Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Abhinav Kumar | 2623 | 96.65% | 3 | 50.00% |
Kuogee Hsieh | 90 | 3.32% | 2 | 33.33% |
Thomas Zimmermann | 1 | 0.04% | 1 | 16.67% |
Total | 2714 | 6 |
// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2016-2020, The Linux Foundation. All rights reserved. */ #define pr_fmt(fmt) "[drm-dp] %s: " fmt, __func__ #include <linux/of_platform.h> #include <drm/display/drm_dp_helper.h> #include <drm/drm_edid.h> #include "dp_catalog.h" #include "dp_audio.h" #include "dp_panel.h" #include "dp_display.h" #define HEADER_BYTE_2_BIT 0 #define PARITY_BYTE_2_BIT 8 #define HEADER_BYTE_1_BIT 16 #define PARITY_BYTE_1_BIT 24 #define HEADER_BYTE_3_BIT 16 #define PARITY_BYTE_3_BIT 24 struct dp_audio_private { struct platform_device *audio_pdev; struct platform_device *pdev; struct drm_device *drm_dev; struct dp_catalog *catalog; struct dp_panel *panel; bool engine_on; u32 channels; struct dp_audio dp_audio; }; static u8 dp_audio_get_g0_value(u8 data) { u8 c[4]; u8 g[4]; u8 ret_data = 0; u8 i; for (i = 0; i < 4; i++) c[i] = (data >> i) & 0x01; g[0] = c[3]; g[1] = c[0] ^ c[3]; g[2] = c[1]; g[3] = c[2]; for (i = 0; i < 4; i++) ret_data = ((g[i] & 0x01) << i) | ret_data; return ret_data; } static u8 dp_audio_get_g1_value(u8 data) { u8 c[4]; u8 g[4]; u8 ret_data = 0; u8 i; for (i = 0; i < 4; i++) c[i] = (data >> i) & 0x01; g[0] = c[0] ^ c[3]; g[1] = c[0] ^ c[1] ^ c[3]; g[2] = c[1] ^ c[2]; g[3] = c[2] ^ c[3]; for (i = 0; i < 4; i++) ret_data = ((g[i] & 0x01) << i) | ret_data; return ret_data; } static u8 dp_audio_calculate_parity(u32 data) { u8 x0 = 0; u8 x1 = 0; u8 ci = 0; u8 iData = 0; u8 i = 0; u8 parity_byte; u8 num_byte = (data & 0xFF00) > 0 ? 8 : 2; for (i = 0; i < num_byte; i++) { iData = (data >> i*4) & 0xF; ci = iData ^ x1; x1 = x0 ^ dp_audio_get_g1_value(ci); x0 = dp_audio_get_g0_value(ci); } parity_byte = x1 | (x0 << 4); return parity_byte; } static u32 dp_audio_get_header(struct dp_catalog *catalog, enum dp_catalog_audio_sdp_type sdp, enum dp_catalog_audio_header_type header) { catalog->sdp_type = sdp; catalog->sdp_header = header; dp_catalog_audio_get_header(catalog); return catalog->audio_data; } static void dp_audio_set_header(struct dp_catalog *catalog, u32 data, enum dp_catalog_audio_sdp_type sdp, enum dp_catalog_audio_header_type header) { catalog->sdp_type = sdp; catalog->sdp_header = header; catalog->audio_data = data; dp_catalog_audio_set_header(catalog); } static void dp_audio_stream_sdp(struct dp_audio_private *audio) { struct dp_catalog *catalog = audio->catalog; u32 value, new_value; u8 parity_byte; /* Config header and parity byte 1 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_STREAM, DP_AUDIO_SDP_HEADER_1); new_value = 0x02; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_1_BIT) | (parity_byte << PARITY_BYTE_1_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 1: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_STREAM, DP_AUDIO_SDP_HEADER_1); /* Config header and parity byte 2 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_STREAM, DP_AUDIO_SDP_HEADER_2); new_value = value; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_2_BIT) | (parity_byte << PARITY_BYTE_2_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 2: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_STREAM, DP_AUDIO_SDP_HEADER_2); /* Config header and parity byte 3 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_STREAM, DP_AUDIO_SDP_HEADER_3); new_value = audio->channels - 1; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_3_BIT) | (parity_byte << PARITY_BYTE_3_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 3: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_STREAM, DP_AUDIO_SDP_HEADER_3); } static