/* * 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 "hwc_display.h" #include "hwc_debugger.h" #include "hwc_tonemapper.h" #include "hwc_session.h" #ifdef QTI_BSP #include #endif #define __CLASS__ "HWCDisplay" namespace sdm { HWCColorMode::HWCColorMode(DisplayInterface *display_intf) : display_intf_(display_intf) {} HWC2::Error HWCColorMode::Init() { PopulateColorModes(); InitColorCompensation(); return ApplyDefaultColorMode(); } HWC2::Error HWCColorMode::DeInit() { color_mode_map_.clear(); return HWC2::Error::None; } uint32_t HWCColorMode::GetColorModeCount() { uint32_t count = UINT32(color_mode_map_.size()); DLOGI("Supported color mode count = %d", count); return std::max(1U, count); } uint32_t HWCColorMode::GetRenderIntentCount(ColorMode mode) { uint32_t count = UINT32(color_mode_map_[mode].size()); DLOGI("mode: %d supported rendering intent count = %d", mode, count); return std::max(1U, count); } HWC2::Error HWCColorMode::GetColorModes(uint32_t *out_num_modes, ColorMode *out_modes) { auto it = color_mode_map_.begin(); *out_num_modes = std::min(*out_num_modes, UINT32(color_mode_map_.size())); for (uint32_t i = 0; i < *out_num_modes; it++, i++) { out_modes[i] = it->first; } return HWC2::Error::None; } HWC2::Error HWCColorMode::GetRenderIntents(ColorMode mode, uint32_t *out_num_intents, RenderIntent *out_intents) { if (color_mode_map_.find(mode) == color_mode_map_.end()) { return HWC2::Error::BadParameter; } auto it = color_mode_map_[mode].begin(); *out_num_intents = std::min(*out_num_intents, UINT32(color_mode_map_[mode].size())); for (uint32_t i = 0; i < *out_num_intents; it++, i++) { out_intents[i] = it->first; } return HWC2::Error::None; } HWC2::Error HWCColorMode::SetColorModeWithRenderIntent(ColorMode mode, RenderIntent intent) { DTRACE_SCOPED(); if (mode < ColorMode::NATIVE || mode > ColorMode::BT2100_HLG) { DLOGE("Could not find mode: %d", mode); return HWC2::Error::BadParameter; } if (color_mode_map_.find(mode) == color_mode_map_.end()) { return HWC2::Error::Unsupported; } if (color_mode_map_[mode].find(intent) == color_mode_map_[mode].end()) { return HWC2::Error::Unsupported; } if (current_color_mode_ == mode && current_render_intent_ == intent) { return HWC2::Error::None; } auto mode_string = color_mode_map_[mode][intent]; DisplayError error = display_intf_->SetColorMode(mode_string); if (error != kErrorNone) { DLOGE("failed for mode = %d intent = %d name = %s", mode, intent, mode_string.c_str()); return HWC2::Error::Unsupported; } current_color_mode_ = mode; current_render_intent_ = intent; // The mode does not have the PCC configured, restore the transform RestoreColorTransform(); DLOGV_IF(kTagClient, "Successfully applied mode = %d intent = %d name = %s", mode, intent, mode_string.c_str()); return HWC2::Error::None; } HWC2::Error HWCColorMode::SetColorModeById(int32_t color_mode_id) { DLOGI("Applying mode: %d", color_mode_id); DisplayError error = display_intf_->SetColorModeById(color_mode_id); if (error != kErrorNone) { DLOGI_IF(kTagClient, "Failed to apply mode: %d", color_mode_id); return HWC2::Error::BadParameter; } return HWC2::Error::None; } HWC2::Error HWCColorMode::RestoreColorTransform() { DisplayError error = display_intf_->SetColorTransform(kColorTransformMatrixCount, PickTransferMatrix()); if (error != kErrorNone) { DLOGE("Failed to set Color Transform"); return HWC2::Error::BadParameter; } return HWC2::Error::None; } void HWCColorMode::InitColorCompensation() { char value[kPropertyMax] = {0}; if (Debug::Get()->GetProperty(ADAPTIVE_WHITE_COEFFICIENT_PROP, value) == kErrorNone) { adaptive_white_ = std::make_unique(string(value)); adaptive_white_->SetEnabled(true); } std::memset(value, 0, sizeof(value)); if (Debug::Get()->GetProperty(ADAPTIVE_SATURATION_PARAMETER_PROP, value) == kErrorNone) { adaptive_saturation_ = std::make_unique(string(value)); adaptive_saturation_->SetEnabled(true); } } const double *HWCColorMode::PickTransferMatrix() { double matrix[kColorTransformMatrixCount] = {0}; if (current_render_intent_ == RenderIntent::ENHANCE) { CopyColorTransformMatrix(color_matrix_, matrix); if (HasSaturationCompensation()) adaptive_saturation_->ApplyToMatrix(matrix); if (HasWhiteCompensation()) adaptive_white_->ApplyToMatrix(matrix); CopyColorTransformMatrix(matrix, compensated_color_matrix_); return compensated_color_matrix_; } else { return color_matrix_; } } HWC2::Error HWCColorMode::SetWhiteCompensation(bool enabled) { if (adaptive_white_ == NULL) return HWC2::Error::Unsupported; if (adaptive_white_->SetEnabled(enabled) != HWC2::Error::None) { return HWC2::Error::NotValidated; } RestoreColorTransform(); DLOGI("Set White Compensation: %d", enabled); return HWC2::Error::None; } HWC2::Error HWCColorMatrix::SetEnabled(bool enabled) { enabled_ = enabled; return HWC2::Error::None; } bool HWCColorMatrix::ParseFloatValueByCommas(const string &values, uint32_t length, std::vector &elements) const { std::istringstream data_stream(values); string data; uint32_t index = 0; std::vector temp_elements; while (std::getline(data_stream, data, ',')) { temp_elements.push_back(std::move(std::stof(data.c_str()))); index++; } if (index != length) { DLOGW("Insufficient elements defined"); return false; } std::move(temp_elements.begin(), temp_elements.end(), elements.begin()); return true; } HWC2::Error WhiteCompensation::SetEnabled(bool