DP_INTF_CONFIG_DATABUS_WIDEN BIT(4) #define DP_INTERRUPT_STATUS1 \ (DP_INTR_AUX_XFER_DONE| \ DP_INTR_WRONG_ADDR | DP_INTR_TIMEOUT | \ DP_INTR_NACK_DEFER | DP_INTR_WRONG_DATA_CNT | \ DP_INTR_I2C_NACK | DP_INTR_I2C_DEFER | \ DP_INTR_PLL_UNLOCKED | DP_INTR_AUX_ERROR) #define DP_INTERRUPT_STATUS1_ACK \ (DP_INTERRUPT_STATUS1 << DP_INTERRUPT_STATUS_ACK_SHIFT) #define DP_INTERRUPT_STATUS1_MASK \ (DP_INTERRUPT_STATUS1 << DP_INTERRUPT_STATUS_MASK_SHIFT) #define DP_INTERRUPT_STATUS2 \ (DP_INTR_READY_FOR_VIDEO | DP_INTR_IDLE_PATTERN_SENT | \ DP_INTR_FRAME_END | DP_INTR_CRC_UPDATED) #define DP_INTERRUPT_STATUS2_ACK \ (DP_INTERRUPT_STATUS2 << DP_INTERRUPT_STATUS_ACK_SHIFT) #define DP_INTERRUPT_STATUS2_MASK \ (DP_INTERRUPT_STATUS2 << DP_INTERRUPT_STATUS_MASK_SHIFT) #define DP_INTERRUPT_STATUS4 \ (PSR_UPDATE_INT | PSR_CAPTURE_INT | PSR_EXIT_INT | \ PSR_UPDATE_ERROR_INT | PSR_WAKE_ERROR_INT) #define DP_INTERRUPT_MASK4 \ (PSR_UPDATE_MASK | PSR_CAPTURE_MASK | PSR_EXIT_MASK | \ PSR_UPDATE_ERROR_MASK | PSR_WAKE_ERROR_MASK) #define DP_DEFAULT_AHB_OFFSET 0x0000 #define DP_DEFAULT_AHB_SIZE 0x0200 #define DP_DEFAULT_AUX_OFFSET 0x0200 #define DP_DEFAULT_AUX_SIZE 0x0200 #define DP_DEFAULT_LINK_OFFSET 0x0400 #define DP_DEFAULT_LINK_SIZE 0x0C00 #define DP_DEFAULT_P0_OFFSET 0x1000 #define DP_DEFAULT_P0_SIZE 0x0400 struct dss_io_region { size_t len; void __iomem *base; }; struct dss_io_data { struct dss_io_region ahb; struct dss_io_region aux; struct dss_io_region link; struct dss_io_region p0; }; struct dp_catalog_private { struct device *dev; struct drm_device *drm_dev; struct dss_io_data io; u32 (*audio_map)[DP_AUDIO_SDP_HEADER_MAX]; struct dp_catalog dp_catalog; }; void dp_catalog_snapshot(struct dp_catalog *dp_catalog, struct msm_disp_state *disp_state) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); struct dss_io_data *dss = &catalog->io; msm_disp_snapshot_add_block(disp_state, dss->ahb.len, dss->ahb.base, "dp_ahb"); msm_disp_snapshot_add_block(disp_state, dss->aux.len, dss->aux.base, "dp_aux"); msm_disp_snapshot_add_block(disp_state, dss->link.len, dss->link.base, "dp_link"); msm_disp_snapshot_add_block(disp_state, dss->p0.len, dss->p0.base, "dp_p0"); } static inline u32 dp_read_aux(struct dp_catalog_private *catalog, u32 offset) { return readl_relaxed(catalog->io.aux.base + offset); } static inline void dp_write_aux(struct dp_catalog_private *catalog, u32 offset, u32 data) { /* * To make sure aux reg writes happens before any other operation, * this function uses writel() instread of writel_relaxed() */ writel(data, catalog->io.aux.base + offset); } static inline u32 dp_read_ahb(const struct dp_catalog_private *catalog, u32 offset) { return readl_relaxed(catalog->io.ahb.base + offset); } static inline void dp_write_ahb(struct dp_catalog_private *catalog, u32 offset, u32 data) { /* * To make sure phy reg writes happens before any other operation, * this function uses writel() instread of writel_relaxed() */ writel(data, catalog->io.ahb.base + offset); } static inline void dp_write_p0(struct dp_catalog_private *catalog, u32 offset, u32 data) { /* * To make sure interface reg writes happens before any other operation, * this function uses writel() instread of writel_relaxed() */ writel(data, catalog->io.p0.base + offset); } static inline u32 dp_read_p0(struct dp_catalog_private *catalog, u32 offset) { /* * To make sure interface reg writes happens before any other operation, * this function uses writel() instread of writel_relaxed() */ return readl_relaxed(catalog->io.p0.base + offset); } static inline u32 dp_read_link(struct dp_catalog_private *catalog, u32 offset) { return readl_relaxed(catalog->io.link.base + offset); } static inline void dp_write_link(struct dp_catalog_private *catalog, u32 offset, u32 data) { /* * To make sure link reg writes happens before any other operation, * this function uses writel() instread of writel_relaxed() */ writel(data, catalog->io.link.base + offset); } /* aux related catalog functions */ u32 dp_catalog_aux_read_data(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); return dp_read_aux(catalog, REG_DP_AUX_DATA); } int dp_catalog_aux_write_data(struct dp_catalog *dp_catalog, u32 data) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_write_aux(catalog, REG_DP_AUX_DATA, data); return 0; } int dp_catalog_aux_write_trans(struct dp_catalog *dp_catalog, u32 data) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_write_aux(catalog, REG_DP_AUX_TRANS_CTRL, data); return 0; } int dp_catalog_aux_clear_trans(struct dp_catalog *dp_catalog, bool read) { u32 data; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); if (read) { data = dp_read_aux(catalog, REG_DP_AUX_TRANS_CTRL); data &= ~DP_AUX_TRANS_CTRL_GO; dp_write_aux(catalog, REG_DP_AUX_TRANS_CTRL, data); } else { dp_write_aux(catalog, REG_DP_AUX_TRANS_CTRL, 0); } return 0; } int dp_catalog_aux_clear_hw_interrupts(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_read_aux(catalog, REG_DP_PHY_AUX_INTERRUPT_STATUS); dp_write_aux(catalog, REG_DP_PHY_AUX_INTERRUPT_CLEAR, 0x1f); dp_write_aux(catalog, REG_DP_PHY_AUX_INTERRUPT_CLEAR, 0x9f); dp_write_aux(catalog, REG_DP_PHY_AUX_INTERRUPT_CLEAR, 0); return 0; } /** * dp_catalog_aux_reset() - reset AUX controller * * @dp_catalog: DP catalog structure * * return: void * * This function reset AUX controller * * NOTE: reset AUX controller will also clear any pending HPD related interrupts * */ void dp_catalog_aux_reset(struct dp_catalog *dp_catalog) { u32 aux_ctrl; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); aux_ctrl = dp_read_aux(catalog, REG_DP_AUX_CTRL); aux_ctrl |= DP_AUX_CTRL_RESET; dp_write_aux(catalog, REG_DP_AUX_CTRL, aux_ctrl); usleep_range(1000, 1100); /* h/w recommended delay */ aux_ctrl &= ~DP_AUX_CTRL_RESET; dp_write_aux(catalog, REG_DP_AUX_CTRL, aux_ctrl); } void dp_catalog_aux_enable(struct dp_catalog *dp_catalog, bool enable) { u32 aux_ctrl; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); aux_ctrl = dp_read_aux(catalog, REG_DP_AUX_CTRL); if (enable) { dp_write_aux(catalog, REG_DP_TIMEOUT_COUNT, 0xffff); dp_write_aux(catalog, REG_DP_AUX_LIMITS, 0xffff); aux_ctrl |= DP_AUX_CTRL_ENABLE; } else { aux_ctrl &= ~DP_AUX_CTRL_ENABLE; } dp_write_aux(catalog, REG_DP_AUX_CTRL, aux_ctrl); } int dp_catalog_aux_wait_for_hpd_connect_state(struct dp_catalog *dp_catalog, unsigned long wait_us) { u32 state; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); /* poll for hpd connected status every 2ms and timeout after wait_us */ return readl_poll_timeout(catalog->io.aux.base + REG_DP_DP_HPD_INT_STATUS, state, state & DP_DP_HPD_STATE_STATUS_CONNECTED, min(wait_us, 2000), wait_us); } static void dump_regs(void __iomem *base, int len) { int i; u32 x0, x4, x8, xc; u32 addr_off = 0; len = DIV_ROUND_UP(len, 16); for (i = 0; i < len; i++) { x0 = readl_relaxed(base + addr_off); x4 = readl_relaxed(base + addr_off + 0x04); x8 = readl_relaxed(base + addr_off + 0x08); xc = readl_relaxed(base + addr_off + 0x0c); pr_info("%08x: %08x %08x %08x %08x", addr_off, x0, x4, x8, xc); addr_off += 16; } } void dp_catalog_dump_regs(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); struct dss_io_data *io = &catalog->io; pr_info("AHB regs\n"); dump_regs(io->ahb.base, io->ahb.len); pr_info("AUXCLK regs\n"); dump_regs(io->aux.base, io->aux.len); pr_info("LCLK regs\n"); dump_regs(io->link.base, io->link.len); pr_info("P0CLK regs\n"); dump_regs(io->p0.base, io->p0.len); } u32 dp_catalog_aux_get_irq(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 intr, intr_ack; intr = dp_read_ahb(catalog, REG_DP_INTR_STATUS); intr &= ~DP_INTERRUPT_STATUS1_MASK; intr_ack = (intr & DP_INTERRUPT_STATUS1) << DP_INTERRUPT_STATUS_ACK_SHIFT; dp_write_ahb(catalog, REG_DP_INTR_STATUS, intr_ack | DP_INTERRUPT_STATUS1_MASK); return intr; } /* controller related catalog functions */ void dp_catalog_ctrl_update_transfer_unit(struct dp_catalog *dp_catalog, u32 dp_tu, u32 valid_boundary, u32 valid_boundary2) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_write_link(catalog, REG_DP_VALID_BOUNDARY, valid_boundary); dp_write_link(catalog, REG_DP_TU, dp_tu); dp_write_link(catalog, REG_DP_VALID_BOUNDARY_2, valid_boundary2); } void dp_catalog_ctrl_state_ctrl(struct dp_catalog *dp_catalog, u32 state) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_write_link(catalog, REG_DP_STATE_CTRL, state); } void dp_catalog_ctrl_config_ctrl(struct dp_catalog *dp_catalog, u32 