void dp_audio_timestamp_sdp(struct dp_audio_private *audio) { struct dp_catalog *catalog = audio->catalog; u32 value, new_value; u8 parity_byte; /* Config header and parity byte 1 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_TIMESTAMP, DP_AUDIO_SDP_HEADER_1); new_value = 0x1; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_1_BIT) | (parity_byte << PARITY_BYTE_1_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 1: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_TIMESTAMP, DP_AUDIO_SDP_HEADER_1); /* Config header and parity byte 2 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_TIMESTAMP, DP_AUDIO_SDP_HEADER_2); new_value = 0x17; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_2_BIT) | (parity_byte << PARITY_BYTE_2_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 2: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_TIMESTAMP, DP_AUDIO_SDP_HEADER_2); /* Config header and parity byte 3 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_TIMESTAMP, DP_AUDIO_SDP_HEADER_3); new_value = (0x0 | (0x11 << 2)); parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_3_BIT) | (parity_byte << PARITY_BYTE_3_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 3: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_TIMESTAMP, DP_AUDIO_SDP_HEADER_3); } static void dp_audio_infoframe_sdp(struct dp_audio_private *audio) { struct dp_catalog *catalog = audio->catalog; u32 value, new_value; u8 parity_byte; /* Config header and parity byte 1 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_INFOFRAME, DP_AUDIO_SDP_HEADER_1); new_value = 0x84; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_1_BIT) | (parity_byte << PARITY_BYTE_1_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 1: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_INFOFRAME, DP_AUDIO_SDP_HEADER_1); /* Config header and parity byte 2 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_INFOFRAME, DP_AUDIO_SDP_HEADER_2); new_value = 0x1b; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_2_BIT) | (parity_byte << PARITY_BYTE_2_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 2: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_INFOFRAME, DP_AUDIO_SDP_HEADER_2); /* Config header and parity byte 3 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_INFOFRAME, DP_AUDIO_SDP_HEADER_3); new_value = (0x0 | (0x11 << 2)); parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_3_BIT) | (parity_byte << PARITY_BYTE_3_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 3: value = 0x%x, parity_byte = 0x%x\n", new_value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_INFOFRAME, DP_AUDIO_SDP_HEADER_3); } static void dp_audio_copy_management_sdp(struct dp_audio_private *audio) { struct dp_catalog *catalog = audio->catalog; u32 value, new_value; u8 parity_byte; /* Config header and parity byte 1 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_COPYMANAGEMENT, DP_AUDIO_SDP_HEADER_1); new_value = 0x05; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_1_BIT) | (parity_byte << PARITY_BYTE_1_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 1: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_COPYMANAGEMENT, DP_AUDIO_SDP_HEADER_1); /* Config header and parity byte 2 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_COPYMANAGEMENT, DP_AUDIO_SDP_HEADER_2); new_value = 0x0F; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_2_BIT) | (parity_byte << PARITY_BYTE_2_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 2: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_COPYMANAGEMENT, DP_AUDIO_SDP_HEADER_2); /* Config header and parity byte 3 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_COPYMANAGEMENT, DP_AUDIO_SDP_HEADER_3); new_value = 0x0; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_3_BIT) | (parity_byte << PARITY_BYTE_3_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 3: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_COPYMANAGEMENT, DP_AUDIO_SDP_HEADER_3); } static void dp_audio_isrc_sdp(struct dp_audio_private *audio) { struct dp_catalog *catalog = audio->catalog; u32 value, new_value; u8 parity_byte; /* Config header and parity byte 1 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_ISRC, DP_AUDIO_SDP_HEADER_1); new_value = 0x06; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_1_BIT) | (parity_byte << PARITY_BYTE_1_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 1: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_ISRC, DP_AUDIO_SDP_HEADER_1); /* Config header and parity byte 2 */ value = dp_audio_get_header(catalog, DP_AUDIO_SDP_ISRC, DP_AUDIO_SDP_HEADER_2); new_value = 0x0F; parity_byte = dp_audio_calculate_parity(new_value); value |= ((new_value << HEADER_BYTE_2_BIT) | (parity_byte << PARITY_BYTE_2_BIT)); drm_dbg_dp(audio->drm_dev, "Header Byte 2: value = 0x%x, parity_byte = 0x%x\n", value, parity_byte); dp_audio_set_header(catalog, value, DP_AUDIO_SDP_ISRC, DP_AUDIO_SDP_HEADER_2); } static void dp_audio_setup_sdp(struct dp_audio_private *audio) { dp_catalog_audio_config_sdp(audio->catalog); dp_audio_stream_sdp(audio); dp_audio_timestamp_sdp(audio); dp_audio_infoframe_sdp(audio); dp_audio_copy_management_sdp(audio); dp_audio_isrc_sdp(audio); } static void dp_audio_setup_acr(struct dp_audio_private *audio) { u32 select = 0; struct dp_catalog *catalog = audio->catalog; switch (audio->dp_audio.bw_code) { case DP_LINK_BW_1_62: select = 0; break; case DP_LINK_BW_2_7: select = 1; break; case DP_LINK_BW_5_4: select = 2; break; case DP_LINK_BW_8_1: select = 3; break; default: drm_dbg_dp(audio->drm_dev, "Unknown link rate\n"); select = 0; break; } catalog->audio_data = select; dp_catalog_audio_config_acr(catalog); } static void dp_audio_safe_to_exit_level(struct dp_audio_private *audio) { struct dp_catalog *catalog = audio->catalog; u32 safe_to_exit_level = 0; switch (audio->dp_audio.lane_count) { case 1: safe_to_exit_level = 14; break; case 2: safe_to_exit_level = 8; break; case 4: safe_to_exit_level = 5; break; default: drm_dbg_dp(audio->drm_dev, "setting the default safe_to_exit_level = %u\n", safe_to_exit_level); safe_to_exit_level = 14; break; } catalog->audio_data = safe_to_exit_level; dp_catalog_audio_sfe_level(catalog); } static void dp_audio_enable(struct dp_audio_private *audio, bool enable) { struct dp_catalog *catalog = audio->catalog; catalog->audio_data = enable; dp_catalog_audio_enable(catalog); audio->engine_on = enable; } static struct dp_audio_private *dp_audio_get_data(struct platform_device *pdev) { struct dp_audio *dp_audio; struct msm_dp *dp_display; if (!pdev) { DRM_ERROR("invalid input\n"); return ERR_PTR(-ENODEV); } dp_display = platform_get_drvdata(pdev); if (!dp_display) { DRM_ERROR("invalid input\n"); return ERR_PTR(-ENODEV); } dp_audio = dp_display->dp_audio; if (!dp_audio) { DRM_ERROR("invalid dp_audio data\n"); return ERR_PTR(-EINVAL); } return container_of(dp_audio, struct dp_audio_private, dp_audio); } static int dp_audio_hook_plugged_cb(struct device *dev, void *data, hdmi_codec_plugged_cb fn, struct device *codec_dev) { struct platform_device *pdev; struct msm_dp *dp_display; pdev = to_platform_device(dev); if (!pdev) { pr_err("invalid input\n"); return -ENODEV; } dp_display = platform_get_drvdata(pdev); if (!dp_display) { pr_err("invalid input\n"); return -ENODEV; } return dp_display_set_plugged_cb(dp_display, fn, codec_dev); } static int dp_audio_get_eld(struct device *dev, void *data, uint8_t *buf, size_t len) { struct platform_device *pdev; struct msm_dp *dp_display; pdev = to_platform_device(dev); if (!pdev) { DRM_ERROR("invalid input\n"); return -ENODEV; } dp_display = platform_get_drvdata(pdev); if (!dp_display) { DRM_ERROR("invalid input\n"); return -ENODEV; } memcpy(buf, dp_display->connector->eld, min(sizeof(dp_display->connector->eld), len)); return 0; } int dp_audio_hw_params(struct device *dev, void *data, struct hdmi_codec_daifmt *daifmt, struct hdmi_codec_params *params) { int rc = 0; struct dp_audio_private *audio; struct platform_device *pdev; struct msm_dp *dp_display; pdev = to_platform_device(dev); dp_display = platform_get_drvdata(pdev); /* * there could be cases where sound card can be opened even * before OR even when DP is not connected . This can cause * unclocked access as the audio subsystem relies on the DP * driver to maintain the correct state of clocks. To protect * such cases check for connection status and bail out if not * connected. */ if (!dp_display->power_on) { rc = -EINVAL; goto end; } audio = dp_audio_get_data(pdev); if (IS_ERR(audio)) { rc = PTR_ERR(audio); goto end; } audio->channels = params->channels; dp_audio_setup_sdp(audio); dp_audio_setup_acr(audio); dp_audio_safe_to_exit_level(audio); dp_audio_enable(audio, true); dp_display_signal_audio_start(dp_display); dp_display->audio_enabled = true; end: return rc; } static void dp_audio_shutdown(struct device *dev, void *data) { struct dp_audio_private *audio; struct platform_device *pdev; struct msm_dp *dp_display; pdev = to_platform_device(dev); dp_display = platform_get_drvdata(pdev); audio = dp_audio_get_data(pdev); if (IS_ERR(audio)) { DRM_ERROR("failed to get audio data\n"); return; } /* * if audio was not enabled there is no need * to execute the shutdown and we can bail out early. * This also makes sure that we dont cause an unclocked * access when audio subsystem calls this without DP being * connected. is_connected cannot be used here as its set * to false earlier than this call */ if (!dp_display->audio_enabled) return; dp_audio_enable(audio, false); /* signal the dp display to safely shutdown clocks */ dp_display_signal_audio_complete(dp_display); } static const struct hdmi_codec_ops dp_audio_codec_ops = { .hw_params = dp_audio_hw_params, .audio_shutdown = dp_audio_shutdown, .get_eld = dp_audio_get_eld, .hook_plugged_cb = dp_audio_hook_plugged_cb, }; static struct hdmi_codec_pdata codec_data = { .ops = &dp_audio_codec_ops, .max_i2s_channels = 8, .i2s = 1, }; int dp_register_audio_driver(struct device *dev, struct dp_audio *dp_audio) { struct dp_audio_private *audio_priv; audio_priv = container_of(dp_audio, struct dp_audio_private, dp_audio); audio_priv->audio_pdev = platform_device_register_data(dev, HDMI_CODEC_DRV_NAME, PLATFORM_DEVID_AUTO, &codec_data, sizeof(codec_data)); return PTR_ERR_OR_ZERO(audio_priv->audio_pdev); } struct dp_audio *dp_audio_get(struct platform_device *pdev, struct dp_panel *panel, struct dp_catalog *catalog) { int rc = 0; struct dp_audio_private *audio; struct dp_audio *dp_audio; if (!pdev || !panel || !catalog) { DRM_ERROR("invalid input\n"); rc = -EINVAL; goto error; } audio = devm_kzalloc(&pdev->dev, sizeof(*audio), GFP_KERNEL); if (!audio) { rc = -ENOMEM; goto error; } audio->pdev = pdev; audio->panel = panel; audio->catalog = catalog; dp_audio = &audio->dp_audio; dp_catalog_audio_init(catalog); return dp_audio; error: return ERR_PTR(rc); } void dp_audio_put(struct dp_audio *dp_audio) { struct dp_audio_private *audio; if (!dp_audio) return; audio = container_of(dp_audio, struct dp_audio_private, dp_audio); devm_kfree(&audio->pdev->dev, audio); }
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