/* * Copyright (c) 2014-2018, The Linux Foundation. All rights reserved. * Not a Contribution. * * Copyright 2015 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "hwc_buffer_allocator.h" #include "hwc_buffer_sync_handler.h" #include "hwc_session.h" #include "hwc_debugger.h" #include "hwc_display_primary.h" #include "hwc_display_virtual.h" #include "hwc_display_external_test.h" #define __CLASS__ "HWCSession" #define HWC_UEVENT_SWITCH_HDMI "change@/devices/virtual/switch/hdmi" #define HWC_UEVENT_GRAPHICS_FB0 "change@/devices/virtual/graphics/fb0" #define HWC_UEVENT_DRM_EXT_HOTPLUG "mdss_mdp/drm/card" #define MAX_BRIGHTNESS 255 #define BRIGHTNESS_FILE1 "/sys/class/leds/lcd-backlight/brightness" #define BRIGHTNESS_FILE2 "/sys/class/backlight/panel0-backlight/brightness" static sdm::HWCSession::HWCModuleMethods g_hwc_module_methods; hwc_module_t HAL_MODULE_INFO_SYM = { .common = { .tag = HARDWARE_MODULE_TAG, .version_major = 3, .version_minor = 0, .id = HWC_HARDWARE_MODULE_ID, .name = "QTI Hardware Composer Module", .author = "CodeAurora Forum", .methods = &g_hwc_module_methods, .dso = 0, .reserved = {0}, } }; namespace sdm { static HWCUEvent g_hwc_uevent_; Locker HWCSession::locker_[HWC_NUM_DISPLAY_TYPES]; static const int kSolidFillDelay = 100 * 1000; void HWCUEvent::UEventThread(HWCUEvent *hwc_uevent) { const char *uevent_thread_name = "HWC_UeventThread"; prctl(PR_SET_NAME, uevent_thread_name, 0, 0, 0); setpriority(PRIO_PROCESS, 0, HAL_PRIORITY_URGENT_DISPLAY); int status = uevent_init(); if (!status) { std::unique_lock caller_lock(hwc_uevent->mutex_); hwc_uevent->caller_cv_.notify_one(); DLOGE("Failed to init uevent with err %d", status); return; } { // Signal caller thread that worker thread is ready to listen to events. std::unique_lock caller_lock(hwc_uevent->mutex_); hwc_uevent->init_done_ = true; hwc_uevent->caller_cv_.notify_one(); } while (1) { char uevent_data[PAGE_SIZE] = {}; // keep last 2 zeroes to ensure double 0 termination int length = uevent_next_event(uevent_data, INT32(sizeof(uevent_data)) - 2); // scope of lock to this block only, so that caller is free to set event handler to nullptr; { std::lock_guard guard(hwc_uevent->mutex_); if (hwc_uevent->uevent_listener_) { hwc_uevent->uevent_listener_->UEventHandler(uevent_data, length); } else { DLOGW("UEvent dropped. No uevent listener."); } } } } HWCUEvent::HWCUEvent() { std::unique_lock caller_lock(mutex_); std::thread thread(HWCUEvent::UEventThread, this); thread.detach(); caller_cv_.wait(caller_lock); } void HWCUEvent::Register(HWCUEventListener *uevent_listener) { DLOGI("Set uevent listener = %p", uevent_listener); std::lock_guard obj(mutex_); uevent_listener_ = uevent_listener; } HWCSession::HWCSession(const hw_module_t *module) { hwc2_device_t::common.tag = HARDWARE_DEVICE_TAG; hwc2_device_t::common.version = HWC_DEVICE_API_VERSION_2_0; hwc2_device_t::common.module = const_cast(module); hwc2_device_t::common.close = Close; hwc2_device_t::getCapabilities = GetCapabilities; hwc2_device_t::getFunction = GetFunction; } int HWCSession::Init() { SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); int status = -EINVAL; const char *qservice_name = "display.qservice"; if (!g_hwc_uevent_.InitDone()) { return status; } // Start QService and connect to it. qService::QService::init(); android::sp iqservice = android::interface_cast( android::defaultServiceManager()->getService(android::String16(qservice_name))); if (iqservice.get()) { iqservice->connect(android::sp(this)); qservice_ = reinterpret_cast(iqservice.get()); } else { DLOGE("Failed to acquire %s", qservice_name); return -EINVAL; } StartServices(); g_hwc_uevent_.Register(this); auto error = CoreInterface::CreateCore(&buffer_allocator_, &buffer_sync_handler_, &socket_handler_, &core_intf_); // If HDMI display is primary display, defer display creation until hotplug event is received. HWDisplayInterfaceInfo hw_disp_info = {}; error = core_intf_->GetFirstDisplayInterfaceType(&hw_disp_info); if (error != kErrorNone) { g_hwc_uevent_.Register(nullptr); CoreInterface::DestroyCore(); DLOGE("Primary display type not recognized. Error = %d", error); return -EINVAL; } if (hw_disp_info.type == kHDMI) { status = 0; hdmi_is_primary_ = true; // Create display if it is connected, else wait for hotplug connect event. if (hw_disp_info.is_connected) { status = CreateExternalDisplay(HWC_DISPLAY_PRIMARY, 0, 0, false); } } else { // Create and power on primary display status = HWCDisplayPrimary::Create(core_intf_, &buffer_allocator_, &callbacks_, qservice_, &hwc_display_[HWC_DISPLAY_PRIMARY]); color_mgr_ = HWCColorManager::CreateColorManager(&buffer_allocator_); if (!color_mgr_) { DLOGW("Failed to load HWCColorManager."); } } if (status) { g_hwc_uevent_.Register(nullptr); CoreInterface::DestroyCore(); return status; } is_composer_up_ = true; struct rlimit fd_limit = {}; getrlimit(RLIMIT_NOFILE, &fd_limit); fd_limit.rlim_cur = fd_limit.rlim_cur * 2; if (fd_limit.rlim_cur < fd_limit.rlim_max) { auto err = setrlimit(RLIMIT_NOFILE, &fd_limit); if (err) { DLOGW("Unable to increase fd limit - err:%d, %s", errno, strerror(errno)); } } char const *brightness_file; if (access(BRIGHTNESS_FILE1, F_OK) == 0) { brightness_file = BRIGHTNESS_FILE1; } else { brightness_file = BRIGHTNESS_FILE2; } brightness_fd_ = open(brightness_file, O_WRONLY); if (brightness_fd_ == -1) { DLOGW("Unable to open brightness file: [%d] %s", errno, strerror(errno)); } return 0; } int HWCSession::Deinit() { Locker::SequenceCancelScopeLock lock_v(locker_[HWC_DISPLAY_VIRTUAL]); Locker::SequenceCancelScopeLock lock_e(locker_[HWC_DISPLAY_EXTERNAL]); Locker::SequenceCancelScopeLock lock_p(locker_[HWC_DISPLAY_PRIMARY]); HWCDisplay *primary_display = hwc_display_[HWC_DISPLAY_PRIMARY]; if (primary_display) { if (hdmi_is_primary_) { HWCDisplayExternal::Destroy(primary_display); } else { HWCDisplayPrimary::Destroy(primary_display); } } hwc_display_[HWC_DISPLAY_PRIMARY] = nullptr; if (color_mgr_) { color_mgr_->DestroyColorManager(); } g_hwc_uevent_.Register(nullptr); DisplayError error = CoreInterface::DestroyCore(); if (error != kErrorNone) { DLOGE("Display core de-initialization failed. Error = %d", error); } close(brightness_fd_); return 0; } int HWCSession::Open(const hw_module_t *module, const char *name, hw_device_t **device) { if (!module || !name || !device) { DLOGE("Invalid parameters."); return -EINVAL; } if (!strcmp(name, HWC_HARDWARE_COMPOSER)) { HWCSession *hwc_session = new HWCSession(module); if (!hwc_session) { return -ENOMEM; } int status = hwc_session->Init(); if (status != 0) { delete hwc_session; hwc_session = NULL; return status; } hwc2_device_t *composer_device = hwc_session; *device = reinterpret_cast(composer_device); } return 0; } int HWCSession::Close(hw_device_t *device) { if (!device) { return -EINVAL; } hwc2_device_t *composer_device = reinterpret_cast(device); HWCSession *hwc_session = static_cast(composer_device); hwc_session->Deinit(); return 0; } void HWCSession::GetCapabilities(struct hwc2_device *device, uint32_t *outCount, int32_t *outCapabilities) { if (!outCount) { return; } int value = 0; bool disable_skip_validate = false; if (Debug::Get()->GetProperty(DISABLE_SKIP_VALIDATE_PROP, &value) == kErrorNone) { disable_skip_validate = (value == 1); } uint32_t count = 1 + (disable_skip_validate ? 0 : 1); if (outCapabilities != nullptr && (*outCount >= count)) { outCapabilities[0] = HWC2_CAPABILITY_SKIP_CLIENT_COLOR_TRANSFORM; if (!disable_skip_validate) { outCapabilities[1] = HWC2_CAPABILITY_SKIP_VALIDATE; } } *outCount = count; } int32_t HWCSession::GetDisplayBrightnessSupport(hwc2_device_t *device, hwc2_display_t display, bool *out_support) { HWCSession *hwc_session = static_cast(device); *out_support = display == HWC_DISPLAY_PRIMARY && hwc_session->brightness_fd_ != -1; return INT32(HWC2::Error::None); } template static hwc2_function_pointer_t AsFP(T function) { static_assert(std::is_same::value, "Incompatible function pointer"); return reinterpret_cast(function); } // HWC2 functions returned in GetFunction // Defined in the same order as in the HWC2 header int32_t HWCSession::AcceptDisplayChanges(hwc2_device_t *device, hwc2_display_t display) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::AcceptDisplayChanges); } int32_t HWCSession::CreateLayer(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t *out_layer_id) { if (!out_layer_id) { return HWC2_ERROR_BAD_PARAMETER; } return CallDisplayFunction(device, display, &HWCDisplay::CreateLayer, out_layer_id); } int32_t HWCSession::CreateVirtualDisplay(hwc2_device_t *device, uint32_t width, uint32_t height, int32_t *format, hwc2_display_t *out_display_id) { // TODO(user): Handle concurrency with HDMI if (!device) { return HWC2_ERROR_BAD_DISPLAY; } if (!out_display_id || !width || !height || !format) { return HWC2_ERROR_BAD_PARAMETER; } HWCSession *hwc_session = static_cast(device); auto status = hwc_session->CreateVirtualDisplayObject(width, height, format); if (status == HWC2::Error::None) { *out_display_id = HWC_DISPLAY_VIRTUAL; DLOGI("Created virtual display id:% " PRIu64 " with res: %dx%d", *out_display_id, width, height); } else { DLOGE("Failed to create virtual display: %s", to_string(status).c_str()); } return INT32(status); } int32_t HWCSession::DestroyLayer(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer) { return CallDisplayFunction(device, display, &HWCDisplay::DestroyLayer, layer); } int32_t HWCSession::DestroyVirtualDisplay(hwc2_device_t *device, hwc2_display_t display) { if (!device || display != HWC_DISPLAY_VIRTUAL) { return HWC2_ERROR_BAD_DISPLAY; } SCOPE_LOCK(locker_[display]); DLOGI("Destroying virtual display id:%" PRIu64, display); auto *hwc_session = static_cast(device); if (hwc_session->hwc_display_[display]) { HWCDisplayVirtual::Destroy(hwc_session->hwc_display_[display]); hwc_session->hwc_display_[display] = nullptr; return HWC2_ERROR_NONE; } else { return HWC2_ERROR_BAD_DISPLAY; } } void HWCSession::Dump(hwc2_device_t *device, uint32_t *out_size, char *out_buffer) { if (!device || !out_size) { return; } auto *hwc_session = static_cast(device); const size_t max_dump_size = 8192; if (out_buffer == nullptr) { *out_size = max_dump_size; } else { std::string s {}; for (int id = HWC_DISPLAY_PRIMARY; id <= HWC_DISPLAY_VIRTUAL; id++) { SCOPE_LOCK(locker_[id]); if (hwc_session->hwc_display_[id]) { s += hwc_session->hwc_display_[id]->Dump(); } } auto copied = s.copy(out_buffer, std::min(s.size(), max_dump_size), 0); *out_size = UINT32(copied); } } static int32_t GetActiveConfig(hwc2_device_t *device, hwc2_display_t display, hwc2_config_t *out_config) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetActiveConfig, out_config); } static int32_t GetChangedCompositionTypes(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_num_elements, hwc2_layer_t *out_layers, int32_t *out_types) { // null_ptr check only for out_num_elements, as out_layers and out_types can be null. if (!out_num_elements) { return HWC2_ERROR_BAD_PARAMETER; } return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetChangedCompositionTypes, out_num_elements, out_layers, out_types); } static int32_t GetClientTargetSupport(hwc2_device_t *device, hwc2_display_t display, uint32_t width, uint32_t height, int32_t format, int32_t dataspace) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetClientTargetSupport, width, height, format, dataspace); } static int32_t GetColorModes(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_num_modes, int32_t /*ColorMode*/ *int_out_modes) { auto out_modes = reinterpret_cast(int_out_modes); if (out_num_modes == nullptr) { return HWC2_ERROR_BAD_PARAMETER; } return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetColorModes, out_num_modes, out_modes); } static int32_t GetRenderIntents(hwc2_device_t *device, hwc2_display_t display, int32_t /*ColorMode*/ int_mode, uint32_t *out_num_intents, int32_t /*RenderIntent*/ *int_out_intents) { auto mode = static_cast(int_mode); auto out_intents = reinterpret_cast(int_out_intents); if (out_num_intents == nullptr) { return HWC2_ERROR_BAD_PARAMETER; } if (mode < ColorMode::NATIVE || mode > ColorMode::BT2100_HLG) { DLOGE("Invalid ColorMode: %d", mode); return HWC2_ERROR_BAD_PARAMETER; } return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetRenderIntents, mode, out_num_intents, out_intents); } static int32_t GetDataspaceSaturationMatrix(hwc2_device_t *device, int32_t /*Dataspace*/ int_dataspace, float *out_matrix) { auto dataspace = static_cast(int_dataspace); if (device == nullptr || out_matrix == nullptr || dataspace != Dataspace::SRGB_LINEAR) { return HWC2_ERROR_BAD_PARAMETER; } // We only have the matrix for sRGB float saturation_matrix[kDataspaceSaturationMatrixCount] = { 1.0, 0.0, 0.0, 0.0, \ 0.0, 1.0, 0.0, 0.0, \ 0.0, 0.0, 1.0, 0.0, \ 0.0, 0.0, 0.0, 1.0 }; // TODO(user): This value should ideally be retrieved from a QDCM configuration file char value[kPropertyMax] = {}; if (Debug::Get()->GetProperty(DATASPACE_SATURATION_MATRIX_PROP, value) != kErrorNone) { DLOGW("Undefined saturation matrix"); return HWC2_ERROR_BAD_CONFIG; } std::string value_string(value); std::size_t start = 0, end = 0; int index = 0; while ((end = value_string.find(",", start)) != std::string::npos) { saturation_matrix[index] = std::stof(value_string.substr(start, end - start)); start = end + 1; index++; // We expect a 3x3, SF needs 4x4, keep the last row/column identity if ((index + 1) % 4 == 0) { index++; } } saturation_matrix[index] = std::stof(value_string.substr(start, end - start)); if (index < kDataspaceSaturationPropertyElements - 1) { // The property must have kDataspaceSaturationPropertyElements delimited by commas DLOGW("Invalid saturation matrix defined"); return HWC2_ERROR_BAD_CONFIG; } for (int32_t i = 0; i < kDataspaceSaturationMatrixCount; i += 4) { DLOGD("%f %f %f %f", saturation_matrix[i], saturation_matrix[i + 1], saturation_matrix[i + 2], saturation_matrix[i + 3]); } for (uint32_t i = 0; i < kDataspaceSaturationMatrixCount; i++) { out_matrix[i] = saturation_matrix[i]; } return HWC2_ERROR_NONE; } static int32_t GetPerFrameMetadataKeys(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_num_keys, int32_t *int_out_keys) { auto out_keys = reinterpret_cast(int_out_keys); return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetPerFrameMetadataKeys, out_num_keys, out_keys); } static int32_t SetLayerPerFrameMetadata(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, uint32_t num_elements, const int32_t *int_keys, const float *metadata) { auto keys = reinterpret_cast(int_keys); return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerPerFrameMetadata, num_elements, keys, metadata); } static int32_t SetDisplayedContentSamplingEnabled(hwc2_device_t* device, hwc2_display_t display, int32_t enabled, uint8_t component_mask, uint64_t max_frames) { static constexpr int32_t validComponentMask = HWC2_FORMAT_COMPONENT_0 | HWC2_FORMAT_COMPONENT_1 | HWC2_FORMAT_COMPONENT_2 | HWC2_FORMAT_COMPONENT_3; if (component_mask & ~validComponentMask) return HWC2_ERROR_BAD_PARAMETER; return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetDisplayedContentSamplingEnabled, enabled, component_mask, max_frames); } static int32_t GetDisplayedContentSamplingAttributes(hwc2_device_t* device, hwc2_display_t display, int32_t* format, int32_t* dataspace, uint8_t* supported_components) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayedContentSamplingAttributes, format, dataspace, supported_components); } static int32_t GetDisplayedContentSample( hwc2_device_t* device, hwc2_display_t display, uint64_t max_frames, uint64_t timestamp, uint64_t* numFrames, int32_t samples_size[NUM_HISTOGRAM_COLOR_COMPONENTS], uint64_t* samples[NUM_HISTOGRAM_COLOR_COMPONENTS]) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayedContentSample, max_frames, timestamp, numFrames, samples_size, samples); } static int32_t GetDisplayAttribute(hwc2_device_t *device, hwc2_display_t display, hwc2_config_t config, int32_t int_attribute, int32_t *out_value) { if (out_value == nullptr || int_attribute < HWC2_ATTRIBUTE_INVALID || int_attribute > HWC2_ATTRIBUTE_DPI_Y) { return HWC2_ERROR_BAD_PARAMETER; } auto attribute = static_cast(int_attribute); return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayAttribute, config, attribute, out_value); } static int32_t GetDisplayConfigs(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_num_configs, hwc2_config_t *out_configs) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayConfigs, out_num_configs, out_configs); } static int32_t GetDisplayName(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_size, char *out_name) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayName, out_size, out_name); } static int32_t GetDisplayRequests(hwc2_device_t *device, hwc2_display_t display, int32_t *out_display_requests, uint32_t *out_num_elements, hwc2_layer_t *out_layers, int32_t *out_layer_requests) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayRequests, out_display_requests, out_num_elements, out_layers, out_layer_requests); } static int32_t GetDisplayType(hwc2_device_t *device, hwc2_display_t display, int32_t *out_type) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetDisplayType, out_type); } int32_t HWCSession::GetDozeSupport(hwc2_device_t *device, hwc2_display_t display, int32_t *out_support) { if (!device || !out_support) { return HWC2_ERROR_BAD_PARAMETER; } HWCSession *hwc_session = static_cast(device); if (display >= HWC_NUM_DISPLAY_TYPES || (hwc_session->hwc_display_[display] == nullptr) ) { return HWC2_ERROR_BAD_DISPLAY; } if (display == HWC_DISPLAY_PRIMARY) { *out_support = 1; } else { *out_support = 0; } return HWC2_ERROR_NONE; } static int32_t GetHdrCapabilities(hwc2_device_t* device, hwc2_display_t display, uint32_t* out_num_types, int32_t* out_types, float* out_max_luminance, float* out_max_average_luminance, float* out_min_luminance) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetHdrCapabilities, out_num_types, out_types, out_max_luminance, out_max_average_luminance, out_min_luminance); } static uint32_t GetMaxVirtualDisplayCount(hwc2_device_t *device) { if (device == nullptr) { return HWC2_ERROR_BAD_PARAMETER; } return 1; } static int32_t GetReleaseFences(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_num_elements, hwc2_layer_t *out_layers, int32_t *out_fences) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::GetReleaseFences, out_num_elements, out_layers, out_fences); } int32_t HWCSession::PresentDisplay(hwc2_device_t *device, hwc2_display_t display, int32_t *out_retire_fence) { HWCSession *hwc_session = static_cast(device); bool notify_hotplug = false; auto status = HWC2::Error::BadDisplay; DTRACE_SCOPED(); if (display >= HWC_NUM_DISPLAY_TYPES || (hwc_session->hwc_display_[display] == nullptr)) { return HWC2_ERROR_BAD_DISPLAY; } { SEQUENCE_EXIT_SCOPE_LOCK(locker_[display]); if (!device) { return HWC2_ERROR_BAD_DISPLAY; } if (out_retire_fence == nullptr) { return HWC2_ERROR_BAD_PARAMETER; } // TODO(user): Handle virtual display/HDMI concurrency status = hwc_session->PresentDisplayInternal(display, out_retire_fence); } if (status != HWC2::Error::None && status != HWC2::Error::NotValidated) { SEQUENCE_CANCEL_SCOPE_LOCK(locker_[display]); } // Handle Pending external display connection if (hwc_session->external_pending_connect_ && (display == HWC_DISPLAY_PRIMARY)) { Locker::ScopeLock lock_e(locker_[HWC_DISPLAY_EXTERNAL]); Locker::ScopeLock lock_v(locker_[HWC_DISPLAY_VIRTUAL]); if (!hwc_session->hwc_display_[HWC_DISPLAY_VIRTUAL]) { DLOGD("Process pending external display connection"); hwc_session->ConnectDisplay(HWC_DISPLAY_EXTERNAL); hwc_session->external_pending_connect_ = false; notify_hotplug = true; } } if (notify_hotplug) { hwc_session->HotPlug(HWC_DISPLAY_EXTERNAL, HWC2::Connection::Connected); } return INT32(status); } int32_t HWCSession::RegisterCallback(hwc2_device_t *device, int32_t descriptor, hwc2_callback_data_t callback_data, hwc2_function_pointer_t pointer) { if (!device) { return HWC2_ERROR_BAD_PARAMETER; } HWCSession *hwc_session = static_cast(device); SCOPE_LOCK(hwc_session->callbacks_lock_); auto desc = static_cast(descriptor); auto error = hwc_session->callbacks_.Register(desc, callback_data, pointer); DLOGD("%s callback: %s", pointer ? "Registering" : "Deregistering", to_string(desc).c_str()); if (descriptor == HWC2_CALLBACK_HOTPLUG) { if (hwc_session->hwc_display_[HWC_DISPLAY_PRIMARY]) { hwc_session->callbacks_.Hotplug(HWC_DISPLAY_PRIMARY, HWC2::Connection::Connected); } } hwc_session->need_invalidate_ = false; hwc_session->callbacks_lock_.Broadcast(); return INT32(error); } static int32_t SetActiveConfig(hwc2_device_t *device, hwc2_display_t display, hwc2_config_t config) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetActiveConfig, config); } static int32_t SetClientTarget(hwc2_device_t *device, hwc2_display_t display, buffer_handle_t target, int32_t acquire_fence, int32_t dataspace, hwc_region_t damage) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetClientTarget, target, acquire_fence, dataspace, damage); } int32_t HWCSession::SetColorMode(hwc2_device_t *device, hwc2_display_t display, int32_t /*ColorMode*/ int_mode) { auto mode = static_cast(int_mode); if (mode < ColorMode::NATIVE || mode > ColorMode::BT2100_HLG) { return HWC2_ERROR_BAD_PARAMETER; } return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetColorMode, mode); } int32_t HWCSession::SetColorModeWithRenderIntent(hwc2_device_t *device, hwc2_display_t display, int32_t /*ColorMode*/ int_mode, int32_t /*RenderIntent*/ int_render_intent) { auto mode = static_cast(int_mode); if (mode < ColorMode::NATIVE || mode > ColorMode::BT2100_HLG) { return HWC2_ERROR_BAD_PARAMETER; } auto render_intent = static_cast(int_render_intent); if ((render_intent < RenderIntent::COLORIMETRIC) || (render_intent > RenderIntent::TONE_MAP_ENHANCE)) { DLOGE("Invalid RenderIntent: %d", render_intent); return HWC2_ERROR_BAD_PARAMETER; } return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetColorModeWithRenderIntent, mode, render_intent); } int32_t HWCSession::SetColorTransform(hwc2_device_t *device, hwc2_display_t display, const float *matrix, int32_t /*android_color_transform_t*/ hint) { if (!matrix || hint < HAL_COLOR_TRANSFORM_IDENTITY || hint > HAL_COLOR_TRANSFORM_CORRECT_TRITANOPIA) { return HWC2_ERROR_BAD_PARAMETER; } android_color_transform_t transform_hint = static_cast(hint); return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetColorTransform, matrix, transform_hint); } static int32_t SetCursorPosition(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, int32_t x, int32_t y) { auto status = INT32(HWC2::Error::None); status = HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetCursorPosition, layer, x, y); if (status == INT32(HWC2::Error::None)) { // Update cursor position HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetCursorPosition, x, y); } return status; } static int32_t SetLayerBlendMode(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, int32_t int_mode) { if (int_mode < HWC2_BLEND_MODE_INVALID || int_mode > HWC2_BLEND_MODE_COVERAGE) { return HWC2_ERROR_BAD_PARAMETER; } auto mode = static_cast(int_mode); return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerBlendMode, mode); } static int32_t SetLayerBuffer(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, buffer_handle_t buffer, int32_t acquire_fence) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerBuffer, buffer, acquire_fence); } static int32_t SetLayerColor(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, hwc_color_t color) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerColor, color); } static int32_t SetLayerCompositionType(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, int32_t int_type) { auto type = static_cast(int_type); return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerCompositionType, type); } static int32_t SetLayerDataspace(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, int32_t dataspace) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerDataspace, dataspace); } static int32_t SetLayerDisplayFrame(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, hwc_rect_t frame) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerDisplayFrame, frame); } static int32_t SetLayerPlaneAlpha(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, float alpha) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerPlaneAlpha, alpha); } static int32_t SetLayerSourceCrop(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, hwc_frect_t crop) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerSourceCrop, crop); } static int32_t SetLayerSurfaceDamage(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, hwc_region_t damage) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerSurfaceDamage, damage); } static int32_t SetLayerTransform(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, int32_t int_transform) { auto transform = static_cast(int_transform); return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerTransform, transform); } static int32_t SetLayerVisibleRegion(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, hwc_region_t visible) { return HWCSession::CallLayerFunction(device, display, layer, &HWCLayer::SetLayerVisibleRegion, visible); } static int32_t SetLayerZOrder(hwc2_device_t *device, hwc2_display_t display, hwc2_layer_t layer, uint32_t z) { return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetLayerZOrder, layer, z); } int32_t HWCSession::SetOutputBuffer(hwc2_device_t *device, hwc2_display_t display, buffer_handle_t buffer, int32_t releaseFence) { if (!device) { return HWC2_ERROR_BAD_PARAMETER; } if (display != HWC_DISPLAY_VIRTUAL) { return HWC2_ERROR_UNSUPPORTED; } SCOPE_LOCK(locker_[display]); auto *hwc_session = static_cast(device); if (hwc_session->hwc_display_[display]) { auto vds = reinterpret_cast(hwc_session->hwc_display_[display]); auto status = vds->SetOutputBuffer(buffer, releaseFence); return INT32(status); } else { return HWC2_ERROR_BAD_DISPLAY; } } int32_t HWCSession::SetPowerMode(hwc2_device_t *device, hwc2_display_t display, int32_t int_mode) { if (display >= HWC_NUM_DISPLAY_TYPES) { return HWC2_ERROR_BAD_DISPLAY; } // validate device and also avoid undefined behavior in cast to HWC2::PowerMode if (!device || int_mode < HWC2_POWER_MODE_OFF || int_mode > HWC2_POWER_MODE_DOZE_SUSPEND) { return HWC2_ERROR_BAD_PARAMETER; } auto mode = static_cast(int_mode); // all displays support on/off. Check for doze modes int support = 0; auto status = GetDozeSupport(device, display, &support); if (status != HWC2_ERROR_NONE) { return INT32(status); } if (!support && (mode == HWC2::PowerMode::Doze || mode == HWC2::PowerMode::DozeSuspend)) { return HWC2_ERROR_UNSUPPORTED; } auto error = CallDisplayFunction(device, display, &HWCDisplay::SetPowerMode, mode); if (error != HWC2_ERROR_NONE) { return error; } // Reset idle pc ref count on suspend, as we enable idle pc during suspend. if (mode == HWC2::PowerMode::Off) { HWCSession *hwc_session = static_cast(device); hwc_session->idle_pc_ref_cnt_ = 0; } return HWC2_ERROR_NONE; } static int32_t SetVsyncEnabled(hwc2_device_t *device, hwc2_display_t display, int32_t int_enabled) { // avoid undefined behavior in cast to HWC2::Vsync if (int_enabled < HWC2_VSYNC_INVALID || int_enabled > HWC2_VSYNC_DISABLE) { return HWC2_ERROR_BAD_PARAMETER; } auto enabled = static_cast(int_enabled); return HWCSession::CallDisplayFunction(device, display, &HWCDisplay::SetVsyncEnabled, enabled); } int32_t HWCSession::ValidateDisplay(hwc2_device_t *device, hwc2_display_t display, uint32_t *out_num_types, uint32_t *out_num_requests) { // out_num_types and out_num_requests will be non-NULL if (!device) { return HWC2_ERROR_BAD_PARAMETER; } if (display >= HWC_NUM_DISPLAY_TYPES) { return HWC2_ERROR_BAD_DISPLAY; } DTRACE_SCOPED(); HWCSession *hwc_session = static_cast(device); // TODO(user): Handle secure session, handle QDCM solid fill // Handle external_pending_connect_ in CreateVirtualDisplay auto status = HWC2::Error::BadDisplay; { SEQUENCE_ENTRY_SCOPE_LOCK(locker_[display]); if (hwc_session->hwc_display_[display]) { status = hwc_session->ValidateDisplayInternal(display, out_num_types, out_num_requests); } } // Sequence locking currently begins on Validate, so cancel the sequence lock on failures if (status != HWC2::Error::None && status != HWC2::Error::HasChanges) { SEQUENCE_CANCEL_SCOPE_LOCK(locker_[display]); } return INT32(status); } int32_t HWCSession::GetDisplayCapabilities(hwc2_device_t* device, hwc2_display_t display, uint32_t* outNumCapabilities, uint32_t* outCapabilities) { if (outNumCapabilities == nullptr) { return INT32(HWC2::Error::None); } bool brightness_support = false; auto status = GetDisplayBrightnessSupport(device, display, &brightness_support); if (status != HWC2_ERROR_NONE) { DLOGE("Failed to get display brightness support Error = %d", status); return INT32(status); } int doze_support = 0; status = GetDozeSupport(device, display, &doze_support); if (status != HWC2_ERROR_NONE) { DLOGE("Failed to get doze support Error = %d", status); return INT32(status); } uint32_t count = 1 + static_cast(doze_support) + (brightness_support ? 1 : 0); int index = 0; if (outCapabilities != nullptr && (*outNumCapabilities >= count)) { outCapabilities[index++] = HWC2_DISPLAY_CAPABILITY_SKIP_CLIENT_COLOR_TRANSFORM; if (doze_support == 1) { outCapabilities[index++] = HWC2_DISPLAY_CAPABILITY_DOZE; } if (brightness_support) { outCapabilities[index++] = HWC2_DISPLAY_CAPABILITY_BRIGHTNESS; } } *outNumCapabilities = count; return INT32(HWC2::Error::None); } int32_t HWCSession::SetDisplayBrightness(hwc2_device_t *device, hwc2_display_t display, float brightness) { bool brightness_support = false; auto status = GetDisplayBrightnessSupport(device, display, &brightness_support); if (status != HWC2_ERROR_NONE) { return INT32(status); } if (!brightness_support) { return HWC2_ERROR_UNSUPPORTED; } int backlight = -1; if (brightness == -1.0f) { backlight = 0; } else if (brightness < 0.0f || brightness > 1.0f) { return INT32(HWC2::Error::BadParameter); } else { // 0 is reserved for "backlight off", so we scale the brightness from 1 to MAX_BRIGHTNESS. backlight = (int) ((MAX_BRIGHTNESS - 1.0f) * brightness + 1.0f); } char buff[20]; int n = snprintf(buff, sizeof(buff), "%d\n", backlight); if (n < 0 || n >= sizeof(buff)) { return INT32(HWC2::Error::BadParameter); } HWCSession *hwc_session = static_cast(device); long error = lseek(hwc_session->brightness_fd_, 0, SEEK_SET); if (error == -1) { DLOGW("Failed to rewind brightness file: [%d] %s", errno, strerror(errno)); return INT32(HWC2::Error::NoResources); } error = write(hwc_session->brightness_fd_, buff, (size_t) n); if (error == -1) { DLOGW("Failed to write to brightness file: [%d] %s", errno, strerror(errno)); return INT32(HWC2::Error::NoResources); } error = fsync(hwc_session->brightness_fd_); if (error == -1) { DLOGW("Failed to flush brightness file: [%d] %s", errno, strerror(errno)); return INT32(HWC2::Error::NoResources); } return INT32(HWC2::Error::None); } hwc2_function_pointer_t HWCSession::GetFunction(struct hwc2_device *device, int32_t int_descriptor) { auto descriptor = static_cast(int_descriptor); switch (descriptor) { case HWC2::FunctionDescriptor::AcceptDisplayChanges: return AsFP(HWCSession::AcceptDisplayChanges); case HWC2::FunctionDescriptor::CreateLayer: return AsFP(CreateLayer); case HWC2::FunctionDescriptor::CreateVirtualDisplay: return AsFP(HWCSession::CreateVirtualDisplay); case HWC2::FunctionDescriptor::DestroyLayer: return AsFP(DestroyLayer); case HWC2::FunctionDescriptor::DestroyVirtualDisplay: return AsFP(HWCSession::DestroyVirtualDisplay); case HWC2::FunctionDescriptor::Dump: return AsFP(HWCSession::Dump); case HWC2::FunctionDescriptor::GetActiveConfig: return AsFP(GetActiveConfig); case HWC2::FunctionDescriptor::GetChangedCompositionTypes: return AsFP(GetChangedCompositionTypes); case HWC2::FunctionDescriptor::GetClientTargetSupport: return AsFP(GetClientTargetSupport); case HWC2::FunctionDescriptor::GetColorModes: return AsFP(GetColorModes); case HWC2::FunctionDescriptor::GetDisplayAttribute: return AsFP(GetDisplayAttribute); case HWC2::FunctionDescriptor::GetDisplayConfigs: return AsFP(GetDisplayConfigs); case HWC2::FunctionDescriptor::GetDisplayName: return AsFP(GetDisplayName); case HWC2::FunctionDescriptor::GetDisplayRequests: return AsFP(GetDisplayRequests); case HWC2::FunctionDescriptor::GetDisplayType: return AsFP(GetDisplayType); case HWC2::FunctionDescriptor::GetHdrCapabilities: return AsFP(GetHdrCapabilities); case HWC2::FunctionDescriptor::GetDozeSupport: return AsFP(GetDozeSupport); case HWC2::FunctionDescriptor::GetMaxVirtualDisplayCount: return AsFP(GetMaxVirtualDisplayCount); case HWC2::FunctionDescriptor::GetReleaseFences: return AsFP(GetReleaseFences); case HWC2::FunctionDescriptor::PresentDisplay: return AsFP(PresentDisplay); case HWC2::FunctionDescriptor::RegisterCallback: return AsFP(RegisterCallback); case HWC2::FunctionDescriptor::SetActiveConfig: return AsFP(SetActiveConfig); case HWC2::FunctionDescriptor::SetClientTarget: return AsFP(SetClientTarget); case HWC2::FunctionDescriptor::SetColorMode: return AsFP(SetColorMode); case HWC2::FunctionDescriptor::SetColorTransform: return AsFP(SetColorTransform); case HWC2::FunctionDescriptor::SetCursorPosition: return AsFP(SetCursorPosition); case HWC2::FunctionDescriptor::SetLayerBlendMode: return AsFP(SetLayerBlendMode); case HWC2::FunctionDescriptor::SetLayerBuffer: return AsFP(SetLayerBuffer); case HWC2::FunctionDescriptor::SetLayerColor: return AsFP(SetLayerColor); case HWC2::FunctionDescriptor::SetLayerCompositionType: return AsFP(SetLayerCompositionType); case HWC2::FunctionDescriptor::SetLayerDataspace: return AsFP(SetLayerDataspace); case HWC2::FunctionDescriptor::SetLayerDisplayFrame: return AsFP(SetLayerDisplayFrame); case HWC2::FunctionDescriptor::SetLayerPlaneAlpha: return AsFP(SetLayerPlaneAlpha); // Sideband stream is not supported // case HWC2::FunctionDescriptor::SetLayerSidebandStream: case HWC2::FunctionDescriptor::SetLayerSourceCrop: return AsFP(SetLayerSourceCrop); case HWC2::FunctionDescriptor::SetLayerSurfaceDamage: return AsFP(SetLayerSurfaceDamage); case HWC2::FunctionDescriptor::SetLayerTransform: return AsFP(SetLayerTransform); case HWC2::FunctionDescriptor::SetLayerVisibleRegion: return AsFP(SetLayerVisibleRegion); case HWC2::FunctionDescriptor::SetLayerZOrder: return AsFP(SetLayerZOrder); case HWC2::FunctionDescriptor::SetOutputBuffer: return AsFP(SetOutputBuffer); case HWC2::FunctionDescriptor::SetPowerMode: return AsFP(SetPowerMode); case HWC2::FunctionDescriptor::SetVsyncEnabled: return AsFP(SetVsyncEnabled); case HWC2::FunctionDescriptor::ValidateDisplay: return