cfg) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); drm_dbg_dp(catalog->drm_dev, "DP_CONFIGURATION_CTRL=0x%x\n", cfg); dp_write_link(catalog, REG_DP_CONFIGURATION_CTRL, cfg); } void dp_catalog_ctrl_lane_mapping(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 ln_0 = 0, ln_1 = 1, ln_2 = 2, ln_3 = 3; /* One-to-One mapping */ u32 ln_mapping; ln_mapping = ln_0 << LANE0_MAPPING_SHIFT; ln_mapping |= ln_1 << LANE1_MAPPING_SHIFT; ln_mapping |= ln_2 << LANE2_MAPPING_SHIFT; ln_mapping |= ln_3 << LANE3_MAPPING_SHIFT; dp_write_link(catalog, REG_DP_LOGICAL2PHYSICAL_LANE_MAPPING, ln_mapping); } void dp_catalog_ctrl_psr_mainlink_enable(struct dp_catalog *dp_catalog, bool enable) { u32 val; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); val = dp_read_link(catalog, REG_DP_MAINLINK_CTRL); if (enable) val |= DP_MAINLINK_CTRL_ENABLE; else val &= ~DP_MAINLINK_CTRL_ENABLE; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, val); } void dp_catalog_ctrl_mainlink_ctrl(struct dp_catalog *dp_catalog, bool enable) { u32 mainlink_ctrl; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); drm_dbg_dp(catalog->drm_dev, "enable=%d\n", enable); if (enable) { /* * To make sure link reg writes happens before other operation, * dp_write_link() function uses writel() */ mainlink_ctrl = dp_read_link(catalog, REG_DP_MAINLINK_CTRL); mainlink_ctrl &= ~(DP_MAINLINK_CTRL_RESET | DP_MAINLINK_CTRL_ENABLE); dp_write_link(catalog, REG_DP_MAINLINK_CTRL, mainlink_ctrl); mainlink_ctrl |= DP_MAINLINK_CTRL_RESET; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, mainlink_ctrl); mainlink_ctrl &= ~DP_MAINLINK_CTRL_RESET; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, mainlink_ctrl); mainlink_ctrl |= (DP_MAINLINK_CTRL_ENABLE | DP_MAINLINK_FB_BOUNDARY_SEL); dp_write_link(catalog, REG_DP_MAINLINK_CTRL, mainlink_ctrl); } else { mainlink_ctrl = dp_read_link(catalog, REG_DP_MAINLINK_CTRL); mainlink_ctrl &= ~DP_MAINLINK_CTRL_ENABLE; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, mainlink_ctrl); } } void dp_catalog_ctrl_config_misc(struct dp_catalog *dp_catalog, u32 colorimetry_cfg, u32 test_bits_depth) { u32 misc_val; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); misc_val = dp_read_link(catalog, REG_DP_MISC1_MISC0); /* clear bpp bits */ misc_val &= ~(0x07 << DP_MISC0_TEST_BITS_DEPTH_SHIFT); misc_val |= colorimetry_cfg << DP_MISC0_COLORIMETRY_CFG_SHIFT; misc_val |= test_bits_depth << DP_MISC0_TEST_BITS_DEPTH_SHIFT; /* Configure clock to synchronous mode */ misc_val |= DP_MISC0_SYNCHRONOUS_CLK; drm_dbg_dp(catalog->drm_dev, "misc settings = 0x%x\n", misc_val); dp_write_link(catalog, REG_DP_MISC1_MISC0, misc_val); } void dp_catalog_setup_peripheral_flush(struct dp_catalog *dp_catalog) { u32 mainlink_ctrl, hw_revision; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); mainlink_ctrl = dp_read_link(catalog, REG_DP_MAINLINK_CTRL); hw_revision = dp_catalog_hw_revision(dp_catalog); if (hw_revision >= DP_HW_VERSION_1_2) mainlink_ctrl |= DP_MAINLINK_FLUSH_MODE_SDE_PERIPH_UPDATE; else mainlink_ctrl |= DP_MAINLINK_FLUSH_MODE_UPDATE_SDP; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, mainlink_ctrl); } void dp_catalog_ctrl_config_msa(struct dp_catalog *dp_catalog, u32 rate, u32 stream_rate_khz, bool is_ycbcr_420) { u32 pixel_m, pixel_n; u32 mvid, nvid, pixel_div = 0, dispcc_input_rate; u32 const nvid_fixed = DP_LINK_CONSTANT_N_VALUE; u32 const link_rate_hbr2 = 540000; u32 const link_rate_hbr3 = 810000; unsigned long den, num; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); if (rate == link_rate_hbr3) pixel_div = 6; else if (rate == 162000 || rate == 270000) pixel_div = 2; else if (rate == link_rate_hbr2) pixel_div = 4; else DRM_ERROR("Invalid pixel mux divider\n"); dispcc_input_rate = (rate * 10) / pixel_div; rational_best_approximation(dispcc_input_rate, stream_rate_khz, (unsigned long)(1 << 16) - 1, (unsigned long)(1 << 16) - 1, &den, &num); den = ~(den - num); den = den & 0xFFFF; pixel_m = num; pixel_n = den; mvid = (pixel_m & 0xFFFF) * 5; nvid = (0xFFFF & (~pixel_n)) + (pixel_m & 0xFFFF); if (nvid < nvid_fixed) { u32 temp; temp = (nvid_fixed / nvid) * nvid; mvid = (nvid_fixed / nvid) * mvid; nvid = temp; } if (is_ycbcr_420) mvid /= 2; if (link_rate_hbr2 == rate) nvid *= 2; if (link_rate_hbr3 == rate) nvid *= 3; drm_dbg_dp(catalog->drm_dev, "mvid=0x%x, nvid=0x%x\n", mvid, nvid); dp_write_link(catalog, REG_DP_SOFTWARE_MVID, mvid); dp_write_link(catalog, REG_DP_SOFTWARE_NVID, nvid); dp_write_p0(catalog, MMSS_DP_DSC_DTO, 0x0); } int dp_catalog_ctrl_set_pattern_state_bit(struct dp_catalog *dp_catalog, u32 state_bit) { int bit, ret; u32 data; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); bit = BIT(state_bit - 1); drm_dbg_dp(catalog->drm_dev, "hw: bit=%d train=%d\n", bit, state_bit); dp_catalog_ctrl_state_ctrl(dp_catalog, bit); bit = BIT(state_bit - 1) << DP_MAINLINK_READY_LINK_TRAINING_SHIFT; /* Poll for mainlink ready status */ ret = readx_poll_timeout(readl, catalog->io.link.base + REG_DP_MAINLINK_READY, data, data & bit, POLLING_SLEEP_US, POLLING_TIMEOUT_US); if (ret < 0) { DRM_ERROR("set state_bit for link_train=%d failed\n", state_bit); return ret; } return 0; } /** * dp_catalog_hw_revision() - retrieve DP hw revision * * @dp_catalog: DP catalog structure * * Return: DP controller hw revision * */ u32 dp_catalog_hw_revision(const struct dp_catalog *dp_catalog) { const struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); return dp_read_ahb(catalog, REG_DP_HW_VERSION); } /** * dp_catalog_ctrl_reset() - reset DP controller * * @dp_catalog: DP catalog structure * * return: void * * This function reset the DP controller * * NOTE: reset DP controller will also clear any pending HPD related interrupts * */ void dp_catalog_ctrl_reset(struct dp_catalog *dp_catalog) { u32 sw_reset; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); sw_reset = dp_read_ahb(catalog, REG_DP_SW_RESET); sw_reset |= DP_SW_RESET; dp_write_ahb(catalog, REG_DP_SW_RESET, sw_reset); usleep_range(1000, 1100); /* h/w recommended delay */ sw_reset &= ~DP_SW_RESET; dp_write_ahb(catalog, REG_DP_SW_RESET, sw_reset); } bool dp_catalog_ctrl_mainlink_ready(struct dp_catalog *dp_catalog) { u32 data; int ret; struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); /* Poll for mainlink ready status */ ret = readl_poll_timeout(catalog->io.link.base + REG_DP_MAINLINK_READY, data, data & DP_MAINLINK_READY_FOR_VIDEO, POLLING_SLEEP_US, POLLING_TIMEOUT_US); if (ret < 0) { DRM_ERROR("mainlink not ready\n"); return false; } return true; } void dp_catalog_ctrl_enable_irq(struct dp_catalog *dp_catalog, bool enable) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); if (enable) { dp_write_ahb(catalog, REG_DP_INTR_STATUS, DP_INTERRUPT_STATUS1_MASK); dp_write_ahb(catalog, REG_DP_INTR_STATUS2, DP_INTERRUPT_STATUS2_MASK); } else { dp_write_ahb(catalog, REG_DP_INTR_STATUS, 0x00); dp_write_ahb(catalog, REG_DP_INTR_STATUS2, 0x00); } } void dp_catalog_hpd_config_intr(struct dp_catalog *dp_catalog, u32 intr_mask, bool en) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 config = dp_read_aux(catalog, REG_DP_DP_HPD_INT_MASK); config = (en ? config | intr_mask : config & ~intr_mask); drm_dbg_dp(catalog->drm_dev, "intr_mask=%#x config=%#x\n", intr_mask, config); dp_write_aux(catalog, REG_DP_DP_HPD_INT_MASK, config & DP_DP_HPD_INT_MASK); } void dp_catalog_ctrl_hpd_enable(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 reftimer = dp_read_aux(catalog, REG_DP_DP_HPD_REFTIMER); /* Configure REFTIMER and enable it */ reftimer |= DP_DP_HPD_REFTIMER_ENABLE; dp_write_aux(catalog, REG_DP_DP_HPD_REFTIMER, reftimer); /* Enable HPD */ dp_write_aux(catalog, REG_DP_DP_HPD_CTRL, DP_DP_HPD_CTRL_HPD_EN); } void dp_catalog_ctrl_hpd_disable(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 reftimer = dp_read_aux(catalog, REG_DP_DP_HPD_REFTIMER); reftimer &= ~DP_DP_HPD_REFTIMER_ENABLE; dp_write_aux(catalog, REG_DP_DP_HPD_REFTIMER, reftimer); dp_write_aux(catalog, REG_DP_DP_HPD_CTRL, 0); } static void dp_catalog_enable_sdp(struct dp_catalog_private *catalog) { /* trigger sdp */ dp_write_link(catalog, MMSS_DP_SDP_CFG3, UPDATE_SDP); dp_write_link(catalog, MMSS_DP_SDP_CFG3, 0x0); } void dp_catalog_ctrl_config_psr(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 config; /* enable PSR1 function */ config = dp_read_link(catalog, REG_PSR_CONFIG); config |= PSR1_SUPPORTED; dp_write_link(catalog, REG_PSR_CONFIG, config); dp_write_ahb(catalog, REG_DP_INTR_MASK4, DP_INTERRUPT_MASK4); dp_catalog_enable_sdp(catalog); } void