enabled) { // re-parse data when set enabled for retry calibration if (enabled) { if (!ConfigCoefficients() || !ParseWhitePointCalibrationData()) { enabled_ = false; DLOGE("Failed to WhiteCompensation Set"); return HWC2::Error::NotValidated; } CalculateRGBRatio(); } enabled_ = enabled; return HWC2::Error::None; } bool WhiteCompensation::ParseWhitePointCalibrationData() { static constexpr char kWhitePointCalibrationDataPath[] = "/persist/display/calibrated_rgb"; FILE *fp = fopen(kWhitePointCalibrationDataPath, "r"); int ret; if (!fp) { DLOGW("Failed to open white point calibration data file"); return false; } ret = fscanf(fp, "%d %d %d", &compensated_red_, &compensated_green_, &compensated_blue_); fclose(fp); if ((ret == kNumOfCompensationData) && CheckCompensatedRGB(compensated_red_) && CheckCompensatedRGB(compensated_green_) && CheckCompensatedRGB(compensated_blue_)) { DLOGD("Compensated RGB: %d %d %d", compensated_red_, compensated_green_, compensated_blue_); return true; } else { compensated_red_ = kCompensatedMaxRGB; compensated_green_ = kCompensatedMaxRGB; compensated_blue_ = kCompensatedMaxRGB; DLOGE("Wrong white compensated value"); return false; } } bool WhiteCompensation::ConfigCoefficients() { std::vector CompensatedCoefficients(kCoefficientElements); if (!ParseFloatValueByCommas(key_values_, kCoefficientElements, CompensatedCoefficients)) return false; std::move(CompensatedCoefficients.begin(), CompensatedCoefficients.end(), white_compensated_Coefficients_); for (const auto &c : white_compensated_Coefficients_) { DLOGD("white_compensated_Coefficients_=%f", c); } return true; } void WhiteCompensation::CalculateRGBRatio() { // r = r_coeffient2 * R^2 + r_coeffient1 * R + r_coeffient0 // g = g_coeffient2 * G^2 + g_coeffient1 * G + g_coeffient0 // b = b_coeffient2 * B^2 + b_coeffient1 * B + b_coeffient0 // r_ratio = r/kCompensatedMaxRGB // g_ratio = g/kCompensatedMaxRGB // b_ratio = b/kCompensatedMaxRGB auto rgb_ratio = [=](int rgb, float c2, float c1, float c0) { float frgb = FLOAT(rgb); return ((c2 * frgb * frgb + c1 * frgb + c0) / kCompensatedMaxRGB); }; compensated_red_ratio_ = rgb_ratio(compensated_red_, white_compensated_Coefficients_[0], white_compensated_Coefficients_[1], white_compensated_Coefficients_[2]); compensated_green_ratio_ = rgb_ratio(compensated_green_, white_compensated_Coefficients_[3], white_compensated_Coefficients_[4], white_compensated_Coefficients_[5]); compensated_blue_ratio_ = rgb_ratio(compensated_blue_, white_compensated_Coefficients_[6], white_compensated_Coefficients_[7], white_compensated_Coefficients_[8]); DLOGI("Compensated ratio %f %f %f", compensated_red_ratio_, compensated_green_ratio_, compensated_blue_ratio_); } void WhiteCompensation::ApplyToMatrix(double *in) { double matrix[kColorTransformMatrixCount] = {0}; for (uint32_t i = 0; i < kColorTransformMatrixCount; i++) { if ((i % 4) == 0) matrix[i] = compensated_red_ratio_ * in[i]; else if ((i % 4) == 1) matrix[i] = compensated_green_ratio_ * in[i]; else if ((i % 4) == 2) matrix[i] = compensated_blue_ratio_ * in[i]; else if ((i % 4) == 3) matrix[i] = in[i]; } std::move(&matrix[0], &matrix[kColorTransformMatrixCount - 1], in); } HWC2::Error SaturationCompensation::SetEnabled(bool enabled) { if (enabled == enabled_) return HWC2::Error::None; if (enabled) { if (!ConfigSaturationParameter()) { enabled_ = false; return HWC2::Error::NotValidated; } } enabled_ = enabled; return HWC2::Error::None; } bool SaturationCompensation::ConfigSaturationParameter() { std::vector SaturationParameter(kSaturationParameters); if (!ParseFloatValueByCommas(key_values_, kSaturationParameters, SaturationParameter)) return false; int32_t matrix_index = 0; for (uint32_t i = 0; i < SaturationParameter.size(); i++) { saturated_matrix_[matrix_index] = SaturationParameter.at(i); // Put parameters to matrix and keep the last row/column identity if ((i + 1) % 3 == 0) { matrix_index += 2; } else { matrix_index++; } DLOGD("SaturationParameter[%d]=%f", i, SaturationParameter.at(i)); } return true; } void SaturationCompensation::ApplyToMatrix(double *in) { double matrix[kColorTransformMatrixCount] = {0}; // 4 x 4 matrix multiplication for (uint32_t i = 0; i < kNumOfRows; i++) { for (uint32_t j = 0; j < kColumnsPerRow; j++) { for (uint32_t k = 0; k < kColumnsPerRow; k++) { matrix[j + (i * kColumnsPerRow)] += saturated_matrix_[k + (i * kColumnsPerRow)] * in[j + (k * kColumnsPerRow)]; } } } std::move(&matrix[0], &matrix[kColorTransformMatrixCount - 1], in); } HWC2::Error HWCColorMode::SetColorTransform(const float *matrix, android_color_transform_t /*hint*/) { DTRACE_SCOPED(); auto status = HWC2::Error::None; double color_matrix_restore[kColorTransformMatrixCount] = {0}; CopyColorTransformMatrix(color_matrix_, color_matrix_restore); CopyColorTransformMatrix(matrix, color_matrix_); DisplayError error = display_intf_->SetColorTransform(kColorTransformMatrixCount, PickTransferMatrix()); if (error != kErrorNone) { CopyColorTransformMatrix(color_matrix_restore, color_matrix_); DLOGE("Failed to set Color Transform Matrix"); status = HWC2::Error::Unsupported; } return status; } void HWCColorMode::FindRenderIntent(const ColorMode &mode, const std::string &mode_string) { auto intent = RenderIntent::COLORIMETRIC; if (mode_string.find("enhanced") != std::string::npos) { intent = RenderIntent::ENHANCE; } color_mode_map_[mode][intent] = mode_string; } void HWCColorMode::PopulateColorModes() { uint32_t color_mode_count = 0; // SDM returns modes which have attributes defining mode and rendering intent DisplayError error = display_intf_->GetColorModeCount(&color_mode_count); if (error != kErrorNone || (color_mode_count == 0)) { DLOGW("GetColorModeCount failed, use native color mode"); color_mode_map_[ColorMode::NATIVE][RenderIntent::COLORIMETRIC] = "hal_native_identity"; return; } DLOGV_IF(kTagClient, "Color Modes supported count = %d", color_mode_count); std::vector color_modes(color_mode_count); error = display_intf_->GetColorModes(&color_mode_count, &color_modes); for (uint32_t i = 0; i < color_mode_count; i++) { std::string &mode_string = color_modes.at(i); DLOGV_IF(kTagClient, "Color Mode[%d] = %s", i, mode_string.c_str()); AttrVal attr; error = display_intf_->GetColorModeAttr(mode_string, &attr); std::string color_gamut = kNative, dynamic_range = kSdr, pic_quality = kStandard; if (!attr.empty()) { for (auto &it : attr) { if (it.first.find(kColorGamutAttribute) != std::string::npos) { color_gamut = it.second; } else if (it.first.find(kDynamicRangeAttribute) != std::string::npos) { dynamic_range = it.second; } else if (it.first.find(kPictureQualityAttribute) != std::string::npos) { pic_quality = it.second; } } DLOGV_IF(kTagClient, "color_gamut : %s, dynamic_range : %s, pic_quality : %s", color_gamut.c_str(), dynamic_range.c_str(), pic_quality.c_str()); if (color_gamut == kNative) { color_mode_map_[ColorMode::NATIVE][RenderIntent::COLORIMETRIC] = mode_string; } if (color_gamut == kSrgb && dynamic_range == kSdr) { if (pic_quality == kStandard) { color_mode_map_[ColorMode::SRGB][RenderIntent::COLORIMETRIC] = mode_string; } if (pic_quality == kEnhanced) { color_mode_map_[ColorMode::SRGB][RenderIntent::ENHANCE] = mode_string; } } if (color_gamut == kDcip3 && dynamic_range == kSdr) { if (pic_quality == kStandard) { color_mode_map_[ColorMode::DISPLAY_P3][RenderIntent::COLORIMETRIC] = mode_string; } if (pic_quality == kEnhanced) { color_mode_map_[ColorMode::DISPLAY_P3][RenderIntent::ENHANCE] = mode_string; } } if (pic_quality == kStandard && dynamic_range == kHdr) { color_mode_map_[ColorMode::BT2100_PQ][RenderIntent::TONE_MAP_COLORIMETRIC] = mode_string; color_mode_map_[ColorMode::BT2100_HLG][RenderIntent::TONE_MAP_COLORIMETRIC] = mode_string; } } else { // Look at the mode names, if no attributes are found if (mode_string.find("hal_native") != std::string::npos) { color_mode_map_[ColorMode::NATIVE][RenderIntent::COLORIMETRIC] = mode_string; } } } } HWC2::Error HWCColorMode::ApplyDefaultColorMode() { auto color_mode = ColorMode::NATIVE; if (color_mode_map_.size() == 1U) { color_mode = color_mode_map_.begin()->first; } else if (color_mode_map_.size() > 1U) { std::string default_color_mode; bool found = false; DisplayError error = display_intf_->GetDefaultColorMode(&default_color_mode); if (error == kErrorNone) { // get the default mode corresponding android_color_mode_t for (auto &it_mode : color_mode_map_) { for (auto &it : it_mode.second) { if (it.second == default_color_mode) { found = true; break; } } if (found) { color_mode = it_mode.first; break; } } } // return the first color mode we encounter if not found if (!found) { color_mode = color_mode_map_.begin()->first; } } return SetColorModeWithRenderIntent(color_mode, RenderIntent::COLORIMETRIC); } PrimariesTransfer HWCColorMode::GetWorkingColorSpace() { ColorPrimaries primaries = ColorPrimaries_BT709_5; GammaTransfer transfer = Transfer_sRGB; switch (current_color_mode_) { case ColorMode::BT2100_PQ: primaries = ColorPrimaries_BT2020; transfer = Transfer_SMPTE_ST2084; break; case ColorMode::BT2100_HLG: primaries = ColorPrimaries_BT2020; transfer = Transfer_HLG; break; case ColorMode::DISPLAY_P3: primaries = ColorPrimaries_DCIP3; transfer = Transfer_sRGB; break; case ColorMode::NATIVE: case ColorMode::SRGB: break; default: DLOGW("Invalid color mode: %d", current_color_mode_); break; } return std::make_pair(primaries, transfer); } void HWCColorMode::Dump(std::ostringstream* os) { *os << "color modes supported: \n"; for (auto it : color_mode_map_) { *os << "mode: " << static_cast(it.first) << " RIs { "; for (auto rit : color_mode_map_[it.first]) { *os << static_cast(rit.first) << " "; } *os << "} \n"; } *os << "current mode: " << static_cast(current_color_mode_) << std::endl; *os << "current render_intent: " << static_cast(current_render_intent_) << std::endl; *os << "Need WhiteCompensation: " << (current_render_intent_ == RenderIntent::ENHANCE && HasWhiteCompensation()) << std::endl; *os << "Need SaturationCompensation: " << (current_render_intent_ == RenderIntent::ENHANCE && HasSaturationCompensation()) << std::endl; *os << "current transform: "; double color_matrix[kColorTransformMatrixCount] = {0}; CopyColorTransformMatrix(PickTransferMatrix(), color_matrix); for (uint32_t i = 0; i < kColorTransformMatrixCount; i++) { if (i % 4 == 0) { *os << std::endl; } *os << std::fixed << std::setprecision(4) << std::setw(8) << std::setfill(' ') << color_matrix[i] << " "; } *os << std::endl; } HWCDisplay::HWCDisplay(CoreInterface *core_intf, HWCCallbacks *callbacks, DisplayType type, hwc2_display_t id, bool needs_blit, qService::QService *qservice, DisplayClass display_class, BufferAllocator *buffer_allocator) : core_intf_(core_intf), callbacks_(callbacks), type_(type), id_(id), needs_blit_(needs_blit), qservice_(qservice), display_class_(display_class) { buffer_allocator_ = static_cast(buffer_allocator); } int HWCDisplay::Init() { DisplayError error = core_intf_->CreateDisplay(type_, this, &display_intf_); if (error != kErrorNone) { DLOGE("Display create failed. Error = %d display_type %d event_handler %p disp_intf %p", error, type_, this, &display_intf_); return -EINVAL; } validated_ = false; HWCDebugHandler::Get()->GetProperty(DISABLE_HDR, &disable_hdr_handling_); if (disable_hdr_handling_) { DLOGI("HDR Handling disabled"); } int property_swap_interval = 1; HWCDebugHandler::Get()->GetProperty("debug.egl.swapinterval", &property_swap_interval); if (property_swap_interval == 0) { swap_interval_zero_ = true; } client_target_ = new HWCLayer(id_, buffer_allocator_); int blit_enabled = 0; HWCDebugHandler::Get()->GetProperty(DISABLE_BLIT_COMPOSITION_PROP, &blit_enabled); if (needs_blit_ && blit_enabled) { // TODO(user): Add blit engine when needed } error = display_intf_->GetNumVariableInfoConfigs(&num_configs_); if (error != kErrorNone) { DLOGE("Getting config count failed. Error = %d", error); return -EINVAL; } display_intf_->GetRefreshRateRange(&min_refresh_rate_, &max_refresh_rate_); current_refresh_rate_ = max_refresh_rate_; GetUnderScanConfig(); DisplayConfigFixedInfo fixed_info = {}; display_intf_->GetConfig(&fixed_info); partial_update_enabled_ = fixed_info.partial_update || (!fixed_info.is_cmdmode); client_target_->SetPartialUpdate(partial_update_enabled_); DLOGI("Display created with id: %d", id_); return 0; } int HWCDisplay::Deinit() { DisplayError error = core_intf_->DestroyDisplay(display_intf_); if (error != kErrorNone) { DLOGE("Display destroy failed. Error = %d", error); return -EINVAL; } delete client_target_; for (auto hwc_layer : layer_set_) { delete hwc_layer; } if (color_mode_) { color_mode_->DeInit(); delete color_mode_; } return 0; } // LayerStack operations HWC2::Error HWCDisplay::CreateLayer(hwc2_layer_t *out_layer_id) { HWCLayer *layer = *layer_set_.emplace(new HWCLayer(id_, buffer_allocator_)); layer_map_.emplace(std::make_pair(layer->GetId(), layer)); *out_layer_id = layer->GetId(); geometry_changes_ |= GeometryChanges::kAdded; validated_ = false; layer_stack_invalid_ = true; layer->SetPartialUpdate(partial_update_enabled_); return HWC2::Error::None; } HWCLayer *HWCDisplay::GetHWCLayer(hwc2_layer_t layer_id) { const auto map_layer = layer_map_.find(layer_id); if (map_layer == layer_map_.end()) { DLOGE("[%" PRIu64 "] GetLayer(%" PRIu64 ") failed: no such layer", id_, layer_id); return nullptr; } else { return map_layer->second; } } HWC2::Error HWCDisplay::DestroyLayer(hwc2_layer_t layer_id) { const auto map_layer = layer_map_.find(layer_id); if (map_layer == layer_map_.end()) { DLOGE("[%" PRIu64 "] destroyLayer(%" PRIu64 ") failed: no such layer", id_, layer_id); return HWC2::Error::BadLayer; } const auto layer = map_layer->second; layer_map_.erase(map_layer); const auto z_range = layer_set_.equal_range(layer); for (auto current = z_range.first; current != z_range.second; ++current) { if (*current == layer) { current = layer_set_.erase(current); delete layer; break; } } geometry_changes_ |= GeometryChanges::kRemoved; validated_ = false; layer_stack_invalid_ = true; return HWC2::Error::None; } void HWCDisplay::BuildLayerStack() { layer_stack_ = LayerStack(); display_rect_ = LayerRect(); metadata_refresh_rate_ = 0; bool secure_display_active = false; layer_stack_.flags.animating = animating_; uint32_t color_mode_count = 0; display_intf_->GetColorModeCount(&color_mode_count); hdr_largest_layer_px_ = 0.0f; // Add one layer for fb target // TODO(user): Add blit target layers for (auto hwc_layer : layer_set_) { // Reset layer data which SDM may change hwc_layer->ResetPerFrameData(); Layer *layer = hwc_layer->GetSDMLayer(); layer->flags = {}; // Reset earlier flags if (hwc_layer->GetClientRequestedCompositionType() == HWC2::Composition::Client) { layer->flags.skip = true; } else if (hwc_layer->GetClientRequestedCompositionType() == HWC2::Composition::SolidColor) { layer->flags.solid_fill = true; } if (!hwc_layer->ValidateAndSetCSC()) { layer->flags.skip = true; } auto range = hwc_layer->GetLayerDataspace() & HAL_DATASPACE_RANGE_MASK; if (range == HAL_DATASPACE_RANGE_EXTENDED) { layer->flags.skip = true; } // set default composition as GPU for SDM layer->composition = kCompositionGPU; if (swap_interval_zero_) { if (layer->input_buffer.acquire_fence_fd >= 0) { close(layer->input_buffer.acquire_fence_fd); layer->input_buffer.acquire_fence_fd = -1; } } bool is_secure = false; bool is_video = false; const private_handle_t *handle = reinterpret_cast(layer->input_buffer.buffer_id); if (handle) { if (handle->buffer_type == BUFFER_TYPE_VIDEO) { layer_stack_.flags.video_present = true; is_video = true; } else if (layer->transform.rotation != 0.0f) { layer->flags.skip = true; } // TZ Protected Buffer - L1 // Gralloc Usage Protected Buffer - L3 - which needs to be treated as Secure & avoid fallback if (handle->flags & private_handle_t::PRIV_FLAGS_PROTECTED_BUFFER || handle->flags & private_handle_t::PRIV_FLAGS_SECURE_BUFFER) { layer_stack_.flags.secure_present = true; is_secure = true; } } if (layer->input_buffer.flags.secure_display) { secure_display_active = true; is_secure = true; } if (hwc_layer->IsSingleBuffered() && !