// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2017-2020, The Linux Foundation. All rights reserved. */ #include #include #include #include #include #include #include #include #include "msm_drv.h" #include "msm_kms.h" #include "dp_hpd.h" #include "dp_parser.h" #include "dp_power.h" #include "dp_catalog.h" #include "dp_aux.h" #include "dp_reg.h" #include "dp_link.h" #include "dp_panel.h" #include "dp_ctrl.h" #include "dp_display.h" #include "dp_drm.h" #include "dp_audio.h" #include "dp_debug.h" #define HPD_STRING_SIZE 30 enum { ISR_DISCONNECTED, ISR_CONNECT_PENDING, ISR_CONNECTED, ISR_HPD_REPLUG_COUNT, ISR_IRQ_HPD_PULSE_COUNT, ISR_HPD_LO_GLITH_COUNT, }; /* event thread connection state */ enum { ST_DISCONNECTED, ST_MAINLINK_READY, ST_CONNECTED, ST_DISCONNECT_PENDING, ST_DISPLAY_OFF, ST_SUSPENDED, }; enum { EV_NO_EVENT, /* hpd events */ EV_HPD_INIT_SETUP, EV_HPD_PLUG_INT, EV_IRQ_HPD_INT, EV_HPD_UNPLUG_INT, EV_USER_NOTIFICATION, }; #define EVENT_TIMEOUT (HZ/10) /* 100ms */ #define DP_EVENT_Q_MAX 8 #define DP_TIMEOUT_NONE 0 #define WAIT_FOR_RESUME_TIMEOUT_JIFFIES (HZ / 2) struct dp_event { u32 event_id; u32 data; u32 delay; }; struct dp_display_private { char *name; int irq; unsigned int id; /* state variables */ bool core_initialized; bool phy_initialized; bool hpd_irq_on; bool audio_supported; struct drm_device *drm_dev; struct platform_device *pdev; struct dentry *root; struct dp_usbpd *usbpd; struct dp_parser *parser; struct dp_power *power; struct dp_catalog *catalog; struct drm_dp_aux *aux; struct dp_link *link; struct dp_panel *panel; struct dp_ctrl *ctrl; struct dp_debug *debug; struct dp_usbpd_cb usbpd_cb; struct dp_display_mode dp_mode; struct msm_dp dp_display; /* wait for audio signaling */ struct completion audio_comp; /* event related only access by event thread */ struct mutex event_mutex; wait_queue_head_t event_q; u32 hpd_state; u32 event_pndx; u32 event_gndx; struct task_struct *ev_tsk; struct dp_event event_list[DP_EVENT_Q_MAX]; spinlock_t event_lock; bool wide_bus_en; struct dp_audio *audio; }; struct msm_dp_desc { phys_addr_t io_start; unsigned int id; unsigned int connector_type; bool wide_bus_en; }; static const struct msm_dp_desc sc7180_dp_descs[] = { { .io_start = 0x0ae90000, .id = MSM_DP_CONTROLLER_0, .connector_type = DRM_MODE_CONNECTOR_DisplayPort }, {} }; static const struct msm_dp_desc sc7280_dp_descs[] = { { .io_start = 0x0ae90000, .id = MSM_DP_CONTROLLER_0, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x0aea0000, .id = MSM_DP_CONTROLLER_1, .connector_type = DRM_MODE_CONNECTOR_eDP, .wide_bus_en = true }, {} }; static const struct msm_dp_desc sc8180x_dp_descs[] = { { .io_start = 0x0ae90000, .id = MSM_DP_CONTROLLER_0, .connector_type = DRM_MODE_CONNECTOR_DisplayPort }, { .io_start = 0x0ae98000, .id = MSM_DP_CONTROLLER_1, .connector_type = DRM_MODE_CONNECTOR_DisplayPort }, { .io_start = 0x0ae9a000, .id = MSM_DP_CONTROLLER_2, .connector_type = DRM_MODE_CONNECTOR_eDP }, {} }; static const struct msm_dp_desc sc8280xp_dp_descs[] = { { .io_start = 0x0ae90000, .id = MSM_DP_CONTROLLER_0, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x0ae98000, .id = MSM_DP_CONTROLLER_1, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x0ae9a000, .id = MSM_DP_CONTROLLER_2, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x0aea0000, .id = MSM_DP_CONTROLLER_3, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x22090000, .id = MSM_DP_CONTROLLER_0, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x22098000, .id = MSM_DP_CONTROLLER_1, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x2209a000, .id = MSM_DP_CONTROLLER_2, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, { .io_start = 0x220a0000, .id = MSM_DP_CONTROLLER_3, .connector_type = DRM_MODE_CONNECTOR_DisplayPort, .wide_bus_en = true }, {} }; static const struct msm_dp_desc sc8280xp_edp_descs[] = { { .io_start = 0x0ae9a000, .id = MSM_DP_CONTROLLER_2, .connector_type = DRM_MODE_CONNECTOR_eDP, .wide_bus_en = true }, { .io_start = 0x0aea0000, .id = MSM_DP_CONTROLLER_3, .connector_type = DRM_MODE_CONNECTOR_eDP, .wide_bus_en = true }, { .io_start = 0x2209a000, .id = MSM_DP_CONTROLLER_2, .connector_type = DRM_MODE_CONNECTOR_eDP, .wide_bus_en = true }, { .io_start = 0x220a0000, .id = MSM_DP_CONTROLLER_3, .connector_type = DRM_MODE_CONNECTOR_eDP, .wide_bus_en = true }, {} }; static const struct msm_dp_desc sm8350_dp_descs[] = { { .io_start = 0x0ae90000, .id = MSM_DP_CONTROLLER_0, .connector_type = DRM_MODE_CONNECTOR_DisplayPort }, {} }; static const struct of_device_id dp_dt_match[] = { { .compatible = "qcom,sc7180-dp", .data = &sc7180_dp_descs }, { .compatible = "qcom,sc7280-dp", .data = &sc7280_dp_descs }, { .compatible = "qcom,sc7280-edp", .data = &sc7280_dp_descs }, { .compatible = "qcom,sc8180x-dp", .data = &sc8180x_dp_descs }, { .compatible = "qcom,sc8180x-edp", .data = &sc8180x_dp_descs }, { .compatible = "qcom,sc8280xp-dp", .data = &sc8280xp_dp_descs }, { .compatible = "qcom,sc8280xp-edp", .data = &sc8280xp_edp_descs }, { .compatible = "qcom,sdm845-dp", .data = &sc7180_dp_descs }, { .compatible = "qcom,sm8350-dp", .data = &sm8350_dp_descs }, {} }; static struct dp_display_private *dev_get_dp_display_private(struct device *dev) { struct msm_dp *dp = dev_get_drvdata(dev); return container_of(dp, struct dp_display_private, dp_display); } static int dp_add_event(struct dp_display_private *dp_priv, u32 event, u32 data, u32 delay) { unsigned long flag; struct dp_event *todo; int pndx; spin_lock_irqsave(&dp_priv->event_lock, flag); pndx = dp_priv->event_pndx + 1; pndx %= DP_EVENT_Q_MAX; if (pndx == dp_priv->event_gndx) { pr_err("event_q is full: pndx=%d gndx=%d\n", dp_priv->event_pndx, dp_priv->event_gndx); spin_unlock_irqrestore(&dp_priv->event_lock, flag); return -EPERM; } todo = &dp_priv->event_list[dp_priv->event_pndx++]; dp_priv->event_pndx %= DP_EVENT_Q_MAX; todo->event_id = event; todo->data = data; todo->delay = delay; wake_up(&dp_priv->event_q); spin_unlock_irqrestore(&dp_priv->event_lock, flag); return 0; } static int dp_del_event(struct dp_display_private *dp_priv, u32 event) { unsigned long flag; struct dp_event *todo; u32 gndx; spin_lock_irqsave(&dp_priv->event_lock, flag); if (dp_priv->event_pndx == dp_priv->event_gndx) { spin_unlock_irqrestore(&dp_priv->event_lock, flag); return -ENOENT; } gndx = dp_priv->event_gndx; while (dp_priv->event_pndx != gndx) { todo = &dp_priv->event_list[gndx]; if (todo->event_id == event) { todo->event_id = EV_NO_EVENT; /* deleted */ todo->delay = 0; } gndx++; gndx %= DP_EVENT_Q_MAX; } spin_unlock_irqrestore(&dp_priv->event_lock, flag); return 0; } void dp_display_signal_audio_start(struct msm_dp *dp_display) { struct dp_display_private *dp; dp = container_of(dp_display, struct dp_display_private, dp_display); reinit_completion(&dp->audio_comp); } void dp_display_signal_audio_complete(struct msm_dp *dp_display) { struct dp_display_private *dp; dp = container_of(dp_display, struct dp_display_private, dp_display); complete_all(&dp->audio_comp); } static int dp_hpd_event_thread_start(struct dp_display_private *dp_priv); static int dp_display_bind(struct device *dev, struct device *master, void *data) { int rc = 0; struct dp_display_private *dp = dev_get_dp_display_private(dev); struct msm_drm_private *priv = dev_get_drvdata(master); struct drm_device *drm = priv->dev; dp->dp_display.drm_dev = drm; priv->dp[dp->id] = &dp->dp_display; rc = dp->parser->parse(dp->parser); if (rc) { DRM_ERROR("device tree parsing failed\n"); goto end; } dp->drm_dev = drm; dp->aux->drm_dev = drm; rc = dp_aux_register(dp->aux); if (rc) { DRM_ERROR("DRM DP AUX register failed\n"); goto end; } rc = dp_power_client_init(dp->power); if (rc) { DRM_ERROR("Power client create failed\n"); goto end; } rc = dp_register_audio_driver(dev, dp->audio); if (rc) { DRM_ERROR("Audio registration Dp failed\n"); goto end; } rc = dp_hpd_event_thread_start(dp); if (rc) { DRM_ERROR("Event thread create failed\n"); goto end; } return 0; end: return rc; } static void dp_display_unbind(struct device *dev, struct device *master, void *data) { struct dp_display_private *dp = dev_get_dp_display_private(dev); struct msm_drm_private *priv = dev_get_drvdata(master); /* disable all HPD interrupts */ if (dp->core_initialized) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_HPD_INT_MASK, false); kthread_stop(dp->ev_tsk); dp_power_client_deinit(dp->power); dp_unregister_audio_driver(dev, dp->audio); dp_aux_unregister(dp->aux); dp->drm_dev = NULL; dp->aux->drm_dev = NULL; priv->dp[dp->id] = NULL; } static const struct component_ops dp_display_comp_ops = { .bind = dp_display_bind, .unbind = dp_display_unbind, }; static bool dp_display_is_ds_bridge(struct dp_panel *panel) { return (panel->dpcd[DP_DOWNSTREAMPORT_PRESENT] & DP_DWN_STRM_PORT_PRESENT); } static bool dp_display_is_sink_count_zero(struct dp_display_private *dp) { drm_dbg_dp(dp->drm_dev, "present=%#x sink_count=%d\n", dp->panel->dpcd[DP_DOWNSTREAMPORT_PRESENT], dp->link->sink_count); return dp_display_is_ds_bridge(dp->panel) && (dp->link->sink_count == 0); } static void dp_display_send_hpd_event(struct msm_dp *dp_display) { struct dp_display_private *dp; struct drm_connector *connector; dp = container_of(dp_display, struct dp_display_private, dp_display); connector = dp->dp_display.connector; drm_helper_hpd_irq_event(connector->dev); } static int dp_display_send_hpd_notification(struct dp_display_private *dp, bool hpd) { if ((hpd && dp->dp_display.is_connected) || (!hpd && !dp->dp_display.is_connected)) { drm_dbg_dp(dp->drm_dev, "HPD already %s\n", (hpd ? "on" : "off")); return 0; } /* reset video pattern flag on disconnect */ if (!hpd) dp->panel->video_test = false; dp->dp_display.is_connected = hpd; drm_dbg_dp(dp->drm_dev, "type=%d hpd=%d\n", dp->dp_display.connector_type, hpd); dp_display_send_hpd_event(&dp->dp_display); return 0; } static int dp_display_process_hpd_high(struct dp_display_private *dp) { int rc = 0; struct edid *edid; dp->panel->max_dp_lanes = dp->parser->max_dp_lanes; dp->panel->max_dp_link_rate = dp->parser->max_dp_link_rate; drm_dbg_dp(dp->drm_dev, "max_lanes=%d max_link_rate=%d\n", dp->panel->max_dp_lanes, dp->panel->max_dp_link_rate); rc = dp_panel_read_sink_caps(dp->panel, dp->dp_display.connector); if (rc) goto end; dp_link_process_request(dp->link); edid = dp->panel->edid; dp->audio_supported = drm_detect_monitor_audio(edid); dp_panel_handle_sink_request(dp->panel); dp->dp_display.max_dp_lanes = dp->parser->max_dp_lanes; /* * set sink to normal operation mode -- D0 * before dpcd read */ dp_link_psm_config(dp->link, &dp->panel->link_info, false); dp_link_reset_phy_params_vx_px(dp->link); rc = dp_ctrl_on_link(dp->ctrl); if (rc) { DRM_ERROR("failed to complete DP link training\n"); goto end; } dp_add_event(dp, EV_USER_NOTIFICATION, true, 0); end: return rc; } static void dp_display_host_phy_init(struct dp_display_private *dp) { drm_dbg_dp(dp->drm_dev, "type=%d core_init=%d phy_init=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized); if (!dp->phy_initialized) { dp_ctrl_phy_init(dp->ctrl); dp->phy_initialized = true; } } static void dp_display_host_phy_exit(struct dp_display_private *dp) { drm_dbg_dp(dp->drm_dev, "type=%d core_init=%d phy_init=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized); if (dp->phy_initialized) { dp_ctrl_phy_exit(dp->ctrl); dp->phy_initialized = false; } } static void dp_display_host_init(struct dp_display_private *dp) { drm_dbg_dp(dp->drm_dev, "type=%d core_init=%d phy_init=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized); dp_power_init(dp->power, false); dp_ctrl_reset_irq_ctrl(dp->ctrl, true); dp_aux_init(dp->aux); dp->core_initialized = true; } static void dp_display_host_deinit(struct dp_display_private *dp) { drm_dbg_dp(dp->drm_dev, "type=%d core_init=%d phy_init=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized); dp_ctrl_reset_irq_ctrl(dp->ctrl, false); dp_aux_deinit(dp->aux); dp_power_deinit(dp->power); dp->core_initialized = false; } static int dp_display_usbpd_configure_cb(struct device *dev) { struct dp_display_private *dp = dev_get_dp_display_private(dev); dp_display_host_phy_init(dp); return dp_display_process_hpd_high(dp); } static int dp_display_usbpd_disconnect_cb(struct device *dev) { return 0; } static int dp_display_notify_disconnect(struct device *dev) { struct dp_display_private *dp = dev_get_dp_display_private(dev); dp_add_event(dp, EV_USER_NOTIFICATION, false, 0); return 0; } static void dp_display_handle_video_request(struct dp_display_private *dp) { if (dp->link->sink_request & DP_TEST_LINK_VIDEO_PATTERN) { dp->panel->video_test = true; dp_link_send_test_response(dp->link); } } static int dp_display_handle_port_ststus_changed(struct dp_display_private *dp) { int rc = 0; if (dp_display_is_sink_count_zero(dp)) { drm_dbg_dp(dp->drm_dev, "sink count is zero, nothing to do\n"); if (dp->hpd_state != ST_DISCONNECTED) { dp->hpd_state = ST_DISCONNECT_PENDING; dp_add_event(dp, EV_USER_NOTIFICATION, false, 0); } } else { if (dp->hpd_state == ST_DISCONNECTED) { dp->hpd_state = ST_MAINLINK_READY; rc = dp_display_process_hpd_high(dp); if (rc) dp->hpd_state = ST_DISCONNECTED; } } return rc; } static int dp_display_handle_irq_hpd(struct dp_display_private *dp) { u32 sink_request = dp->link->sink_request; drm_dbg_dp(dp->drm_dev, "%d\n", sink_request); if (dp->hpd_state == ST_DISCONNECTED) { if (sink_request & DP_LINK_STATUS_UPDATED) { drm_dbg_dp(dp->drm_dev, "Disconnected sink_request: %d\n", sink_request); DRM_ERROR("Disconnected, no DP_LINK_STATUS_UPDATED\n"); return -EINVAL; } } dp_ctrl_handle_sink_request(dp->ctrl); if (sink_request & DP_TEST_LINK_VIDEO_PATTERN) dp_display_handle_video_request(dp); return 0; } static int dp_display_usbpd_attention_cb(struct device *dev) { int rc = 0; u32 sink_request; struct dp_display_private *dp = dev_get_dp_display_private(dev); /* check for any test request issued by sink */ rc = dp_link_process_request(dp->link); if (!rc) { sink_request = dp->link->sink_request; drm_dbg_dp(dp->drm_dev, "hpd_state=%d sink_request=%d\n", dp->hpd_state, sink_request); if (sink_request & DS_PORT_STATUS_CHANGED) rc = dp_display_handle_port_ststus_changed(dp); else rc = dp_display_handle_irq_hpd(dp); } return rc; } static int dp_hpd_plug_handle(struct dp_display_private *dp, u32 data) { struct dp_usbpd *hpd = dp->usbpd; u32 state; int ret; if (!hpd) return 0; mutex_lock(&dp->event_mutex); state = dp->hpd_state; drm_dbg_dp(dp->drm_dev, "Before, type=%d hpd_state=%d\n", dp->dp_display.connector_type, state); if (state == ST_DISPLAY_OFF || state == ST_SUSPENDED) { mutex_unlock(&dp->event_mutex); return 0; } if (state == ST_MAINLINK_READY || state == ST_CONNECTED) { mutex_unlock(&dp->event_mutex); return 0; } if (state == ST_DISCONNECT_PENDING) { /* wait until ST_DISCONNECTED */ dp_add_event(dp, EV_HPD_PLUG_INT, 0, 1); /* delay = 1 */ mutex_unlock(&dp->event_mutex); return 0; } ret = dp_display_usbpd_configure_cb(&dp->pdev->dev); if (ret) { /* link train failed */ dp->hpd_state = ST_DISCONNECTED; } else { dp->hpd_state = ST_MAINLINK_READY; } /* enable HDP irq_hpd/replug interrupt */ if (dp->dp_display.internal_hpd) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_IRQ_HPD_INT_MASK | DP_DP_HPD_REPLUG_INT_MASK, true); drm_dbg_dp(dp->drm_dev, "After, type=%d hpd_state=%d\n", dp->dp_display.connector_type, state); mutex_unlock(&dp->event_mutex); /* uevent will complete connection part */ return 0; }; static void dp_display_handle_plugged_change(struct msm_dp *dp_display, bool plugged) { struct dp_display_private *dp; dp = container_of(dp_display, struct dp_display_private, dp_display); /* notify audio subsystem only if sink supports audio */ if (dp_display->plugged_cb && dp_display->codec_dev && dp->audio_supported) dp_display->plugged_cb(dp_display->codec_dev, plugged); } static int dp_hpd_unplug_handle(struct dp_display_private *dp, u32 data) { struct dp_usbpd *hpd = dp->usbpd; u32 state; if (!hpd) return 0; mutex_lock(&dp->event_mutex); state = dp->hpd_state; drm_dbg_dp(dp->drm_dev, "Before, type=%d hpd_state=%d\n", dp->dp_display.connector_type, state); /* disable irq_hpd/replug interrupts */ if (dp->dp_display.internal_hpd) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_IRQ_HPD_INT_MASK | DP_DP_HPD_REPLUG_INT_MASK, false); /* unplugged, no more irq_hpd handle */ dp_del_event(dp, EV_IRQ_HPD_INT); if (state == ST_DISCONNECTED) { /* triggered by irq_hdp with sink_count = 0 */ if (dp->link->sink_count == 