dp_catalog_ctrl_set_psr(struct dp_catalog *dp_catalog, bool enter) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 cmd; cmd = dp_read_link(catalog, REG_PSR_CMD); cmd &= ~(PSR_ENTER | PSR_EXIT); if (enter) cmd |= PSR_ENTER; else cmd |= PSR_EXIT; dp_catalog_enable_sdp(catalog); dp_write_link(catalog, REG_PSR_CMD, cmd); } u32 dp_catalog_link_is_connected(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 status; status = dp_read_aux(catalog, REG_DP_DP_HPD_INT_STATUS); drm_dbg_dp(catalog->drm_dev, "aux status: %#x\n", status); status >>= DP_DP_HPD_STATE_STATUS_BITS_SHIFT; status &= DP_DP_HPD_STATE_STATUS_BITS_MASK; return status; } u32 dp_catalog_hpd_get_intr_status(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); int isr, mask; isr = dp_read_aux(catalog, REG_DP_DP_HPD_INT_STATUS); dp_write_aux(catalog, REG_DP_DP_HPD_INT_ACK, (isr & DP_DP_HPD_INT_MASK)); mask = dp_read_aux(catalog, REG_DP_DP_HPD_INT_MASK); /* * We only want to return interrupts that are unmasked to the caller. * However, the interrupt status field also contains other * informational bits about the HPD state status, so we only mask * out the part of the register that tells us about which interrupts * are pending. */ return isr & (mask | ~DP_DP_HPD_INT_MASK); } u32 dp_catalog_ctrl_read_psr_interrupt_status(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 intr, intr_ack; intr = dp_read_ahb(catalog, REG_DP_INTR_STATUS4); intr_ack = (intr & DP_INTERRUPT_STATUS4) << DP_INTERRUPT_STATUS_ACK_SHIFT; dp_write_ahb(catalog, REG_DP_INTR_STATUS4, intr_ack); return intr; } int dp_catalog_ctrl_get_interrupt(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 intr, intr_ack; intr = dp_read_ahb(catalog, REG_DP_INTR_STATUS2); intr &= ~DP_INTERRUPT_STATUS2_MASK; intr_ack = (intr & DP_INTERRUPT_STATUS2) << DP_INTERRUPT_STATUS_ACK_SHIFT; dp_write_ahb(catalog, REG_DP_INTR_STATUS2, intr_ack | DP_INTERRUPT_STATUS2_MASK); return intr; } void dp_catalog_ctrl_phy_reset(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_write_ahb(catalog, REG_DP_PHY_CTRL, DP_PHY_CTRL_SW_RESET | DP_PHY_CTRL_SW_RESET_PLL); usleep_range(1000, 1100); /* h/w recommended delay */ dp_write_ahb(catalog, REG_DP_PHY_CTRL, 0x0); } void dp_catalog_ctrl_send_phy_pattern(struct dp_catalog *dp_catalog, u32 pattern) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 value = 0x0; /* Make sure to clear the current pattern before starting a new one */ dp_write_link(catalog, REG_DP_STATE_CTRL, 0x0); drm_dbg_dp(catalog->drm_dev, "pattern: %#x\n", pattern); switch (pattern) { case DP_PHY_TEST_PATTERN_D10_2: dp_write_link(catalog, REG_DP_STATE_CTRL, DP_STATE_CTRL_LINK_TRAINING_PATTERN1); break; case DP_PHY_TEST_PATTERN_ERROR_COUNT: value &= ~(1 << 16); dp_write_link(catalog, REG_DP_HBR2_COMPLIANCE_SCRAMBLER_RESET, value); value |= SCRAMBLER_RESET_COUNT_VALUE; dp_write_link(catalog, REG_DP_HBR2_COMPLIANCE_SCRAMBLER_RESET, value); dp_write_link(catalog, REG_DP_MAINLINK_LEVELS, DP_MAINLINK_SAFE_TO_EXIT_LEVEL_2); dp_write_link(catalog, REG_DP_STATE_CTRL, DP_STATE_CTRL_LINK_SYMBOL_ERR_MEASURE); break; case DP_PHY_TEST_PATTERN_PRBS7: dp_write_link(catalog, REG_DP_STATE_CTRL, DP_STATE_CTRL_LINK_PRBS7); break; case DP_PHY_TEST_PATTERN_80BIT_CUSTOM: dp_write_link(catalog, REG_DP_STATE_CTRL, DP_STATE_CTRL_LINK_TEST_CUSTOM_PATTERN); /* 00111110000011111000001111100000 */ dp_write_link(catalog, REG_DP_TEST_80BIT_CUSTOM_PATTERN_REG0, 0x3E0F83E0); /* 00001111100000111110000011111000 */ dp_write_link(catalog, REG_DP_TEST_80BIT_CUSTOM_PATTERN_REG1, 0x0F83E0F8); /* 1111100000111110 */ dp_write_link(catalog, REG_DP_TEST_80BIT_CUSTOM_PATTERN_REG2, 0x0000F83E); break; case DP_PHY_TEST_PATTERN_CP2520: value = dp_read_link(catalog, REG_DP_MAINLINK_CTRL); value &= ~DP_MAINLINK_CTRL_SW_BYPASS_SCRAMBLER; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, value); value = DP_HBR2_ERM_PATTERN; dp_write_link(catalog, REG_DP_HBR2_COMPLIANCE_SCRAMBLER_RESET, value); value |= SCRAMBLER_RESET_COUNT_VALUE; dp_write_link(catalog, REG_DP_HBR2_COMPLIANCE_SCRAMBLER_RESET, value); dp_write_link(catalog, REG_DP_MAINLINK_LEVELS, DP_MAINLINK_SAFE_TO_EXIT_LEVEL_2); dp_write_link(catalog, REG_DP_STATE_CTRL, DP_STATE_CTRL_LINK_SYMBOL_ERR_MEASURE); value = dp_read_link(catalog, REG_DP_MAINLINK_CTRL); value |= DP_MAINLINK_CTRL_ENABLE; dp_write_link(catalog, REG_DP_MAINLINK_CTRL, value); break; case DP_PHY_TEST_PATTERN_SEL_MASK: dp_write_link(catalog, REG_DP_MAINLINK_CTRL, DP_MAINLINK_CTRL_ENABLE); dp_write_link(catalog, REG_DP_STATE_CTRL, DP_STATE_CTRL_LINK_TRAINING_PATTERN4); break; default: drm_dbg_dp(catalog->drm_dev, "No valid test pattern requested: %#x\n", pattern); break; } } u32 dp_catalog_ctrl_read_phy_pattern(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); return dp_read_link(catalog, REG_DP_MAINLINK_READY); } /* panel related catalog functions */ int dp_catalog_panel_timing_cfg(struct dp_catalog *dp_catalog, u32 total, u32 sync_start, u32 width_blanking, u32 dp_active) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 reg; dp_write_link(catalog, REG_DP_TOTAL_HOR_VER, total); dp_write_link(catalog, REG_DP_START_HOR_VER_FROM_SYNC, sync_start); dp_write_link(catalog, REG_DP_HSYNC_VSYNC_WIDTH_POLARITY, width_blanking); dp_write_link(catalog, REG_DP_ACTIVE_HOR_VER, dp_active); reg = dp_read_p0(catalog, MMSS_DP_INTF_CONFIG); if (dp_catalog->wide_bus_en) reg |= DP_INTF_CONFIG_DATABUS_WIDEN; else reg &= ~DP_INTF_CONFIG_DATABUS_WIDEN; DRM_DEBUG_DP("wide_bus_en=%d reg=%#x\n", dp_catalog->wide_bus_en, reg); dp_write_p0(catalog, MMSS_DP_INTF_CONFIG, reg); return 0; } static void dp_catalog_panel_send_vsc_sdp(struct dp_catalog *dp_catalog, struct dp_sdp *vsc_sdp) { struct dp_catalog_private *catalog; u32 header[2]; u32 val; int i; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_utils_pack_sdp_header(&vsc_sdp->sdp_header, header); dp_write_link(catalog, MMSS_DP_GENERIC0_0, header[0]); dp_write_link(catalog, MMSS_DP_GENERIC0_1, header[1]); for (i = 0; i < sizeof(vsc_sdp->db); i += 4) { val = ((vsc_sdp->db[i]) | (vsc_sdp->db[i + 1] << 8) | (vsc_sdp->db[i + 2] << 16) | (vsc_sdp->db[i + 3] << 24)); dp_write_link(catalog, MMSS_DP_GENERIC0_2 + i, val); } } static void dp_catalog_panel_update_sdp(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog; u32 hw_revision; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); hw_revision = dp_catalog_hw_revision(dp_catalog); if (hw_revision < DP_HW_VERSION_1_2 && hw_revision >= DP_HW_VERSION_1_0) { dp_write_link(catalog, MMSS_DP_SDP_CFG3, 0x01); dp_write_link(catalog, MMSS_DP_SDP_CFG3, 0x00); } } void dp_catalog_panel_enable_vsc_sdp(struct dp_catalog *dp_catalog, struct dp_sdp *vsc_sdp) { struct dp_catalog_private *catalog; u32 cfg, cfg2, misc; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); cfg = dp_read_link(catalog, MMSS_DP_SDP_CFG); cfg2 = dp_read_link(catalog, MMSS_DP_SDP_CFG2); misc = dp_read_link(catalog, REG_DP_MISC1_MISC0); cfg |= GEN0_SDP_EN; dp_write_link(catalog, MMSS_DP_SDP_CFG, cfg); cfg2 |= GENERIC0_SDPSIZE_VALID; dp_write_link(catalog, MMSS_DP_SDP_CFG2, cfg2); dp_catalog_panel_send_vsc_sdp(dp_catalog, vsc_sdp); /* indicates presence of VSC (BIT(6) of MISC1) */ misc |= DP_MISC1_VSC_SDP; drm_dbg_dp(catalog->drm_dev, "vsc sdp enable=1\n"); pr_debug("misc settings = 0x%x\n", misc); dp_write_link(catalog, REG_DP_MISC1_MISC0, misc); dp_catalog_panel_update_sdp(dp_catalog); } void dp_catalog_panel_disable_vsc_sdp(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog; u32 cfg, cfg2, misc; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); cfg = dp_read_link(catalog, MMSS_DP_SDP_CFG); cfg2 = dp_read_link(catalog, MMSS_DP_SDP_CFG2); misc = dp_read_link(catalog, REG_DP_MISC1_MISC0); cfg &= ~GEN0_SDP_EN; dp_write_link(catalog, MMSS_DP_SDP_CFG, cfg); cfg2 &= ~GENERIC0_SDPSIZE_VALID; dp_write_link(catalog, MMSS_DP_SDP_CFG2, cfg2); /* switch back to MSA */ misc &= ~DP_MISC1_VSC_SDP; drm_dbg_dp(catalog->drm_dev, "vsc sdp enable=0\n"); pr_debug("misc settings = 0x%x\n", misc); dp_write_link(catalog, REG_DP_MISC1_MISC0, misc); dp_catalog_panel_update_sdp(dp_catalog); } void dp_catalog_panel_tpg_enable(struct dp_catalog *dp_catalog, struct drm_display_mode *drm_mode) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); u32 hsync_period, vsync_period; u32 display_v_start, display_v_end; u32 hsync_start_x, hsync_end_x; u32 v_sync_width; u32 hsync_ctl; u32 