(hwc_layer->IsRotationPresent() || hwc_layer->IsScalingPresent())) { layer->flags.single_buffer = true; layer_stack_.flags.single_buffered_layer_present = true; } if (hwc_layer->GetClientRequestedCompositionType() == HWC2::Composition::Cursor) { // Currently we support only one HWCursor & only at top most z-order if ((*layer_set_.rbegin())->GetId() == hwc_layer->GetId()) { layer->flags.cursor = true; layer_stack_.flags.cursor_present = true; } } bool hdr_layer = layer->input_buffer.color_metadata.colorPrimaries == ColorPrimaries_BT2020 && (layer->input_buffer.color_metadata.transfer == Transfer_SMPTE_ST2084 || layer->input_buffer.color_metadata.transfer == Transfer_HLG); if (hdr_layer && !disable_hdr_handling_ && current_color_mode_ != ColorMode::NATIVE) { // Dont honor HDR when its handling is disabled // Also, when the color mode is native, it implies that // SF has not correctly set the mode to BT2100_PQ in the presence of an HDR layer // In such cases, we should not handle HDR as the HDR mode isn't applied layer->input_buffer.flags.hdr = true; layer_stack_.flags.hdr_present = true; // HDR area auto hdr_layer_area = (layer->dst_rect.right - layer->dst_rect.left) * (layer->dst_rect.bottom - layer->dst_rect.top); hdr_largest_layer_px_ = std::max(hdr_largest_layer_px_, hdr_layer_area); } if (hwc_layer->IsNonIntegralSourceCrop() && !is_secure && !layer->flags.solid_fill && !is_video) { layer->flags.skip = true; } if (layer->flags.skip) { layer_stack_.flags.skip_present = true; } // TODO(user): Move to a getter if this is needed at other places hwc_rect_t scaled_display_frame = {INT(layer->dst_rect.left), INT(layer->dst_rect.top), INT(layer->dst_rect.right), INT(layer->dst_rect.bottom)}; if (hwc_layer->GetGeometryChanges() & kDisplayFrame) { ApplyScanAdjustment(&scaled_display_frame); } hwc_layer->SetLayerDisplayFrame(scaled_display_frame); hwc_layer->ResetPerFrameData(); // SDM requires these details even for solid fill if (layer->flags.solid_fill) { LayerBuffer *layer_buffer = &layer->input_buffer; layer_buffer->width = UINT32(layer->dst_rect.right - layer->dst_rect.left); layer_buffer->height = UINT32(layer->dst_rect.bottom - layer->dst_rect.top); layer_buffer->unaligned_width = layer_buffer->width; layer_buffer->unaligned_height = layer_buffer->height; layer_buffer->acquire_fence_fd = -1; layer_buffer->release_fence_fd = -1; layer->src_rect.left = 0; layer->src_rect.top = 0; layer->src_rect.right = FLOAT(layer_buffer->width); layer->src_rect.bottom = FLOAT(layer_buffer->height); } if (hwc_layer->HasMetaDataRefreshRate() && layer->frame_rate > metadata_refresh_rate_) { metadata_refresh_rate_ = SanitizeRefreshRate(layer->frame_rate); } display_rect_ = Union(display_rect_, layer->dst_rect); geometry_changes_ |= hwc_layer->GetGeometryChanges(); layer->flags.updating = true; if (layer_set_.size() <= kMaxLayerCount) { layer->flags.updating = IsLayerUpdating(hwc_layer); } layer_stack_.layers.push_back(layer); } for (auto hwc_layer : layer_set_) { auto layer = hwc_layer->GetSDMLayer(); if (layer->input_buffer.color_metadata.colorPrimaries != working_primaries_ && !hwc_layer->SupportLocalConversion(working_primaries_)) { layer->flags.skip = true; } if (layer->flags.skip) { layer_stack_.flags.skip_present = true; } } // TODO(user): Set correctly when SDM supports geometry_changes as bitmask layer_stack_.flags.geometry_changed = UINT32(geometry_changes_ > 0); // Append client target to the layer stack Layer *sdm_client_target = client_target_->GetSDMLayer(); sdm_client_target->flags.updating = IsLayerUpdating(client_target_); layer_stack_.layers.push_back(sdm_client_target); // fall back frame composition to GPU when client target is 10bit // TODO(user): clarify the behaviour from Client(SF) and SDM Extn - // when handling 10bit FBT, as it would affect blending if (Is10BitFormat(sdm_client_target->input_buffer.format)) { // Must fall back to client composition MarkLayersForClientComposition(); } // set secure display SetSecureDisplay(secure_display_active); } void HWCDisplay::BuildSolidFillStack() { layer_stack_ = LayerStack(); display_rect_ = LayerRect(); layer_stack_.layers.push_back(solid_fill_layer_); layer_stack_.flags.geometry_changed = 1U; // Append client target to the layer stack layer_stack_.layers.push_back(client_target_->GetSDMLayer()); } HWC2::Error HWCDisplay::SetLayerZOrder(hwc2_layer_t layer_id, uint32_t z) { const auto map_layer = layer_map_.find(layer_id); if (map_layer == layer_map_.end()) { DLOGE("[%" PRIu64 "] updateLayerZ failed to find layer", id_); return HWC2::Error::BadLayer; } const auto layer = map_layer->second; const auto z_range = layer_set_.equal_range(layer); bool layer_on_display = false; for (auto current = z_range.first; current != z_range.second; ++current) { if (*current == layer) { if ((*current)->GetZ() == z) { // Don't change anything if the Z hasn't changed return HWC2::Error::None; } current = layer_set_.erase(current); layer_on_display = true; break; } } if (!layer_on_display) { DLOGE("[%" PRIu64 "] updateLayerZ failed to find layer on display", id_); return HWC2::Error::BadLayer; } layer->SetLayerZOrder(z); layer_set_.emplace(layer); return HWC2::Error::None; } HWC2::Error HWCDisplay::SetVsyncEnabled(HWC2::Vsync enabled) { DLOGV("Display ID: %d enabled: %s", id_, to_string(enabled).c_str()); ATRACE_INT("SetVsyncState ", enabled == HWC2::Vsync::Enable ? 