0) { dp_display_host_phy_exit(dp); } dp_display_notify_disconnect(&dp->pdev->dev); mutex_unlock(&dp->event_mutex); return 0; } else if (state == ST_DISCONNECT_PENDING) { mutex_unlock(&dp->event_mutex); return 0; } else if (state == ST_MAINLINK_READY) { dp_ctrl_off_link(dp->ctrl); dp_display_host_phy_exit(dp); dp->hpd_state = ST_DISCONNECTED; dp_display_notify_disconnect(&dp->pdev->dev); mutex_unlock(&dp->event_mutex); return 0; } /* disable HPD plug interrupts */ if (dp->dp_display.internal_hpd) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_HPD_PLUG_INT_MASK, false); /* * We don't need separate work for disconnect as * connect/attention interrupts are disabled */ dp_display_notify_disconnect(&dp->pdev->dev); if (state == ST_DISPLAY_OFF) { dp->hpd_state = ST_DISCONNECTED; } else { dp->hpd_state = ST_DISCONNECT_PENDING; } /* signal the disconnect event early to ensure proper teardown */ dp_display_handle_plugged_change(&dp->dp_display, false); /* enable HDP plug interrupt to prepare for next plugin */ if (dp->dp_display.internal_hpd) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_HPD_PLUG_INT_MASK, true); drm_dbg_dp(dp->drm_dev, "After, type=%d hpd_state=%d\n", dp->dp_display.connector_type, state); /* uevent will complete disconnection part */ mutex_unlock(&dp->event_mutex); return 0; } static int dp_irq_hpd_handle(struct dp_display_private *dp, u32 data) { u32 state; mutex_lock(&dp->event_mutex); /* irq_hpd can happen at either connected or disconnected state */ state = dp->hpd_state; drm_dbg_dp(dp->drm_dev, "Before, type=%d hpd_state=%d\n", dp->dp_display.connector_type, state); if (state == ST_DISPLAY_OFF || state == ST_SUSPENDED) { mutex_unlock(&dp->event_mutex); return 0; } if (state == ST_MAINLINK_READY || state == ST_DISCONNECT_PENDING) { /* wait until ST_CONNECTED */ dp_add_event(dp, EV_IRQ_HPD_INT, 0, 1); /* delay = 1 */ mutex_unlock(&dp->event_mutex); return 0; } dp_display_usbpd_attention_cb(&dp->pdev->dev); drm_dbg_dp(dp->drm_dev, "After, type=%d hpd_state=%d\n", dp->dp_display.connector_type, state); mutex_unlock(&dp->event_mutex); return 0; } static void dp_display_deinit_sub_modules(struct dp_display_private *dp) { dp_debug_put(dp->debug); dp_audio_put(dp->audio); dp_panel_put(dp->panel); dp_aux_put(dp->aux); } static int dp_init_sub_modules(struct dp_display_private *dp) { int rc = 0; struct device *dev = &dp->pdev->dev; struct dp_usbpd_cb *cb = &dp->usbpd_cb; struct dp_panel_in panel_in = { .dev = dev, }; /* Callback APIs used for cable status change event */ cb->configure = dp_display_usbpd_configure_cb; cb->disconnect = dp_display_usbpd_disconnect_cb; cb->attention = dp_display_usbpd_attention_cb; dp->usbpd = dp_hpd_get(dev, cb); if (IS_ERR(dp->usbpd)) { rc = PTR_ERR(dp->usbpd); DRM_ERROR("failed to initialize hpd, rc = %d\n", rc); dp->usbpd = NULL; goto error; } dp->parser = dp_parser_get(dp->pdev); if (IS_ERR(dp->parser)) { rc = PTR_ERR(dp->parser); DRM_ERROR("failed to initialize parser, rc = %d\n", rc); dp->parser = NULL; goto error; } dp->catalog = dp_catalog_get(dev, &dp->parser->io); if (IS_ERR(dp->catalog)) { rc = PTR_ERR(dp->catalog); DRM_ERROR("failed to initialize catalog, rc = %d\n", rc); dp->catalog = NULL; goto error; } dp->power = dp_power_get(dev, dp->parser); if (IS_ERR(dp->power)) { rc = PTR_ERR(dp->power); DRM_ERROR("failed to initialize power, rc = %d\n", rc); dp->power = NULL; goto error; } dp->aux = dp_aux_get(dev, dp->catalog, dp->dp_display.is_edp); if (IS_ERR(dp->aux)) { rc = PTR_ERR(dp->aux); DRM_ERROR("failed to initialize aux, rc = %d\n", rc); dp->aux = NULL; goto error; } dp->link = dp_link_get(dev, dp->aux); if (IS_ERR(dp->link)) { rc = PTR_ERR(dp->link); DRM_ERROR("failed to initialize link, rc = %d\n", rc); dp->link = NULL; goto error_link; } panel_in.aux = dp->aux; panel_in.catalog = dp->catalog; panel_in.link = dp->link; dp->panel = dp_panel_get(&panel_in); if (IS_ERR(dp->panel)) { rc = PTR_ERR(dp->panel); DRM_ERROR("failed to initialize panel, rc = %d\n", rc); dp->panel = NULL; goto error_link; } dp->ctrl = dp_ctrl_get(dev, dp->link, dp->panel, dp->aux, dp->power, dp->catalog, dp->parser); if (IS_ERR(dp->ctrl)) { rc = PTR_ERR(dp->ctrl); DRM_ERROR("failed to initialize ctrl, rc = %d\n", rc); dp->ctrl = NULL; goto error_ctrl; } dp->audio = dp_audio_get(dp->pdev, dp->panel, dp->catalog); if (IS_ERR(dp->audio)) { rc = PTR_ERR(dp->audio); pr_err("failed to initialize audio, rc = %d\n", rc); dp->audio = NULL; goto error_ctrl; } /* populate wide_bus_en to differernt layers */ dp->ctrl->wide_bus_en = dp->wide_bus_en; dp->catalog->wide_bus_en = dp->wide_bus_en; return rc; error_ctrl: dp_panel_put(dp->panel); error_link: dp_aux_put(dp->aux); error: return rc; } static int dp_display_set_mode(struct msm_dp *dp_display, struct dp_display_mode *mode) { struct dp_display_private *dp; dp = container_of(dp_display, struct dp_display_private, dp_display); drm_mode_copy(&dp->panel->dp_mode.drm_mode, &mode->drm_mode); dp->panel->dp_mode.bpp = mode->bpp; dp->panel->dp_mode.capabilities = mode->capabilities; dp_panel_init_panel_info(dp->panel); return 0; } static int dp_display_enable(struct dp_display_private *dp, bool force_link_train) { int rc = 0; struct msm_dp *dp_display = &dp->dp_display; drm_dbg_dp(dp->drm_dev, "sink_count=%d\n", dp->link->sink_count); if (dp_display->power_on) { drm_dbg_dp(dp->drm_dev, "Link already setup, return\n"); return 0; } rc = dp_ctrl_on_stream(dp->ctrl, force_link_train); if (!rc) dp_display->power_on = true; return rc; } static int