display_hctl; /* TPG config parameters*/ hsync_period = drm_mode->htotal; vsync_period = drm_mode->vtotal; display_v_start = ((drm_mode->vtotal - drm_mode->vsync_start) * hsync_period); display_v_end = ((vsync_period - (drm_mode->vsync_start - drm_mode->vdisplay)) * hsync_period) - 1; display_v_start += drm_mode->htotal - drm_mode->hsync_start; display_v_end -= (drm_mode->hsync_start - drm_mode->hdisplay); hsync_start_x = drm_mode->htotal - drm_mode->hsync_start; hsync_end_x = hsync_period - (drm_mode->hsync_start - drm_mode->hdisplay) - 1; v_sync_width = drm_mode->vsync_end - drm_mode->vsync_start; hsync_ctl = (hsync_period << 16) | (drm_mode->hsync_end - drm_mode->hsync_start); display_hctl = (hsync_end_x << 16) | hsync_start_x; dp_write_p0(catalog, MMSS_DP_INTF_CONFIG, 0x0); dp_write_p0(catalog, MMSS_DP_INTF_HSYNC_CTL, hsync_ctl); dp_write_p0(catalog, MMSS_DP_INTF_VSYNC_PERIOD_F0, vsync_period * hsync_period); dp_write_p0(catalog, MMSS_DP_INTF_VSYNC_PULSE_WIDTH_F0, v_sync_width * hsync_period); dp_write_p0(catalog, MMSS_DP_INTF_VSYNC_PERIOD_F1, 0); dp_write_p0(catalog, MMSS_DP_INTF_VSYNC_PULSE_WIDTH_F1, 0); dp_write_p0(catalog, MMSS_DP_INTF_DISPLAY_HCTL, display_hctl); dp_write_p0(catalog, MMSS_DP_INTF_ACTIVE_HCTL, 0); dp_write_p0(catalog, MMSS_INTF_DISPLAY_V_START_F0, display_v_start); dp_write_p0(catalog, MMSS_DP_INTF_DISPLAY_V_END_F0, display_v_end); dp_write_p0(catalog, MMSS_INTF_DISPLAY_V_START_F1, 0); dp_write_p0(catalog, MMSS_DP_INTF_DISPLAY_V_END_F1, 0); dp_write_p0(catalog, MMSS_DP_INTF_ACTIVE_V_START_F0, 0); dp_write_p0(catalog, MMSS_DP_INTF_ACTIVE_V_END_F0, 0); dp_write_p0(catalog, MMSS_DP_INTF_ACTIVE_V_START_F1, 0); dp_write_p0(catalog, MMSS_DP_INTF_ACTIVE_V_END_F1, 0); dp_write_p0(catalog, MMSS_DP_INTF_POLARITY_CTL, 0); dp_write_p0(catalog, MMSS_DP_TPG_MAIN_CONTROL, DP_TPG_CHECKERED_RECT_PATTERN); dp_write_p0(catalog, MMSS_DP_TPG_VIDEO_CONFIG, DP_TPG_VIDEO_CONFIG_BPP_8BIT | DP_TPG_VIDEO_CONFIG_RGB); dp_write_p0(catalog, MMSS_DP_BIST_ENABLE, DP_BIST_ENABLE_DPBIST_EN); dp_write_p0(catalog, MMSS_DP_TIMING_ENGINE_EN, DP_TIMING_ENGINE_EN_EN); drm_dbg_dp(catalog->drm_dev, "%s: enabled tpg\n", __func__); } void dp_catalog_panel_tpg_disable(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); dp_write_p0(catalog, MMSS_DP_TPG_MAIN_CONTROL, 0x0); dp_write_p0(catalog, MMSS_DP_BIST_ENABLE, 0x0); dp_write_p0(catalog, MMSS_DP_TIMING_ENGINE_EN, 0x0); } static void __iomem *dp_ioremap(struct platform_device *pdev, int idx, size_t *len) { struct resource *res; void __iomem *base; base = devm_platform_get_and_ioremap_resource(pdev, idx, &res); if (!IS_ERR(base)) *len = resource_size(res); return base; } static int dp_catalog_get_io(struct dp_catalog_private *catalog) { struct platform_device *pdev = to_platform_device(catalog->dev); struct dss_io_data *dss = &catalog->io; dss->ahb.base = dp_ioremap(pdev, 0, &dss->ahb.len); if (IS_ERR(dss->ahb.base)) return PTR_ERR(dss->ahb.base); dss->aux.base = dp_ioremap(pdev, 1, &dss->aux.len); if (IS_ERR(dss->aux.base)) { /* * The initial binding had a single reg, but in order to * support variation in the sub-region sizes this was split. * dp_ioremap() will fail with -EINVAL here if only a single * reg is specified, so fill in the sub-region offsets and * lengths based on this single region. */ if (PTR_ERR(dss->aux.base) == -EINVAL) { if (dss->ahb.len < DP_DEFAULT_P0_OFFSET + DP_DEFAULT_P0_SIZE) { DRM_ERROR("legacy memory region not large enough\n"); return -EINVAL; } dss->ahb.len = DP_DEFAULT_AHB_SIZE; dss->aux.base = dss->ahb.base + DP_DEFAULT_AUX_OFFSET; dss->aux.len = DP_DEFAULT_AUX_SIZE; dss->link.base = dss->ahb.base + DP_DEFAULT_LINK_OFFSET; dss->link.len = DP_DEFAULT_LINK_SIZE; dss->p0.base = dss->ahb.base + DP_DEFAULT_P0_OFFSET; dss->p0.len = DP_DEFAULT_P0_SIZE; } else { DRM_ERROR("unable to remap aux region: %pe\n", dss->aux.base); return PTR_ERR(dss->aux.base); } } else { dss->link.base = dp_ioremap(pdev, 2, &dss->link.len); if (IS_ERR(dss->link.base)) { DRM_ERROR("unable to remap link region: %pe\n", dss->link.base); return PTR_ERR(dss->link.base); } dss->p0.base = dp_ioremap(pdev, 3, &dss->p0.len); if (IS_ERR(dss->p0.base)) { DRM_ERROR("unable to remap p0 region: %pe\n", dss->p0.base); return