1 : 0); DisplayError error = kErrorNone; if (shutdown_pending_ || !callbacks_->VsyncCallbackRegistered()) { return HWC2::Error::None; } bool state; if (enabled == HWC2::Vsync::Enable) state = true; else if (enabled == HWC2::Vsync::Disable) state = false; else return HWC2::Error::BadParameter; error = display_intf_->SetVSyncState(state); if (error != kErrorNone) { if (error == kErrorShutDown) { shutdown_pending_ = true; return HWC2::Error::None; } DLOGE("Failed. enabled = %s, error = %d", to_string(enabled).c_str(), error); return HWC2::Error::BadDisplay; } return HWC2::Error::None; } HWC2::Error HWCDisplay::SetPowerMode(HWC2::PowerMode mode) { DLOGV("display = %d, mode = %s", id_, to_string(mode).c_str()); DisplayState state = kStateOff; bool flush_on_error = flush_on_error_; if (shutdown_pending_) { return HWC2::Error::None; } switch (mode) { case HWC2::PowerMode::Off: // During power off, all of the buffers are released. // Do not flush until a buffer is successfully submitted again. flush_on_error = false; state = kStateOff; if (tone_mapper_) { tone_mapper_->Terminate(); } break; case HWC2::PowerMode::On: state = kStateOn; last_power_mode_ = HWC2::PowerMode::On; break; case HWC2::PowerMode::Doze: state = kStateDoze; last_power_mode_ = HWC2::PowerMode::Doze; break; case HWC2::PowerMode::DozeSuspend: state = kStateDozeSuspend; last_power_mode_ = HWC2::PowerMode::DozeSuspend; break; default: return HWC2::Error::BadParameter; } int release_fence = -1; ATRACE_INT("SetPowerMode ", state); DisplayError error = display_intf_->SetDisplayState(state, &release_fence); validated_ = false; if (error == kErrorNone) { flush_on_error_ = flush_on_error; } else { if (error == kErrorShutDown) { shutdown_pending_ = true; return HWC2::Error::None; } DLOGE("Set state failed. Error = %d", error); return HWC2::Error::BadParameter; } if (release_fence >= 0) { for (auto hwc_layer : layer_set_) { auto fence = hwc_layer->PopBackReleaseFence(); auto merged_fence = -1; if (fence >= 0) { merged_fence = sync_merge("sync_merge", release_fence, fence); ::close(fence); } else { merged_fence = ::dup(release_fence); } hwc_layer->PushBackReleaseFence(merged_fence); } ::close(release_fence); } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetClientTargetSupport(uint32_t width, uint32_t height, int32_t format, int32_t dataspace) { ColorMetaData color_metadata = {}; if (dataspace != HAL_DATASPACE_UNKNOWN) { GetColorPrimary(dataspace, &(color_metadata.colorPrimaries)); GetTransfer(dataspace, &(color_metadata.transfer)); GetRange(dataspace, &(color_metadata.range)); } LayerBufferFormat sdm_format = GetSDMFormat(format, 0); if (display_intf_->GetClientTargetSupport(width, height, sdm_format, color_metadata) != kErrorNone) { return HWC2::Error::Unsupported; } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetColorModes(uint32_t *out_num_modes, ColorMode *out_modes) { if (out_modes == nullptr) { *out_num_modes = 1; } else if (out_modes && *out_num_modes > 0) { *out_num_modes = 1; out_modes[0] = ColorMode::NATIVE; } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetRenderIntents(ColorMode mode, uint32_t *out_num_intents, RenderIntent *out_intents) { if (mode != ColorMode::NATIVE) { return HWC2::Error::Unsupported; } if (out_intents == nullptr) { *out_num_intents = 1; } else if (out_intents && *out_num_intents > 0) { *out_num_intents = 1; out_intents[0] = RenderIntent::COLORIMETRIC; } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetDisplayConfigs(uint32_t *out_num_configs, hwc2_config_t *out_configs) { if (out_num_configs == nullptr) { return HWC2::Error::BadParameter; } if (out_configs == nullptr) { *out_num_configs = num_configs_; return HWC2::Error::None; } *out_num_configs = std::min(*out_num_configs, num_configs_); for (uint32_t i = 0; i < *out_num_configs; i++) { out_configs[i] = i; } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetDisplayAttribute(hwc2_config_t config, HWC2::Attribute attribute, int32_t *out_value) { DisplayConfigVariableInfo variable_config; // Get display attributes from config index only if resolution switch is supported. // Otherwise always send mixer attributes. This is to support destination scaler. if (num_configs_ > 1) { if (GetDisplayAttributesForConfig(INT(config), &variable_config) != kErrorNone) { DLOGE("Get variable config failed"); return HWC2::Error::BadDisplay; } } else { if (display_intf_->GetFrameBufferConfig(&variable_config) != kErrorNone) { DLOGV("Get variable config failed"); return HWC2::Error::BadDisplay; } } switch (attribute) { case HWC2::Attribute::VsyncPeriod: *out_value = INT32(variable_config.vsync_period_ns); break; case HWC2::Attribute::Width: *out_value = INT32(variable_config.x_pixels); break; case HWC2::Attribute::Height: *out_value = INT32(variable_config.y_pixels); break; case HWC2::Attribute::DpiX: *out_value = INT32(variable_config.x_dpi * 1000.0f); break; case HWC2::Attribute::DpiY: *out_value = INT32(variable_config.y_dpi * 1000.0f); break; default: DLOGW("Spurious attribute type = %s", to_string(attribute).c_str()); *out_value = -1; return HWC2::Error::BadConfig; } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetDisplayName(uint32_t *out_size, char *out_name) { // TODO(user): Get