AsFP(HWCSession::ValidateDisplay); case HWC2::FunctionDescriptor::SetReadbackBuffer: return AsFP(HWCSession::SetReadbackBuffer); case HWC2::FunctionDescriptor::GetReadbackBufferAttributes: return AsFP(HWCSession::GetReadbackBufferAttributes); case HWC2::FunctionDescriptor::GetReadbackBufferFence: return AsFP(HWCSession::GetReadbackBufferFence); case HWC2::FunctionDescriptor::GetRenderIntents: return AsFP(GetRenderIntents); case HWC2::FunctionDescriptor::SetColorModeWithRenderIntent: return AsFP( HWCSession::SetColorModeWithRenderIntent); case HWC2::FunctionDescriptor::GetDataspaceSaturationMatrix: return AsFP(GetDataspaceSaturationMatrix); case HWC2::FunctionDescriptor::GetPerFrameMetadataKeys: return AsFP(GetPerFrameMetadataKeys); case HWC2::FunctionDescriptor::SetLayerPerFrameMetadata: return AsFP(SetLayerPerFrameMetadata); case HWC2::FunctionDescriptor::SetDisplayedContentSamplingEnabled: return AsFP(SetDisplayedContentSamplingEnabled); case HWC2::FunctionDescriptor::GetDisplayedContentSamplingAttributes: return AsFP(GetDisplayedContentSamplingAttributes); case HWC2::FunctionDescriptor::GetDisplayedContentSample: return AsFP(GetDisplayedContentSample); case HWC2::FunctionDescriptor::GetDisplayCapabilities: return AsFP(GetDisplayCapabilities); case HWC2::FunctionDescriptor::SetDisplayBrightness: return AsFP(SetDisplayBrightness); default: DLOGD("Unknown/Unimplemented function descriptor: %d (%s)", int_descriptor, to_string(descriptor).c_str()); return nullptr; } return nullptr; } HWC2::Error HWCSession::CreateVirtualDisplayObject(uint32_t width, uint32_t height, int32_t *format) { { SCOPE_LOCK(locker_[HWC_DISPLAY_VIRTUAL]); if (hwc_display_[HWC_DISPLAY_VIRTUAL]) { return HWC2::Error::NoResources; } if (hwc_display_[HWC_DISPLAY_PRIMARY]) { auto error = hwc_display_[HWC_DISPLAY_PRIMARY]->TeardownConcurrentWriteback(); if (error) { return HWC2::Error::NoResources; } } auto status = HWCDisplayVirtual::Create(core_intf_, &buffer_allocator_, &callbacks_, width, height, format, &hwc_display_[HWC_DISPLAY_VIRTUAL]); // TODO(user): validate width and height support if (status) { return HWC2::Error::NoResources; } } SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); hwc_display_[HWC_DISPLAY_PRIMARY]->ResetValidation(); return HWC2::Error::None; } int32_t HWCSession::ConnectDisplay(int disp) { DLOGI("Display = %d", disp); int status = 0; uint32_t primary_width = 0; uint32_t primary_height = 0; hwc_display_[HWC_DISPLAY_PRIMARY]->GetFrameBufferResolution(&primary_width, &primary_height); if (disp == HWC_DISPLAY_EXTERNAL) { status = CreateExternalDisplay(disp, primary_width, primary_height, false); } else { DLOGE("Invalid display type"); return -1; } if (!status) { hwc_display_[disp]->SetSecureDisplay(secure_display_active_); } return status; } int HWCSession::DisconnectDisplay(int disp) { DLOGI("Display = %d", disp); if (disp == HWC_DISPLAY_EXTERNAL) { DisplayError error = hwc_display_[disp]->Flush(); if (error != kErrorNone) { DLOGW("Flush failed. Error = %d", error); } HWCDisplayExternal::Destroy(hwc_display_[disp]); } else if (disp == HWC_DISPLAY_VIRTUAL) { HWCDisplayVirtual::Destroy(hwc_display_[disp]); } else { DLOGE("Invalid display type"); return -1; } hwc_display_[disp] = NULL; return 0; } // Qclient methods android::status_t HWCSession::notifyCallback(uint32_t command, const android::Parcel *input_parcel, android::Parcel *output_parcel) { android::status_t status = -EINVAL; switch (command) { case qService::IQService::DYNAMIC_DEBUG: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = 0; DynamicDebug(input_parcel); break; case qService::IQService::SCREEN_REFRESH: status = refreshScreen(); break; case qService::IQService::SET_IDLE_TIMEOUT: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = setIdleTimeout(UINT32(input_parcel->readInt32())); break; case qService::IQService::SET_FRAME_DUMP_CONFIG: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetFrameDumpConfig(input_parcel); break; case qService::IQService::SET_MAX_PIPES_PER_MIXER: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetMaxMixerStages(input_parcel); break; case qService::IQService::SET_DISPLAY_MODE: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetDisplayMode(input_parcel); break; case qService::IQService::SET_SECONDARY_DISPLAY_STATUS: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } int disp_id = INT(input_parcel->readInt32()); HWCDisplay::DisplayStatus disp_status = static_cast(input_parcel->readInt32()); status = SetSecondaryDisplayStatus(disp_id, disp_status); output_parcel->writeInt32(status); } break; case qService::IQService::CONFIGURE_DYN_REFRESH_RATE: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = ConfigureRefreshRate(input_parcel); break; case qService::IQService::SET_VIEW_FRAME: status = 0; break; case qService::IQService::TOGGLE_SCREEN_UPDATES: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } int32_t input = input_parcel->readInt32(); status = toggleScreenUpdate(input == 1); output_parcel->writeInt32(status); } break; case qService::IQService::QDCM_SVC_CMDS: if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } status = QdcmCMDHandler(input_parcel, output_parcel); break; case qService::IQService::MIN_HDCP_ENCRYPTION_LEVEL_CHANGED: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } int disp_id = input_parcel->readInt32(); uint32_t min_enc_level = UINT32(input_parcel->readInt32()); status = MinHdcpEncryptionLevelChanged(disp_id, min_enc_level); output_parcel->writeInt32(status); } break; case qService::IQService::CONTROL_PARTIAL_UPDATE: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } int disp_id = input_parcel->readInt32(); uint32_t enable = UINT32(input_parcel->readInt32()); status = ControlPartialUpdate(disp_id, enable == 1); output_parcel->writeInt32(status); } break; case qService::IQService::SET_ACTIVE_CONFIG: { if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } uint32_t config = UINT32(input_parcel->readInt32()); int disp_id = input_parcel->readInt32(); status = SetActiveConfigIndex(disp_id, config); } break; case qService::IQService::GET_ACTIVE_CONFIG: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } int disp_id = input_parcel->readInt32(); uint32_t config = 0; status = GetActiveConfigIndex(disp_id, &config); output_parcel->writeInt32(INT(config)); } break; case qService::IQService::GET_CONFIG_COUNT: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } int disp_id = input_parcel->readInt32(); uint32_t count = 0; status = GetConfigCount(disp_id, &count); output_parcel->writeInt32(INT(count)); } break; case qService::IQService::GET_DISPLAY_ATTRIBUTES_FOR_CONFIG: if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } status = HandleGetDisplayAttributesForConfig(input_parcel, output_parcel); break; case qService::IQService::GET_PANEL_BRIGHTNESS: { if (!output_parcel) { DLOGE("QService command = %d: output_parcel needed.", command); break; } int level = 0; status = GetPanelBrightness(&level); output_parcel->writeInt32(level); } break; case qService::IQService::SET_PANEL_BRIGHTNESS: { if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } uint32_t level = UINT32(input_parcel->readInt32()); status = setPanelBrightness(level); output_parcel->writeInt32(status); } break; case qService::IQService::GET_DISPLAY_VISIBLE_REGION: if (!input_parcel || !output_parcel) { DLOGE("QService command = %d: input_parcel and output_parcel needed.", command); break; } status = GetVisibleDisplayRect(input_parcel, output_parcel); break; case qService::IQService::SET_CAMERA_STATUS: { if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } uint32_t camera_status = UINT32(input_parcel->readInt32()); status = setCameraLaunchStatus(camera_status); } break; case qService::IQService::GET_BW_TRANSACTION_STATUS: { if (!output_parcel) { DLOGE("QService command = %d: output_parcel needed.", command); break; } bool state = true; status = DisplayBWTransactionPending(&state); output_parcel->writeInt32(state); } break; case qService::IQService::SET_LAYER_MIXER_RESOLUTION: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetMixerResolution(input_parcel); break; case qService::IQService::SET_COLOR_MODE: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetColorModeOverride(input_parcel); break; case qService::IQService::SET_COLOR_MODE_WITH_RENDER_INTENT: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetColorModeWithRenderIntentOverride(input_parcel); break; case qService::IQService::SET_COLOR_MODE_BY_ID: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetColorModeById(input_parcel); break; case qService::IQService::GET_COMPOSER_STATUS: if (!output_parcel) { DLOGE("QService command = %d: output_parcel needed.", command); break; } status = 