PTR_ERR(dss->p0.base); } } return 0; } struct dp_catalog *dp_catalog_get(struct device *dev) { struct dp_catalog_private *catalog; int ret; catalog = devm_kzalloc(dev, sizeof(*catalog), GFP_KERNEL); if (!catalog) return ERR_PTR(-ENOMEM); catalog->dev = dev; ret = dp_catalog_get_io(catalog); if (ret) return ERR_PTR(ret); return &catalog->dp_catalog; } u32 dp_catalog_audio_get_header(struct dp_catalog *dp_catalog, enum dp_catalog_audio_sdp_type sdp, enum dp_catalog_audio_header_type header) { struct dp_catalog_private *catalog; u32 (*sdp_map)[DP_AUDIO_SDP_HEADER_MAX]; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); sdp_map = catalog->audio_map; return dp_read_link(catalog, sdp_map[sdp][header]); } void dp_catalog_audio_set_header(struct dp_catalog *dp_catalog, enum dp_catalog_audio_sdp_type sdp, enum dp_catalog_audio_header_type header, u32 data) { struct dp_catalog_private *catalog; u32 (*sdp_map)[DP_AUDIO_SDP_HEADER_MAX]; if (!dp_catalog) return; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); sdp_map = catalog->audio_map; dp_write_link(catalog, sdp_map[sdp][header], data); } void dp_catalog_audio_config_acr(struct dp_catalog *dp_catalog, u32 select) { struct dp_catalog_private *catalog; u32 acr_ctrl; if (!dp_catalog) return; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); acr_ctrl = select << 4 | BIT(31) | BIT(8) | BIT(14); drm_dbg_dp(catalog->drm_dev, "select: %#x, acr_ctrl: %#x\n", select, acr_ctrl); dp_write_link(catalog, MMSS_DP_AUDIO_ACR_CTRL, acr_ctrl); } void dp_catalog_audio_enable(struct dp_catalog *dp_catalog, bool enable) { struct dp_catalog_private *catalog; u32 audio_ctrl; if (!dp_catalog) return; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); audio_ctrl = dp_read_link(catalog, MMSS_DP_AUDIO_CFG); if (enable) audio_ctrl |= BIT(0); else audio_ctrl &= ~BIT(0); drm_dbg_dp(catalog->drm_dev, "dp_audio_cfg = 0x%x\n", audio_ctrl); dp_write_link(catalog, MMSS_DP_AUDIO_CFG, audio_ctrl); /* make sure audio engine is disabled */ wmb(); } void dp_catalog_audio_config_sdp(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog; u32 sdp_cfg = 0; u32 sdp_cfg2 = 0; if (!dp_catalog) return; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); sdp_cfg = dp_read_link(catalog, MMSS_DP_SDP_CFG); /* AUDIO_TIMESTAMP_SDP_EN */ sdp_cfg |= BIT(1); /* AUDIO_STREAM_SDP_EN */ sdp_cfg |= BIT(2); /* AUDIO_COPY_MANAGEMENT_SDP_EN */ sdp_cfg |= BIT(5); /* AUDIO_ISRC_SDP_EN */ sdp_cfg |= BIT(6); /* AUDIO_INFOFRAME_SDP_EN */ sdp_cfg |= BIT(20); drm_dbg_dp(catalog->drm_dev, "sdp_cfg = 0x%x\n", sdp_cfg); dp_write_link(catalog, MMSS_DP_SDP_CFG, sdp_cfg); sdp_cfg2 = dp_read_link(catalog, MMSS_DP_SDP_CFG2); /* IFRM_REGSRC -> Do not use reg values */ sdp_cfg2 &= ~BIT(0); /* AUDIO_STREAM_HB3_REGSRC-> Do not use reg values */ sdp_cfg2 &= ~BIT(1); drm_dbg_dp(catalog->drm_dev, "sdp_cfg2 = 0x%x\n", sdp_cfg2); dp_write_link(catalog, MMSS_DP_SDP_CFG2, sdp_cfg2); } void dp_catalog_audio_init(struct dp_catalog *dp_catalog) { struct dp_catalog_private *catalog; static u32 sdp_map[][DP_AUDIO_SDP_HEADER_MAX] = { { MMSS_DP_AUDIO_STREAM_0, MMSS_DP_AUDIO_STREAM_1, MMSS_DP_AUDIO_STREAM_1, }, { MMSS_DP_AUDIO_TIMESTAMP_0, MMSS_DP_AUDIO_TIMESTAMP_1, MMSS_DP_AUDIO_TIMESTAMP_1, }, { MMSS_DP_AUDIO_INFOFRAME_0, MMSS_DP_AUDIO_INFOFRAME_1, MMSS_DP_AUDIO_INFOFRAME_1, }, { MMSS_DP_AUDIO_COPYMANAGEMENT_0, MMSS_DP_AUDIO_COPYMANAGEMENT_1, MMSS_DP_AUDIO_COPYMANAGEMENT_1, }, { MMSS_DP_AUDIO_ISRC_0, MMSS_DP_AUDIO_ISRC_1, MMSS_DP_AUDIO_ISRC_1, }, }; if (!dp_catalog) return; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); catalog->audio_map = sdp_map; } void dp_catalog_audio_sfe_level(struct dp_catalog *dp_catalog, u32 safe_to_exit_level) { struct dp_catalog_private *catalog; u32 mainlink_levels; if (!dp_catalog) return; catalog = container_of(dp_catalog, struct dp_catalog_private, dp_catalog); mainlink_levels = dp_read_link(catalog, REG_DP_MAINLINK_LEVELS); mainlink_levels &= 0xFE0; mainlink_levels |= safe_to_exit_level; drm_dbg_dp(catalog->drm_dev, "mainlink_level = 0x%x, safe_to_exit_level = 0x%x\n", mainlink_levels, safe_to_exit_level); dp_write_link(catalog, REG_DP_MAINLINK_LEVELS, mainlink_levels); }
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