dp_display_post_enable(struct msm_dp *dp_display) { struct dp_display_private *dp; u32 rate; dp = container_of(dp_display, struct dp_display_private, dp_display); rate = dp->link->link_params.rate; if (dp->audio_supported) { dp->audio->bw_code = drm_dp_link_rate_to_bw_code(rate); dp->audio->lane_count = dp->link->link_params.num_lanes; } /* signal the connect event late to synchronize video and display */ dp_display_handle_plugged_change(dp_display, true); return 0; } static int dp_display_disable(struct dp_display_private *dp) { struct msm_dp *dp_display = &dp->dp_display; if (!dp_display->power_on) return 0; /* wait only if audio was enabled */ if (dp_display->audio_enabled) { /* signal the disconnect event */ dp_display_handle_plugged_change(dp_display, false); if (!wait_for_completion_timeout(&dp->audio_comp, HZ * 5)) DRM_ERROR("audio comp timeout\n"); } dp_display->audio_enabled = false; if (dp->link->sink_count == 0) { /* * irq_hpd with sink_count = 0 * hdmi unplugged out of dongle */ dp_ctrl_off_link_stream(dp->ctrl); } else { /* * unplugged interrupt * dongle unplugged out of DUT */ dp_ctrl_off(dp->ctrl); dp_display_host_phy_exit(dp); } dp_display->power_on = false; drm_dbg_dp(dp->drm_dev, "sink count: %d\n", dp->link->sink_count); return 0; } int dp_display_set_plugged_cb(struct msm_dp *dp_display, hdmi_codec_plugged_cb fn, struct device *codec_dev) { bool plugged; dp_display->plugged_cb = fn; dp_display->codec_dev = codec_dev; plugged = dp_display->is_connected; dp_display_handle_plugged_change(dp_display, plugged); return 0; } /** * dp_bridge_mode_valid - callback to determine if specified mode is valid * @bridge: Pointer to drm bridge structure * @info: display info * @mode: Pointer to drm mode structure * Returns: Validity status for specified mode */ enum drm_mode_status dp_bridge_mode_valid(struct drm_bridge *bridge, const struct drm_display_info *info, const struct drm_display_mode *mode) { const u32 num_components = 3, default_bpp = 24; struct dp_display_private *dp_display; struct dp_link_info *link_info; u32 mode_rate_khz = 0, supported_rate_khz = 0, mode_bpp = 0; struct msm_dp *dp; int mode_pclk_khz = mode->clock; dp = to_dp_bridge(bridge)->dp_display; if (!dp || !mode_pclk_khz || !dp->connector) { DRM_ERROR("invalid params\n"); return -EINVAL; } /* * The eDP controller currently does not have a reliable way of * enabling panel power to read sink capabilities. So, we rely * on the panel driver to populate only supported modes for now. */ if (dp->is_edp) return MODE_OK; if (mode->clock > DP_MAX_PIXEL_CLK_KHZ) return MODE_CLOCK_HIGH; dp_display = container_of(dp, struct dp_display_private, dp_display); link_info = &dp_display->panel->link_info; mode_bpp = dp->connector->display_info.bpc * num_components; if (!mode_bpp) mode_bpp = default_bpp; mode_bpp = dp_panel_get_mode_bpp(dp_display->panel, mode_bpp, mode_pclk_khz); mode_rate_khz = mode_pclk_khz * mode_bpp; supported_rate_khz = link_info->num_lanes * link_info->rate * 8; if (mode_rate_khz > supported_rate_khz) return MODE_BAD; return MODE_OK; } int dp_display_get_modes(struct msm_dp *dp) { struct dp_display_private *dp_display; if (!dp) { DRM_ERROR("invalid params\n"); return 0; } dp_display = container_of(dp, struct dp_display_private, dp_display); return dp_panel_get_modes(dp_display->panel, dp->connector); } bool dp_display_check_video_test(struct msm_dp *dp) { struct dp_display_private *dp_display; dp_display = container_of(dp, struct dp_display_private, dp_display); return dp_display->panel->video_test; } int dp_display_get_test_bpp(struct msm_dp *dp) { struct dp_display_private *dp_display; if (!dp) { DRM_ERROR("invalid params\n"); return 0; } dp_display = container_of(dp, struct dp_display_private, dp_display); return dp_link_bit_depth_to_bpp( dp_display->link->test_video.test_bit_depth); } void msm_dp_snapshot(struct msm_disp_state *disp_state, struct msm_dp *dp) { struct dp_display_private *dp_display; dp_display = container_of(dp, struct dp_display_private, dp_display); /* * if we are reading registers we need the link clocks to be on * however till DP cable is connected this will not happen as we * do not know the resolution to power up with. Hence check the * power_on status before dumping DP registers to avoid crash due * to unclocked access */ mutex_lock(&dp_display->event_mutex); if (!dp->power_on) { mutex_unlock(&dp_display->event_mutex); return; } dp_catalog_snapshot(dp_display->catalog, disp_state); mutex_unlock(&dp_display->event_mutex); } static void dp_display_config_hpd(struct dp_display_private *dp) { dp_display_host_init(dp); dp_catalog_ctrl_hpd_config(dp->catalog); /* Enable plug and unplug interrupts only if requested */ if (dp->dp_display.internal_hpd) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_HPD_PLUG_INT_MASK | DP_DP_HPD_UNPLUG_INT_MASK, true); /* Enable interrupt first time * we are leaving dp clocks on during disconnect * and never disable interrupt */ enable_irq(dp->irq); } static int hpd_event_thread(void *data) { struct dp_display_private *dp_priv; unsigned long flag; struct dp_event *todo; int timeout_mode = 0; dp_priv = (struct dp_display_private *)data; while (1) { if (timeout_mode) { wait_event_timeout(dp_priv->event_q, (dp_priv->event_pndx == dp_priv->event_gndx) || kthread_should_stop(), EVENT_TIMEOUT); } else { wait_event_interruptible(dp_priv->event_q, (dp_priv->event_pndx != dp_priv->event_gndx) || kthread_should_stop()); } if (kthread_should_stop()) break; spin_lock_irqsave(&dp_priv->event_lock, flag); todo = &dp_priv->event_list[dp_priv->event_gndx]; if (todo->delay) { struct dp_event *todo_next; dp_priv->event_gndx++; dp_priv->event_gndx %= DP_EVENT_Q_MAX; /* re enter delay event into q */ todo_next = &dp_priv->event_list[dp_priv->event_pndx++]; dp_priv->event_pndx %= DP_EVENT_Q_MAX; todo_next->event_id = todo->event_id; todo_next->data = todo->data; todo_next->delay = todo->delay - 1; /* clean up older event */ todo->event_id = EV_NO_EVENT; todo->delay = 0; /* switch to timeout mode */ timeout_mode = 1; spin_unlock_irqrestore(&dp_priv->event_lock, flag); continue; } /* timeout with no events in q */ if (dp_priv->event_pndx == dp_priv->event_gndx) { spin_unlock_irqrestore(&dp_priv->event_lock, flag); continue; } dp_priv->event_gndx++; dp_priv->event_gndx %= DP_EVENT_Q_MAX; timeout_mode = 0; spin_unlock_irqrestore(&dp_priv->event_lock, flag); switch (todo->event_id) { case EV_HPD_INIT_SETUP: dp_display_config_hpd(dp_priv); break; case EV_HPD_PLUG_INT: dp_hpd_plug_handle(dp_priv, todo->data); break; case EV_HPD_UNPLUG_INT: dp_hpd_unplug_handle(dp_priv, todo->data); break; case EV_IRQ_HPD_INT: dp_irq_hpd_handle(dp_priv, todo->data); break; case EV_USER_NOTIFICATION: dp_display_send_hpd_notification(dp_priv, todo->data); break; default: break; } } return 0; } static int dp_hpd_event_thread_start(struct dp_display_private *dp_priv) { /* set event q to empty */ dp_priv->event_gndx = 0; dp_priv->event_pndx = 0; dp_priv->ev_tsk = kthread_run(hpd_event_thread, dp_priv, "dp_hpd_handler"); if (IS_ERR(dp_priv->ev_tsk)) return PTR_ERR(dp_priv->ev_tsk); return 0; } static irqreturn_t dp_display_irq_handler(int irq, void *dev_id) { struct dp_display_private *dp = dev_id; irqreturn_t ret = IRQ_HANDLED; u32 hpd_isr_status; if (!dp) { DRM_ERROR("invalid data\n"); return IRQ_NONE; } hpd_isr_status = dp_catalog_hpd_get_intr_status(dp->catalog); if (hpd_isr_status & 0x0F) { drm_dbg_dp(dp->drm_dev, "type=%d isr=0x%x\n", dp->dp_display.connector_type, hpd_isr_status); /* hpd related interrupts */ if (hpd_isr_status & DP_DP_HPD_PLUG_INT_MASK) dp_add_event(dp, EV_HPD_PLUG_INT, 0, 0); if (hpd_isr_status & DP_DP_IRQ_HPD_INT_MASK) { dp_add_event(dp, EV_IRQ_HPD_INT, 0, 0); } if (hpd_isr_status & DP_DP_HPD_REPLUG_INT_MASK) { dp_add_event(dp, EV_HPD_UNPLUG_INT, 0, 0); dp_add_event(dp, EV_HPD_PLUG_INT, 0, 3); } if (hpd_isr_status & DP_DP_HPD_UNPLUG_INT_MASK) dp_add_event(dp, EV_HPD_UNPLUG_INT, 0, 0); } /* DP controller isr */ dp_ctrl_isr(dp->ctrl); /* DP aux isr */ dp_aux_isr(dp->aux); return ret; } int dp_display_request_irq(struct msm_dp *dp_display) { int rc = 0; struct dp_display_private *dp; if (!dp_display) { DRM_ERROR("invalid input\n"); return -EINVAL; } dp = container_of(dp_display, struct dp_display_private, dp_display); dp->irq = irq_of_parse_and_map(dp->pdev->dev.of_node, 0); if (!dp->irq) { DRM_ERROR("failed to get irq\n"); return -EINVAL; } rc = devm_request_irq(dp_display->drm_dev->dev, dp->irq, dp_display_irq_handler, IRQF_TRIGGER_HIGH, "dp_display_isr", dp); if (rc < 0) { DRM_ERROR("failed to request IRQ%u: %d\n", dp->irq, rc); return rc; } disable_irq(dp->irq); return 0; } static const struct msm_dp_desc *dp_display_get_desc(struct platform_device *pdev) { const struct msm_dp_desc *descs = of_device_get_match_data(&pdev->dev); struct resource *res; int i; res = platform_get_resource(pdev, IORESOURCE_MEM, 0); if (!res) return NULL; for (i = 0; i < descs[i].io_start; i++) { if (descs[i].io_start == res->start) return &descs[i]; } dev_err(&pdev->dev, "unknown displayport instance\n"); return NULL; } static int dp_display_probe(struct platform_device *pdev) { int rc = 0; struct dp_display_private *dp; const struct msm_dp_desc *desc; if (!pdev || !pdev->dev.of_node) { DRM_ERROR("pdev not found\n"); return -ENODEV; } dp = devm_kzalloc(&pdev->dev, sizeof(*dp), GFP_KERNEL); if (!dp) return -ENOMEM; desc = dp_display_get_desc(pdev); if (!desc) return -EINVAL; dp->pdev = pdev; dp->name = "drm_dp"; dp->id = desc->id; dp->dp_display.connector_type = desc->connector_type; dp->wide_bus_en = desc->wide_bus_en; dp->dp_display.is_edp = (dp->dp_display.connector_type == DRM_MODE_CONNECTOR_eDP); rc = dp_init_sub_modules(dp); if (rc) { DRM_ERROR("init sub module failed\n"); return -EPROBE_DEFER; } /* setup event q */ mutex_init(&dp->event_mutex); init_waitqueue_head(&dp->event_q); spin_lock_init(&dp->event_lock); /* Store DP audio handle inside DP display */ dp->dp_display.dp_audio = dp->audio; init_completion(&dp->audio_comp); platform_set_drvdata(pdev, &dp->dp_display); rc = component_add(&pdev->dev, &dp_display_comp_ops); if (rc) { DRM_ERROR("component add failed, rc=%d\n", rc); dp_display_deinit_sub_modules(dp); } return rc; } static int dp_display_remove(struct platform_device *pdev) { struct dp_display_private *dp = dev_get_dp_display_private(&pdev->dev); dp_display_deinit_sub_modules(dp); component_del(&pdev->dev, &dp_display_comp_ops); platform_set_drvdata(pdev, NULL); return 0; } static int dp_pm_resume(struct device *dev) { struct platform_device *pdev = to_platform_device(dev); struct msm_dp *dp_display = platform_get_drvdata(pdev); struct dp_display_private *dp; int sink_count = 0; dp = container_of(dp_display, struct dp_display_private, dp_display); mutex_lock(&dp->event_mutex); drm_dbg_dp(dp->drm_dev, "Before, type=%d core_inited=%d phy_inited=%d power_on=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized, dp_display->power_on); /* start from disconnected state */ dp->hpd_state = ST_DISCONNECTED; /* turn on dp ctrl/phy */ dp_display_host_init(dp); dp_catalog_ctrl_hpd_config(dp->catalog); if (dp->dp_display.internal_hpd) dp_catalog_hpd_config_intr(dp->catalog, DP_DP_HPD_PLUG_INT_MASK | DP_DP_HPD_UNPLUG_INT_MASK, true); if (dp_catalog_link_is_connected(dp->catalog)) { /* * set sink to normal operation mode -- D0 * before dpcd read */ dp_display_host_phy_init(dp); dp_link_psm_config(dp->link, &dp->panel->link_info, false); sink_count = drm_dp_read_sink_count(dp->aux); if (sink_count < 0) sink_count = 0; dp_display_host_phy_exit(dp); } dp->link->sink_count = sink_count; /* * can not declared display is connected unless * HDMI cable is plugged in and sink_count of * dongle become 1 * also only signal audio when disconnected */ if (dp->link->sink_count) { dp->dp_display.is_connected = true; } else { dp->dp_display.is_connected = false; dp_display_handle_plugged_change(dp_display, false); } drm_dbg_dp(dp->drm_dev, "After, type=%d sink=%d conn=%d core_init=%d phy_init=%d power=%d\n", dp->dp_display.connector_type, dp->link->sink_count, dp->dp_display.is_connected, dp->core_initialized, dp->phy_initialized, dp_display->power_on); mutex_unlock(&dp->event_mutex); return 0; } static int dp_pm_suspend(struct device *dev) { struct platform_device *pdev = to_platform_device(dev); struct msm_dp *dp_display = platform_get_drvdata(pdev); struct dp_display_private *dp; dp = container_of(dp_display, struct dp_display_private, dp_display); mutex_lock(&dp->event_mutex); drm_dbg_dp(dp->drm_dev, "Before, type=%d core_inited=%d phy_inited=%d power_on=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized, dp_display->power_on); /* mainlink enabled */ if (dp_power_clk_status(dp->power, DP_CTRL_PM)) dp_ctrl_off_link_stream(dp->ctrl); dp_display_host_phy_exit(dp); /* host_init will be called at pm_resume */ dp_display_host_deinit(dp); dp->hpd_state = ST_SUSPENDED; drm_dbg_dp(dp->drm_dev, "After, type=%d core_inited=%d phy_inited=%d power_on=%d\n", dp->dp_display.connector_type, dp->core_initialized, dp->phy_initialized, dp_display->power_on); mutex_unlock(&dp->event_mutex); return 0; } static const struct dev_pm_ops dp_pm_ops = { .suspend = dp_pm_suspend, .resume = dp_pm_resume, }; static struct platform_driver dp_display_driver = { .probe = dp_display_probe, .remove = dp_display_remove, .driver = { .name = "msm-dp-display", .of_match_table = dp_dt_match, .suppress_bind_attrs = true, .pm = &dp_pm_ops, }, }; int __init msm_dp_register(void) { int ret; ret = platform_driver_register(&dp_display_driver); if (ret) DRM_ERROR("Dp display driver register failed"); return ret; } void __exit msm_dp_unregister(void) { platform_driver_unregister(&dp_display_driver); } void msm_dp_irq_postinstall(struct msm_dp *dp_display) { struct dp_display_private *dp; if (!dp_display) return; dp = container_of(dp_display, struct dp_display_private, dp_display); if (!dp_display->is_edp) dp_add_event(dp, EV_HPD_INIT_SETUP, 0, 0); } bool msm_dp_wide_bus_available(const struct msm_dp *dp_display) { struct dp_display_private *dp; dp = container_of(dp_display, struct dp_display_private, dp_display); return dp->wide_bus_en; } void msm_dp_debugfs_init(struct msm_dp *dp_display, struct drm_minor *minor) { struct dp_display_private *dp; struct device *dev; int rc; dp = container_of(dp_display, struct dp_display_private, dp_display); dev = &dp->pdev->dev; dp->debug = dp_debug_get(dev, dp->panel, dp->usbpd, dp->link, dp->dp_display.connector, minor); if (IS_ERR(dp->debug)) { rc = PTR_ERR(dp->debug); DRM_ERROR("failed to initialize debug, rc = %d\n", rc); dp->debug = NULL; } } static void of_dp_aux_depopulate_bus_void(void *data) { of_dp_aux_depopulate_bus(data); } static int dp_display_get_next_bridge(struct msm_dp *dp) { int rc; struct dp_display_private *dp_priv; struct device_node *aux_bus; struct device *dev; dp_priv = container_of(dp, struct dp_display_private, dp_display); dev = &dp_priv->pdev->dev; aux_bus = of_get_child_by_name(dev->of_node, "aux-bus"); if (aux_bus && dp->is_edp) { dp_display_host_init(dp_priv); dp_catalog_ctrl_hpd_config(dp_priv->catalog); dp_display_host_phy_init(dp_priv); enable_irq(dp_priv->irq); /* * The code below assumes that the panel will finish probing * by the time devm_of_dp_aux_populate_ep_devices() returns. * This isn't a great assumption since it will fail if the * panel driver is probed asynchronously but is the best we * can do without a bigger driver reorganization. */ rc = of_dp_aux_populate_bus(dp_priv->aux, NULL); of_node_put(aux_bus); if (rc) goto error; rc = devm_add_action_or_reset(dp->drm_dev->dev, of_dp_aux_depopulate_bus_void, dp_priv->aux); if (rc) goto error; } else if (dp->is_edp) { DRM_ERROR("eDP aux_bus not found\n"); return -ENODEV; } /* * External bridges are mandatory for eDP interfaces: one has to * provide at least an eDP panel (which gets wrapped into panel-bridge). * * For DisplayPort interfaces external bridges are optional, so * silently ignore an error if one is not present (-ENODEV). */ rc = devm_dp_parser_find_next_bridge(dp->drm_dev->dev, dp_priv->parser); if (!dp->is_edp && rc == -ENODEV) return 0; if (!rc) { dp->next_bridge = dp_priv->parser->next_bridge; return 0; } error: if (dp->is_edp) { disable_irq(dp_priv->irq); dp_display_host_phy_exit(dp_priv); dp_display_host_deinit(dp_priv); } return rc; } int msm_dp_modeset_init(struct msm_dp *dp_display, struct drm_device *dev, struct drm_encoder *encoder) { struct msm_drm_private *priv = dev->dev_private; struct dp_display_private *dp_priv; int ret; dp_display->drm_dev = dev; dp_priv = container_of(dp_display, struct dp_display_private, dp_display); ret = dp_display_request_irq(dp_display); if (ret) { DRM_ERROR("request_irq failed, ret=%d\n", ret); return ret; } ret = dp_display_get_next_bridge(dp_display); if (ret) return ret; dp_display->bridge = dp_bridge_init(dp_display, dev, encoder); if (IS_ERR(dp_display->bridge)) { ret = PTR_ERR(dp_display->bridge); DRM_DEV_ERROR(dev->dev, "failed to create dp bridge: %d\n", ret); dp_display->bridge = NULL; return ret; } priv->bridges[priv->num_bridges++] = dp_display->bridge; dp_display->connector = dp_drm_connector_init(dp_display, encoder); if (IS_ERR(dp_display->connector)) { ret = PTR_ERR(dp_display->connector); DRM_DEV_ERROR(dev->dev, "failed to create dp connector: %d\n", ret); dp_display->connector = NULL; return ret; } dp_priv->panel->connector = dp_display->connector; return 0; } void dp_bridge_enable(struct drm_bridge *drm_bridge) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(drm_bridge); struct msm_dp *dp = dp_bridge->dp_display; int rc = 0; struct dp_display_private *dp_display; u32 state; bool force_link_train = false; dp_display = container_of(dp, struct dp_display_private, dp_display); if (!dp_display->dp_mode.drm_mode.clock) { DRM_ERROR("invalid params\n"); return; } if (dp->is_edp) dp_hpd_plug_handle(dp_display, 0); mutex_lock(&dp_display->event_mutex); state = dp_display->hpd_state; if (state != ST_DISPLAY_OFF && state != ST_MAINLINK_READY) { mutex_unlock(&dp_display->event_mutex); return; } rc = dp_display_set_mode(dp, &dp_display->dp_mode); if (rc) { DRM_ERROR("Failed to perform a mode set, rc=%d\n", rc); mutex_unlock(&dp_display->event_mutex); return; } state = dp_display->hpd_state; if (state == ST_DISPLAY_OFF) { dp_display_host_phy_init(dp_display); force_link_train = true; } dp_display_enable(dp_display, force_link_train); rc = dp_display_post_enable(dp); if (rc) { DRM_ERROR("DP display post enable failed, rc=%d\n", rc); dp_display_disable(dp_display); } /* completed connection */ dp_display->hpd_state = ST_CONNECTED; drm_dbg_dp(dp->drm_dev, "type=%d Done\n", dp->connector_type); mutex_unlock(&dp_display->event_mutex); } void dp_bridge_disable(struct drm_bridge *drm_bridge) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(drm_bridge); struct msm_dp *dp = dp_bridge->dp_display; struct dp_display_private *dp_display; dp_display = container_of(dp, struct dp_display_private, dp_display); dp_ctrl_push_idle(dp_display->ctrl); } void dp_bridge_post_disable(struct drm_bridge *drm_bridge) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(drm_bridge); struct msm_dp *dp = dp_bridge->dp_display; u32 state; struct dp_display_private *dp_display; dp_display = container_of(dp, struct dp_display_private, dp_display); if (dp->is_edp) dp_hpd_unplug_handle(dp_display, 0); mutex_lock(&dp_display->event_mutex); state = dp_display->hpd_state; if (state != ST_DISCONNECT_PENDING && state != ST_CONNECTED) { mutex_unlock(&dp_display->event_mutex); return; } dp_display_disable(dp_display); state = dp_display->hpd_state; if (state == ST_DISCONNECT_PENDING) { /* completed disconnection */ dp_display->hpd_state = ST_DISCONNECTED; } else { dp_display->hpd_state = ST_DISPLAY_OFF; } drm_dbg_dp(dp->drm_dev, "type=%d Done\n", dp->connector_type); mutex_unlock(&dp_display->event_mutex); } void dp_bridge_mode_set(struct drm_bridge *drm_bridge, const struct drm_display_mode *mode, const struct drm_display_mode *adjusted_mode) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(drm_bridge); struct msm_dp *dp = dp_bridge->dp_display; struct dp_display_private *dp_display; dp_display = container_of(dp, struct dp_display_private, dp_display); memset(&dp_display->dp_mode, 0x0, sizeof(struct dp_display_mode)); if (dp_display_check_video_test(dp)) dp_display->dp_mode.bpp = dp_display_get_test_bpp(dp); else /* Default num_components per pixel = 3 */ dp_display->dp_mode.bpp = dp->connector->display_info.bpc * 3; if (!dp_display->dp_mode.bpp) dp_display->dp_mode.bpp = 24; /* Default bpp */ drm_mode_copy(&dp_display->dp_mode.drm_mode, adjusted_mode); dp_display->dp_mode.v_active_low = !!(dp_display->dp_mode.drm_mode.flags & DRM_MODE_FLAG_NVSYNC); dp_display->dp_mode.h_active_low = !!(dp_display->dp_mode.drm_mode.flags & DRM_MODE_FLAG_NHSYNC); } void dp_bridge_hpd_enable(struct drm_bridge *bridge) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(bridge); struct msm_dp *dp_display = dp_bridge->dp_display; dp_display->internal_hpd = true; } void dp_bridge_hpd_disable(struct drm_bridge *bridge) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(bridge); struct msm_dp *dp_display = dp_bridge->dp_display; dp_display->internal_hpd = false; } void dp_bridge_hpd_notify(struct drm_bridge *bridge, enum drm_connector_status status) { struct msm_dp_bridge *dp_bridge = to_dp_bridge(bridge); struct msm_dp *dp_display = dp_bridge->dp_display; struct dp_display_private *dp = container_of(dp_display, struct dp_display_private, dp_display); /* Without next_bridge interrupts are handled by the DP core directly */ if (dp_display->internal_hpd) return; if (!dp->core_initialized) { drm_dbg_dp(dp->drm_dev, "not initialized\n"); return; } if (!dp_display->is_connected && status == connector_status_connected) dp_add_event(dp, EV_HPD_PLUG_INT, 0, 0); else if (dp_display->is_connected && status == connector_status_disconnected) dp_add_event(dp, EV_HPD_UNPLUG_INT, 0, 0); }