0; output_parcel->writeInt32(getComposerStatus()); break; case qService::IQService::SET_IDLE_PC: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetIdlePC(input_parcel); break; case qService::IQService::SET_COLOR_SAMPLING_ENABLED: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = setColorSamplingEnabled(input_parcel); break; case qService::IQService::SET_WHITE_COMPENSATION: if (!input_parcel) { DLOGE("QService command = %d: input_parcel needed.", command); break; } status = SetWhiteCompensation(input_parcel); break; default: DLOGW("QService command = %d is not supported.", command); break; } return status; } android::status_t HWCSession::getComposerStatus() { return is_composer_up_; } android::status_t HWCSession::setColorSamplingEnabled(const android::Parcel* input_parcel) { int dpy = input_parcel->readInt32(); int enabled_cmd = input_parcel->readInt32(); if (dpy < HWC_DISPLAY_PRIMARY || dpy >= HWC_NUM_DISPLAY_TYPES || enabled_cmd < 0 || enabled_cmd > 1) { return android::BAD_VALUE; } SEQUENCE_WAIT_SCOPE_LOCK(locker_[dpy]); if (!hwc_display_[dpy]) { DLOGW("No display id %i active to enable histogram event", dpy); return android::BAD_VALUE; } auto error = hwc_display_[dpy]->SetDisplayedContentSamplingEnabledVndService(enabled_cmd); return (error == HWC2::Error::None) ? android::OK : android::BAD_VALUE; } android::status_t HWCSession::HandleGetDisplayAttributesForConfig(const android::Parcel *input_parcel, android::Parcel *output_parcel) { int config = input_parcel->readInt32(); int dpy = input_parcel->readInt32(); int error = android::BAD_VALUE; DisplayConfigVariableInfo display_attributes; if (dpy < HWC_DISPLAY_PRIMARY || dpy >= HWC_NUM_DISPLAY_TYPES || config < 0) { return android::BAD_VALUE; } SEQUENCE_WAIT_SCOPE_LOCK(locker_[dpy]); if (hwc_display_[dpy]) { error = hwc_display_[dpy]->GetDisplayAttributesForConfig(config, &display_attributes); if (error == 0) { output_parcel->writeInt32(INT(display_attributes.vsync_period_ns)); output_parcel->writeInt32(INT(display_attributes.x_pixels)); output_parcel->writeInt32(INT(display_attributes.y_pixels)); output_parcel->writeFloat(display_attributes.x_dpi); output_parcel->writeFloat(display_attributes.y_dpi); output_parcel->writeInt32(0); // Panel type, unsupported. } } return error; } android::status_t HWCSession::ConfigureRefreshRate(const android::Parcel *input_parcel) { SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); uint32_t operation = UINT32(input_parcel->readInt32()); HWCDisplay *hwc_display = hwc_display_[HWC_DISPLAY_PRIMARY]; if (!hwc_display) { DLOGW("Display = %d is not connected.", HWC_DISPLAY_PRIMARY); return -ENODEV; } switch (operation) { case qdutils::DISABLE_METADATA_DYN_REFRESH_RATE: return hwc_display->Perform(HWCDisplayPrimary::SET_METADATA_DYN_REFRESH_RATE, false); case qdutils::ENABLE_METADATA_DYN_REFRESH_RATE: return hwc_display->Perform(HWCDisplayPrimary::SET_METADATA_DYN_REFRESH_RATE, true); case qdutils::SET_BINDER_DYN_REFRESH_RATE: { uint32_t refresh_rate = UINT32(input_parcel->readInt32()); return hwc_display->Perform(HWCDisplayPrimary::SET_BINDER_DYN_REFRESH_RATE, refresh_rate); } default: DLOGW("Invalid operation %d", operation); return -EINVAL; } return 0; } android::status_t HWCSession::SetDisplayMode(const android::Parcel *input_parcel) { SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); if (!hwc_display_[HWC_DISPLAY_PRIMARY]) { DLOGW("Display = %d is not connected.", HWC_DISPLAY_PRIMARY); return -ENODEV; } uint32_t mode = UINT32(input_parcel->readInt32()); return hwc_display_[HWC_DISPLAY_PRIMARY]->Perform(HWCDisplayPrimary::SET_DISPLAY_MODE, mode); } android::status_t HWCSession::SetMaxMixerStages(const android::Parcel *input_parcel) { DisplayError error = kErrorNone; std::bitset<32> bit_mask_display_type = UINT32(input_parcel->readInt32()); uint32_t max_mixer_stages = UINT32(input_parcel->readInt32()); android::status_t status = 0; for (uint32_t disp_id = HWC_DISPLAY_PRIMARY; disp_id < HWC_NUM_DISPLAY_TYPES; disp_id++) { if (bit_mask_display_type[disp_id]) { SEQUENCE_WAIT_SCOPE_LOCK(locker_[disp_id]); if (hwc_display_[disp_id]) { error = hwc_display_[disp_id]->SetMaxMixerStages(max_mixer_stages); if (error != kErrorNone) { status = -EINVAL; continue; } } else { DLOGW("Display = %d is not connected.", disp_id); status = (status)? status : -ENODEV; // Return higher priority error. continue; } } } return status; } android::status_t HWCSession::SetFrameDumpConfig(const android::Parcel *input_parcel) { uint32_t frame_dump_count = UINT32(input_parcel->readInt32()); std::bitset<32> bit_mask_display_type = UINT32(input_parcel->readInt32()); uint32_t bit_mask_layer_type = UINT32(input_parcel->readInt32()); int32_t output_format = HAL_PIXEL_FORMAT_RGB_888; bool post_processed = true; // Read optional user preferences: output_format and post_processed. if (input_parcel->dataPosition() != input_parcel->dataSize()) { // HAL Pixel Format for output buffer output_format = input_parcel->readInt32(); } if (input_parcel->dataPosition() != input_parcel->dataSize()) { // Option to dump Layer Mixer output (0) or DSPP output (1) post_processed = (input_parcel->readInt32() != 0); } android::status_t status = 0; for (uint32_t disp_id = HWC_DISPLAY_PRIMARY; disp_id < HWC_NUM_DISPLAY_TYPES; disp_id++) { if (bit_mask_display_type[disp_id]) { SEQUENCE_WAIT_SCOPE_LOCK(locker_[disp_id]); if (hwc_display_[disp_id]) { HWC2::Error error; error = hwc_display_[disp_id]->SetFrameDumpConfig(frame_dump_count, bit_mask_layer_type, output_format, post_processed); if (HWC2::Error::None != error) { if (HWC2::Error::NoResources == error) status = -ENOMEM; else status = -EINVAL; continue; } } else { DLOGW("Display = %d is not connected.", disp_id); status = (status)? status : -ENODEV; // Return higher priority error. continue; } } } return status; } android::status_t HWCSession::SetMixerResolution(const android::Parcel *input_parcel) { DisplayError error = kErrorNone; uint32_t dpy = UINT32(input_parcel->readInt32()); if (dpy != HWC_DISPLAY_PRIMARY) { DLOGW("Resolution change not supported for this display = %d", dpy); return -EINVAL; } SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); if (!hwc_display_[HWC_DISPLAY_PRIMARY]) { DLOGW("Primary display is not initialized"); return -ENODEV; } uint32_t width = UINT32(input_parcel->readInt32()); uint32_t height = UINT32(input_parcel->readInt32()); error = hwc_display_[HWC_DISPLAY_PRIMARY]->SetMixerResolution(width, height); if (error != kErrorNone) { return -EINVAL; } return 0; } android::status_t HWCSession::SetColorModeOverride(const android::Parcel *input_parcel) { auto display = static_cast(input_parcel->readInt32()); auto mode = static_cast(input_parcel->readInt32()); auto device = static_cast(this); if (mode < ColorMode::NATIVE || mode > ColorMode::BT2100_HLG) { DLOGE("Invalid ColorMode: %d", mode); return HWC2_ERROR_BAD_PARAMETER; } auto err = CallDisplayFunction(device, display, &HWCDisplay::SetColorMode, mode); if (err != HWC2_ERROR_NONE) return -EINVAL; return 0; } android::status_t HWCSession::SetWhiteCompensation(const android::Parcel *input_parcel) { auto display = static_cast(input_parcel->readInt32()); auto enabled = static_cast(input_parcel->readInt32()); auto device = static_cast(this); auto err = CallDisplayFunction(device, display, &HWCDisplay::SetWhiteCompensation, enabled); if (err != HWC2_ERROR_NONE) return -EINVAL; return 0; } android::status_t HWCSession::SetColorModeWithRenderIntentOverride( const android::Parcel *input_parcel) { auto display = static_cast(input_parcel->readInt32()); auto mode = static_cast(input_parcel->readInt32()); auto intent = static_cast(input_parcel->readInt32()); auto device = static_cast(this); if (mode < ColorMode::NATIVE || mode > ColorMode::BT2100_HLG) { DLOGE("Invalid ColorMode: %d", mode); return HWC2_ERROR_BAD_PARAMETER; } if (intent < RenderIntent::COLORIMETRIC || intent > RenderIntent::TONE_MAP_ENHANCE) { DLOGE("Invalid RenderIntent: %d", intent); return HWC2_ERROR_BAD_PARAMETER; } auto err = CallDisplayFunction(device, display, &HWCDisplay::SetColorModeWithRenderIntent, mode, intent); if (err != HWC2_ERROR_NONE) return -EINVAL; return 0; } android::status_t HWCSession::SetColorModeById(const android::Parcel *input_parcel) { auto display = static_cast(input_parcel->readInt32()); auto mode = input_parcel->readInt32(); auto device = static_cast(this); auto err = CallDisplayFunction(device, display, &HWCDisplay::SetColorModeById, mode); if (err != HWC2_ERROR_NONE) return -EINVAL; return 0; } void HWCSession::DynamicDebug(const android::Parcel *input_parcel) { int type = input_parcel->readInt32(); bool enable = (input_parcel->readInt32() > 0); DLOGI("type = %d enable = %d", type, enable); int verbose_level = input_parcel->readInt32(); switch (type) { case qService::IQService::DEBUG_ALL: HWCDebugHandler::DebugAll(enable, verbose_level); break; case qService::IQService::DEBUG_MDPCOMP: HWCDebugHandler::DebugStrategy(enable, verbose_level); HWCDebugHandler::DebugCompManager(enable, verbose_level); break; case qService::IQService::DEBUG_PIPE_LIFECYCLE: HWCDebugHandler::DebugResources(enable, verbose_level); break; case qService::IQService::DEBUG_DRIVER_CONFIG: HWCDebugHandler::DebugDriverConfig(enable, verbose_level); break; case qService::IQService::DEBUG_ROTATOR: HWCDebugHandler::DebugResources(enable, verbose_level); HWCDebugHandler::DebugDriverConfig(enable, verbose_level); HWCDebugHandler::DebugRotator(enable, verbose_level); break; case qService::IQService::DEBUG_QDCM: HWCDebugHandler::DebugQdcm(enable, verbose_level); break; case qService::IQService::DEBUG_SCALAR: HWCDebugHandler::DebugScalar(enable, verbose_level); break; case qService::IQService::DEBUG_CLIENT: HWCDebugHandler::DebugClient(enable, verbose_level); break; case qService::IQService::DEBUG_DISPLAY: HWCDebugHandler::DebugDisplay(enable, verbose_level); break; default: DLOGW("type = %d is not supported", type); } } android::status_t HWCSession::QdcmCMDHandler(const android::Parcel *input_parcel, android::Parcel *output_parcel) { int ret = 0; int32_t *brightness_value = NULL; uint32_t display_id(0); PPPendingParams pending_action; PPDisplayAPIPayload resp_payload, req_payload; if (!color_mgr_) { DLOGW("color_mgr_ not initialized."); return -ENOENT; } pending_action.action = kNoAction; pending_action.params = NULL; // Read display_id, payload_size and payload from in_parcel. ret = HWCColorManager::CreatePayloadFromParcel(*input_parcel, &display_id, &req_payload); if (!ret) { if ((display_id >= HWC_NUM_DISPLAY_TYPES) || !hwc_display_[display_id]) { DLOGW("Invalid display id or display = %d is not connected.", display_id); ret = -ENODEV; } } if (!ret) { if ((HWC_DISPLAY_PRIMARY == display_id) || (HWC_DISPLAY_EXTERNAL == display_id)) { ret = hwc_display_[display_id]->ColorSVCRequestRoute(req_payload, &resp_payload, &pending_action); } else { // Virtual, Tertiary etc. not supported. DLOGW("Operation not supported on display = %d.", display_id); ret = -EINVAL; } } if (ret) { output_parcel->writeInt32(ret); // first field in out parcel indicates return code. req_payload.DestroyPayload(); resp_payload.DestroyPayload(); return ret; } if (kNoAction != pending_action.action) { // Restrict pending actions to primary display. if (HWC_DISPLAY_PRIMARY != display_id) { DLOGW("Skipping pending action %d on display = %d.", pending_action.action, display_id); pending_action.action = kNoAction; } int32_t action = pending_action.action; int count = -1; while (action > 0) { count++; int32_t bit = (action & 1); action = action >> 1; if (!bit) continue; DLOGV_IF(kTagQDCM, "pending action = %d", BITMAP(count)); switch (BITMAP(count)) { case kInvalidating: Refresh(HWC_DISPLAY_PRIMARY); break; case kEnterQDCMMode: ret = color_mgr_->EnableQDCMMode(true, hwc_display_[HWC_DISPLAY_PRIMARY]); break; case kExitQDCMMode: ret = color_mgr_->EnableQDCMMode(false, hwc_display_[HWC_DISPLAY_PRIMARY]); break; case kApplySolidFill: { SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); ret = color_mgr_->SetSolidFill(pending_action.params, true, hwc_display_[HWC_DISPLAY_PRIMARY]); } Refresh(HWC_DISPLAY_PRIMARY); usleep(kSolidFillDelay); break; case kDisableSolidFill: { SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); ret = color_mgr_->SetSolidFill(pending_action.params, false, hwc_display_[HWC_DISPLAY_PRIMARY]); } Refresh(HWC_DISPLAY_PRIMARY); usleep(kSolidFillDelay); break; case kSetPanelBrightness: brightness_value = reinterpret_cast(resp_payload.payload); if (brightness_value == NULL) { DLOGE("Brightness value is Null"); ret = -EINVAL; } else { ret = hwc_display_[HWC_DISPLAY_PRIMARY]->SetPanelBrightness(*brightness_value); } break; case kEnableFrameCapture: ret = color_mgr_->SetFrameCapture(pending_action.params, true, hwc_display_[HWC_DISPLAY_PRIMARY]); Refresh(HWC_DISPLAY_PRIMARY); break; case kDisableFrameCapture: ret = color_mgr_->SetFrameCapture(pending_action.params, false, hwc_display_[HWC_DISPLAY_PRIMARY]); break; case kConfigureDetailedEnhancer: ret = color_mgr_->SetDetailedEnhancer(pending_action.params, hwc_display_[HWC_DISPLAY_PRIMARY]); Refresh(HWC_DISPLAY_PRIMARY); break; case kModeSet: ret = static_cast (hwc_display_[HWC_DISPLAY_PRIMARY]->RestoreColorTransform()); Refresh(HWC_DISPLAY_PRIMARY); break; case kNoAction: break; default: DLOGW("Invalid pending action = %d!", pending_action.action); break; } } } // for display API getter case, marshall returned params into out_parcel. output_parcel->writeInt32(ret); HWCColorManager::MarshallStructIntoParcel(resp_payload, output_parcel); req_payload.DestroyPayload(); resp_payload.DestroyPayload(); hwc_display_[display_id]->ResetValidation(); return ret; } void HWCSession::UEventHandler(const char *uevent_data, int length) { if (strcasestr(uevent_data, HWC_UEVENT_SWITCH_HDMI)) { DLOGI("Uevent HDMI = %s", uevent_data); int connected = GetEventValue(uevent_data, length, "SWITCH_STATE="); if (connected >= 0) { DLOGI("HDMI = %s", connected ? "connected" : "disconnected"); if (HotPlugHandler(connected) == -1) { DLOGE("Failed handling Hotplug = %s", connected ? "connected" : "disconnected"); } } } else if (strcasestr(uevent_data, HWC_UEVENT_GRAPHICS_FB0)) { DLOGI("Uevent FB0 = %s", uevent_data); int panel_reset = GetEventValue(uevent_data, length, "PANEL_ALIVE="); if (panel_reset == 0) { Refresh(0); reset_panel_ = true; } } else if (strcasestr(uevent_data, HWC_UEVENT_DRM_EXT_HOTPLUG)) { HandleExtHPD(uevent_data, length); } } const char *GetTokenValue(const char *uevent_data, int length, const char *token) { const char *iterator_str = uevent_data; const char *pstr = NULL; while (((iterator_str - uevent_data) <= length) && (*iterator_str)) { pstr = strstr(iterator_str, token); if (pstr) { break; } iterator_str += strlen(iterator_str) + 1; } if (pstr) pstr = pstr+strlen(token); return pstr; } void HWCSession::HandleExtHPD(const char *uevent_data, int length) { const char *pstr = GetTokenValue(uevent_data, length, "name="); if (!pstr || (strncmp(pstr, "DP-1", strlen("DP-1")) != 0)) { return; } pstr = GetTokenValue(uevent_data, length, "status="); if (pstr) { bool connected = false; hpd_bpp_ = 0; hpd_pattern_ = 0; if (strncmp(pstr, "connected", strlen("connected")) == 0) { connected = true; } int bpp = GetEventValue(uevent_data, length, "bpp="); int pattern = GetEventValue(uevent_data, length, "pattern="); if (bpp >=0 && pattern >= 0) { hpd_bpp_ = bpp; hpd_pattern_ = pattern; } DLOGI("Recived Ext HPD, connected:%d status=%s bpp = %d pattern =%d ", connected, pstr, hpd_bpp_, hpd_pattern_); HotPlugHandler(connected); } } int HWCSession::GetEventValue(const char *uevent_data, int length, const char *event_info) { const char *iterator_str = uevent_data; while (((iterator_str - uevent_data) <= length) && (*iterator_str)) { const char *pstr = strstr(iterator_str, event_info); if (pstr != NULL) { return (atoi(iterator_str + strlen(event_info))); } iterator_str += strlen(iterator_str) + 1; } return -1; } void HWCSession::ResetPanel() { HWC2::Error status; DLOGI("Powering off primary"); status = hwc_display_[HWC_DISPLAY_PRIMARY]->SetPowerMode(HWC2::PowerMode::Off); if (status != HWC2::Error::None) { DLOGE("power-off on primary failed with error = %d", status); } DLOGI("Restoring power mode on primary"); HWC2::PowerMode mode = hwc_display_[HWC_DISPLAY_PRIMARY]->GetLastPowerMode(); status = hwc_display_[HWC_DISPLAY_PRIMARY]->SetPowerMode(mode); if (status != HWC2::Error::None) { DLOGE("Setting power mode = %d on primary failed with error = %d", mode, status); } status = hwc_display_[HWC_DISPLAY_PRIMARY]->SetVsyncEnabled(HWC2::Vsync::Enable); if (status != HWC2::Error::None) { DLOGE("enabling vsync failed for primary with error = %d", status); } reset_panel_ = false; } int HWCSession::HotPlugHandler(bool connected) { int status = 0; bool notify_hotplug = false; // To prevent sending events to client while a lock is held, acquire scope locks only within // below scope so that those get automatically unlocked after the scope ends. do { // If HDMI is primary but not created yet (first time), create it and notify surfaceflinger. // if it is already created, but got disconnected/connected again, // just toggle display status and do not notify surfaceflinger. // If HDMI is not primary, create/destroy external display normally. if (hdmi_is_primary_) { SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); if (hwc_display_[HWC_DISPLAY_PRIMARY]) { status = hwc_display_[HWC_DISPLAY_PRIMARY]->SetState(connected); } else { status = CreateExternalDisplay(HWC_DISPLAY_PRIMARY, 0, 0, false); notify_hotplug = true; } break; } { SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); // Primary display must be connected for HDMI as secondary cases. if (!hwc_display_[HWC_DISPLAY_PRIMARY]) { DLOGE("Primary display is not connected."); return -1; } hwc_display_[HWC_DISPLAY_PRIMARY]->ResetValidation(); } if (connected) { SCOPE_LOCK(locker_[HWC_DISPLAY_EXTERNAL]); Locker::ScopeLock lock_v(locker_[HWC_DISPLAY_VIRTUAL]); // Connect external display if virtual display is not connected. // Else, defer external display connection and process it when virtual display // tears down; Do not notify SurfaceFlinger since connection is deferred now. if (!hwc_display_[HWC_DISPLAY_VIRTUAL]) { status = ConnectDisplay(HWC_DISPLAY_EXTERNAL); if (status) { return status; } notify_hotplug = true; } else { DLOGI("Virtual display is connected, pending connection"); external_pending_connect_ = true; } } else { SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_EXTERNAL]); if (hwc_display_[HWC_DISPLAY_EXTERNAL]) { notify_hotplug = true; } external_pending_connect_ = false; } } while (0); if (connected) { // In connect case, we send hotplug after we create display Refresh(0); if (!hdmi_is_primary_) { // wait for sufficient time to ensure sufficient resources are available to process new // new display connection. uint32_t vsync_period = UINT32(GetVsyncPeriod(HWC_DISPLAY_PRIMARY)); usleep(vsync_period * 2 / 1000); } if (notify_hotplug) { HotPlug(hdmi_is_primary_ ? HWC_DISPLAY_PRIMARY : HWC_DISPLAY_EXTERNAL, HWC2::Connection::Connected); } } else { // In disconnect case, we notify hotplug first to let the listener state update happen first // Then we can destroy the underlying display object if (notify_hotplug) { HotPlug(hdmi_is_primary_ ? HWC_DISPLAY_PRIMARY : HWC_DISPLAY_EXTERNAL, HWC2::Connection::Disconnected); } Refresh(0); if (!hdmi_is_primary_) { uint32_t vsync_period = UINT32(GetVsyncPeriod(HWC_DISPLAY_PRIMARY)); usleep(vsync_period * 2 / 1000); } // Now disconnect the display { SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_EXTERNAL]); // Do not return error if external display is not in connected status. // Due to virtual display concurrency, external display connection might be still pending // but hdmi got disconnected before pending connection could be processed. if (hwc_display_[HWC_DISPLAY_EXTERNAL]) { status = DisconnectDisplay(HWC_DISPLAY_EXTERNAL); } } } // notify client qservice_->onHdmiHotplug(INT(connected)); return 0; } int HWCSession::GetVsyncPeriod(int disp) { SCOPE_LOCK(locker_[disp]); // default value int32_t vsync_period = 1000000000l / 60; auto attribute = HWC2::Attribute::VsyncPeriod; if (hwc_display_[disp]) { hwc_display_[disp]->GetDisplayAttribute(0, attribute, &vsync_period); } return vsync_period; } android::status_t HWCSession::GetVisibleDisplayRect(const android::Parcel *input_parcel, android::Parcel *output_parcel) { int dpy = input_parcel->readInt32(); if (dpy < HWC_DISPLAY_PRIMARY || dpy >= HWC_NUM_DISPLAY_TYPES) { return android::BAD_VALUE; } SEQUENCE_WAIT_SCOPE_LOCK(locker_[dpy]); if (!hwc_display_[dpy]) { return android::NO_INIT; } hwc_rect_t visible_rect = {0, 0, 0, 0}; int error = hwc_display_[dpy]->GetVisibleDisplayRect(&visible_rect); if (error < 0) { return error; } output_parcel->writeInt32(visible_rect.left); output_parcel->writeInt32(visible_rect.top); output_parcel->writeInt32(visible_rect.right); output_parcel->writeInt32(visible_rect.bottom); return android::NO_ERROR; } void HWCSession::Refresh(hwc2_display_t display) { SCOPE_LOCK(callbacks_lock_); HWC2::Error err = callbacks_.Refresh(display); while (err != HWC2::Error::None) { callbacks_lock_.Wait(); err = callbacks_.Refresh(display); } } void HWCSession::HotPlug(hwc2_display_t display, HWC2::Connection state) { SCOPE_LOCK(callbacks_lock_); HWC2::Error err = callbacks_.Hotplug(display, state); while (err != HWC2::Error::None) { callbacks_lock_.Wait(); err = callbacks_.Hotplug(display, state); } } int HWCSession::CreateExternalDisplay(int disp_id, uint32_t primary_width, uint32_t primary_height, bool use_primary_res) { uint32_t panel_bpp = 0; uint32_t pattern_type = 0; if (GetDriverType() == DriverType::FB) { qdutils::getDPTestConfig(&panel_bpp, &pattern_type); } else { panel_bpp = static_cast(hpd_bpp_); pattern_type = static_cast(hpd_pattern_); } if (panel_bpp && pattern_type) { return HWCDisplayExternalTest::Create(core_intf_, &buffer_allocator_, &callbacks_, qservice_, panel_bpp, pattern_type, &hwc_display_[disp_id]); } return HWCDisplayExternal::Create(core_intf_, &buffer_allocator_, &callbacks_, primary_width, primary_height, qservice_, use_primary_res, &hwc_display_[disp_id]); } HWC2::Error HWCSession::ValidateDisplayInternal(hwc2_display_t display, uint32_t *out_num_types, uint32_t *out_num_requests) { HWCDisplay *hwc_display = hwc_display_[display]; if (hwc_display->IsInternalValidateState()) { // Internal Validation has already been done on display, get the Output params. return hwc_display->GetValidateDisplayOutput(out_num_types, out_num_requests); } if (display == HWC_DISPLAY_PRIMARY) { // TODO(user): This can be moved to HWCDisplayPrimary if (reset_panel_) { DLOGW("panel is in bad state, resetting the panel"); ResetPanel(); } if (need_invalidate_) { Refresh(display); need_invalidate_ = false; } if (color_mgr_) { color_mgr_->SetColorModeDetailEnhancer(hwc_display_[display]); } } return hwc_display->Validate(out_num_types, out_num_requests); } HWC2::Error HWCSession::PresentDisplayInternal(hwc2_display_t display, int32_t *out_retire_fence) { HWCDisplay *hwc_display = hwc_display_[display]; // If display is in Skip-Validate state and Validate cannot be skipped, do Internal // Validation to optimize for the frames which don't require the Client composition. if (hwc_display->IsSkipValidateState() && !hwc_display->CanSkipValidate()) { uint32_t out_num_types = 0, out_num_requests = 0; HWC2::Error error = ValidateDisplayInternal(display, &out_num_types, &out_num_requests); if ((error != HWC2::Error::None) || hwc_display->HasClientComposition()) { hwc_display->SetValidationState(HWCDisplay::kInternalValidate); return HWC2::Error::NotValidated; } } return hwc_display->Present(out_retire_fence); } int32_t HWCSession::GetReadbackBufferAttributes(hwc2_device_t *device, hwc2_display_t display, int32_t *format, int32_t *dataspace) { if (!device || !format || !dataspace) { return HWC2_ERROR_BAD_PARAMETER; } if (display != HWC_DISPLAY_PRIMARY) { return HWC2_ERROR_BAD_DISPLAY; } HWCSession *hwc_session = static_cast(device); HWCDisplay *hwc_display = hwc_session->hwc_display_[display]; if (hwc_display) { *format = HAL_PIXEL_FORMAT_RGB_888; *dataspace = GetDataspace(hwc_display->GetCurrentColorMode()); return HWC2_ERROR_NONE; } return HWC2_ERROR_BAD_DISPLAY; } int32_t HWCSession::SetReadbackBuffer(hwc2_device_t *device, hwc2_display_t display, const native_handle_t *buffer, int32_t acquire_fence) { if (!buffer) { return HWC2_ERROR_BAD_PARAMETER; } if (display != HWC_DISPLAY_PRIMARY) { return HWC2_ERROR_BAD_DISPLAY; } HWCSession *hwc_session = static_cast(device); if (hwc_session->hwc_display_[HWC_DISPLAY_EXTERNAL] || hwc_session->hwc_display_[HWC_DISPLAY_VIRTUAL]) { return HWC2_ERROR_UNSUPPORTED; } return CallDisplayFunction(device, display, &HWCDisplay::SetReadbackBuffer, buffer, acquire_fence, false); } int32_t HWCSession::GetReadbackBufferFence(hwc2_device_t *device, hwc2_display_t display, int32_t *release_fence) { if (!release_fence) { return HWC2_ERROR_BAD_PARAMETER; } if (display != HWC_DISPLAY_PRIMARY) { return HWC2_ERROR_BAD_DISPLAY; } return CallDisplayFunction(device, display, &HWCDisplay::GetReadbackBufferFence, release_fence); } android::status_t HWCSession::SetIdlePC(const android::Parcel *input_parcel) { auto enable = input_parcel->readInt32(); auto synchronous = input_parcel->readInt32(); #ifdef DISPLAY_CONFIG_1_3 return static_cast(controlIdlePowerCollapse(enable, synchronous)); #else { SEQUENCE_WAIT_SCOPE_LOCK(locker_[HWC_DISPLAY_PRIMARY]); if (hwc_display_[HWC_DISPLAY_PRIMARY]) { DLOGE("Primary display is not ready"); return -EINVAL; } auto error = hwc_display_[HWC_DISPLAY_PRIMARY]->ControlIdlePowerCollapse(enable, synchronous); if (error != HWC2::Error::None) { return -EINVAL; } if (!enable) { Refresh(HWC_DISPLAY_PRIMARY); int32_t error = locker_[HWC_DISPLAY_PRIMARY].WaitFinite(kCommitDoneTimeoutMs); if (error == ETIMEDOUT) { DLOGE("Timed out!! Next frame commit done event not received!!"); return error; } } DLOGI("Idle PC %s!!", enable ? "enabled" : "disabled"); } return 0; #endif } } // namespace sdm