panel name and EDID name and populate it here if (out_size == nullptr) { return HWC2::Error::BadParameter; } std::string name; switch (id_) { case HWC_DISPLAY_PRIMARY: name = "Primary Display"; break; case HWC_DISPLAY_EXTERNAL: name = "External Display"; break; case HWC_DISPLAY_VIRTUAL: name = "Virtual Display"; break; default: name = "Unknown"; break; } if (out_name == nullptr) { *out_size = UINT32(name.size()) + 1; } else { *out_size = std::min((UINT32(name.size()) + 1), *out_size); if (*out_size > 0) { std::strncpy(out_name, name.c_str(), *out_size); out_name[*out_size - 1] = '\0'; } else { DLOGW("Invalid size requested"); } } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetDisplayType(int32_t *out_type) { if (out_type != nullptr) { if (id_ == HWC_DISPLAY_VIRTUAL) { *out_type = HWC2_DISPLAY_TYPE_VIRTUAL; } else { *out_type = HWC2_DISPLAY_TYPE_PHYSICAL; } return HWC2::Error::None; } else { return HWC2::Error::BadParameter; } } HWC2::Error HWCDisplay::GetPerFrameMetadataKeys(uint32_t *out_num_keys, PerFrameMetadataKey *out_keys) { if (out_num_keys == nullptr) { return HWC2::Error::BadParameter; } *out_num_keys = UINT32(PerFrameMetadataKey::MAX_FRAME_AVERAGE_LIGHT_LEVEL) + 1; if (out_keys != nullptr) { out_keys[0] = PerFrameMetadataKey::DISPLAY_RED_PRIMARY_X; out_keys[1] = PerFrameMetadataKey::DISPLAY_RED_PRIMARY_Y; out_keys[2] = PerFrameMetadataKey::DISPLAY_GREEN_PRIMARY_X; out_keys[3] = PerFrameMetadataKey::DISPLAY_GREEN_PRIMARY_Y; out_keys[4] = PerFrameMetadataKey::DISPLAY_BLUE_PRIMARY_X; out_keys[5] = PerFrameMetadataKey::DISPLAY_BLUE_PRIMARY_Y; out_keys[6] = PerFrameMetadataKey::WHITE_POINT_X; out_keys[7] = PerFrameMetadataKey::WHITE_POINT_Y; out_keys[8] = PerFrameMetadataKey::MAX_LUMINANCE; out_keys[9] = PerFrameMetadataKey::MIN_LUMINANCE; out_keys[10] = PerFrameMetadataKey::MAX_CONTENT_LIGHT_LEVEL; out_keys[11] = PerFrameMetadataKey::MAX_FRAME_AVERAGE_LIGHT_LEVEL; } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetActiveConfig(hwc2_config_t *out_config) { if (out_config == nullptr) { return HWC2::Error::BadDisplay; } uint32_t active_index = 0; if (GetActiveDisplayConfig(&active_index) != kErrorNone) { return HWC2::Error::BadConfig; } *out_config = active_index; return HWC2::Error::None; } HWC2::Error HWCDisplay::SetClientTarget(buffer_handle_t target, int32_t acquire_fence, int32_t dataspace, hwc_region_t damage) { // TODO(user): SurfaceFlinger gives us a null pointer here when doing full SDE composition // The error is problematic for layer caching as it would overwrite our cached client target. // Reported bug 28569722 to resolve this. // For now, continue to use the last valid buffer reported to us for layer caching. if (target == nullptr) { return HWC2::Error::None; } if (acquire_fence == 0) { DLOGE("acquire_fence is zero"); return HWC2::Error::BadParameter; } Layer *sdm_layer = client_target_->GetSDMLayer(); sdm_layer->frame_rate = current_refresh_rate_; client_target_->SetLayerBuffer(target, acquire_fence); client_target_->SetLayerSurfaceDamage(damage); if (client_target_->GetLayerDataspace() != dataspace) { client_target_->SetLayerDataspace(dataspace); Layer *sdm_layer = client_target_->GetSDMLayer(); // Data space would be validated at GetClientTargetSupport, so just use here. sdm::GetSDMColorSpace(dataspace, &sdm_layer->input_buffer.color_metadata); } return HWC2::Error::None; } HWC2::Error HWCDisplay::SetActiveConfig(hwc2_config_t config) { if (SetActiveDisplayConfig(config) != kErrorNone) { return HWC2::Error::BadConfig; } validated_ = false; return HWC2::Error::None; } DisplayError HWCDisplay::SetMixerResolution(uint32_t width, uint32_t height) { return kErrorNotSupported; } HWC2::Error HWCDisplay::SetFrameDumpConfig(uint32_t count, uint32_t bit_mask_layer_type, int32_t format, bool post_processed) { dump_frame_count_ = count; dump_frame_index_ = 0; dump_input_layers_ = ((bit_mask_layer_type & (1 << INPUT_LAYER_DUMP)) != 0); if (tone_mapper_) { tone_mapper_->SetFrameDumpConfig(count); } DLOGI("num_frame_dump %d, input_layer_dump_enable %d", dump_frame_count_, dump_input_layers_); validated_ = false; return HWC2::Error::None; } HWC2::PowerMode HWCDisplay::GetLastPowerMode() { return last_power_mode_; } DisplayError HWCDisplay::VSync(const DisplayEventVSync &vsync) { callbacks_->Vsync(id_, vsync.timestamp); return kErrorNone; } DisplayError HWCDisplay::Refresh() { return kErrorNotSupported; } DisplayError HWCDisplay::CECMessage(char *message) { if (qservice_) { qservice_->onCECMessageReceived(message, 0); } else { DLOGW("Qservice instance not available."); } return kErrorNone; } DisplayError HWCDisplay::HandleEvent(DisplayEvent event) { switch (event) { case kIdleTimeout: { SCOPE_LOCK(HWCSession::locker_[type_]); if (pending_commit_) { // If idle timeout event comes in between prepare // and commit, drop it since device is not really // idle. return kErrorNotSupported; } validated_ = false; break; } case kThermalEvent: case kIdlePowerCollapse: case kPanelDeadEvent: { SEQUENCE_WAIT_SCOPE_LOCK(HWCSession::locker_[type_]); validated_ = false; } break; default: DLOGW("Unknown event: %d", event); break; } return kErrorNone; } HWC2::Error HWCDisplay::PrepareLayerStack(uint32_t *out_num_types, uint32_t *out_num_requests) { layer_changes_.clear(); layer_requests_.clear(); has_client_composition_ = false; if (shutdown_pending_) { validated_ = false; return HWC2::Error::BadDisplay; } UpdateRefreshRate(); if (CanSkipSdmPrepare(out_num_types, out_num_requests)) { return ((*out_num_types > 0) ? HWC2::Error::HasChanges : HWC2::Error::None); } if (!skip_prepare_) { DisplayError error = display_intf_->Prepare(&layer_stack_); if (error != kErrorNone) { if (error == kErrorShutDown) { shutdown_pending_ = true; } else if (error != kErrorPermission) { DLOGE("Prepare failed. Error = %d", error); // To prevent surfaceflinger infinite wait, flush the previous frame during Commit() // so that previous buffer and fences are released, and override the error. flush_ = true; } validated_ = false; return HWC2::Error::BadDisplay; } } else { // Skip is not set MarkLayersForGPUBypass(); skip_prepare_ = false; DLOGI("SecureDisplay %s, Skip Prepare/Commit and Flush", secure_display_active_ ? "Starting" : "Stopping"); flush_ = true; } for (auto hwc_layer : layer_set_) { Layer *layer = hwc_layer->GetSDMLayer(); LayerComposition &composition = layer->composition; if ((composition == kCompositionSDE) || (composition == kCompositionHybrid) || (composition == kCompositionBlit)) { layer_requests_[hwc_layer->GetId()] = HWC2::LayerRequest::ClearClientTarget; } HWC2::Composition requested_composition = hwc_layer->GetClientRequestedCompositionType(); // Set SDM composition to HWC2 type in HWCLayer hwc_layer->SetComposition(composition); HWC2::Composition device_composition = hwc_layer->GetDeviceSelectedCompositionType(); if (device_composition == HWC2::Composition::Client) { has_client_composition_ = true; } // Update the changes list only if the requested composition is different from SDM comp type // TODO(user): Take Care of other comptypes(BLIT) if (requested_composition != device_composition) { layer_changes_[hwc_layer->GetId()] = device_composition; } hwc_layer->ResetValidation(); } client_target_->ResetValidation(); *out_num_types = UINT32(layer_changes_.size()); *out_num_requests = UINT32(layer_requests_.size()); validate_state_ = kNormalValidate; validated_ = true; layer_stack_invalid_ = false; return ((*out_num_types > 0) ? HWC2::Error::HasChanges : HWC2::Error::None); } HWC2::Error HWCDisplay::AcceptDisplayChanges() { if (layer_set_.empty()) { return HWC2::Error::None; } if (!validated_) { return HWC2::Error::NotValidated; } for (const auto& change : layer_changes_) { auto hwc_layer = layer_map_[change.first]; auto composition = change.second; if (hwc_layer != nullptr) { hwc_layer->UpdateClientCompositionType(composition); } else { DLOGW("Invalid layer: %" PRIu64, change.first); } } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetChangedCompositionTypes(uint32_t *out_num_elements, hwc2_layer_t *out_layers, int32_t *out_types) { if (layer_set_.empty()) { return HWC2::Error::None; } if (!validated_) { DLOGW("Display is not validated"); return HWC2::Error::NotValidated; } *out_num_elements = UINT32(layer_changes_.size()); if (out_layers != nullptr && out_types != nullptr) { int i = 0; for (auto change : layer_changes_) { out_layers[i] = change.first; out_types[i] = INT32(change.second); i++; } } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetReleaseFences(uint32_t *out_num_elements, hwc2_layer_t *out_layers, int32_t *out_fences) { if (out_num_elements == nullptr) { return HWC2::Error::BadParameter; } if (out_layers != nullptr && out_fences != nullptr) { *out_num_elements = std::min(*out_num_elements, UINT32(layer_set_.size())); auto it = layer_set_.begin(); for (uint32_t i = 0; i < *out_num_elements; i++, it++) { auto hwc_layer = *it; out_layers[i] = hwc_layer->GetId(); out_fences[i] = hwc_layer->PopFrontReleaseFence(); } } else { *out_num_elements = UINT32(layer_set_.size()); } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetDisplayRequests(int32_t *out_display_requests, uint32_t *out_num_elements, hwc2_layer_t *out_layers, int32_t *out_layer_requests) { if (layer_set_.empty()) { return HWC2::Error::None; } if (out_display_requests == nullptr || out_num_elements == nullptr) { return HWC2::Error::BadParameter; } // No display requests for now // Use for sharing blit buffers and // writing wfd buffer directly to output if there is full GPU composition // and no color conversion needed if (!validated_) { DLOGW("Display is not validated"); return HWC2::Error::NotValidated; } *out_display_requests = 0; if (out_layers != nullptr && out_layer_requests != nullptr) { *out_num_elements = std::min(*out_num_elements, UINT32(layer_requests_.size())); auto it = layer_requests_.begin(); for (uint32_t i = 0; i < *out_num_elements; i++, it++) { out_layers[i] = it->first; out_layer_requests[i] = INT32(it->second); } } else { *out_num_elements = UINT32(layer_requests_.size()); } auto client_target_layer = client_target_->GetSDMLayer(); if (client_target_layer->request.flags.flip_buffer) { *out_display_requests = INT32(HWC2::DisplayRequest::FlipClientTarget); } return HWC2::Error::None; } HWC2::Error HWCDisplay::GetHdrCapabilities(uint32_t *out_num_types, int32_t *out_types, float *out_max_luminance, float *out_max_average_luminance, float *out_min_luminance) { if (out_num_types == nullptr || out_max_luminance == nullptr || out_max_average_luminance == nullptr || out_min_luminance == nullptr) { return HWC2::Error::BadParameter; } DisplayConfigFixedInfo fixed_info = {}; display_intf_->GetConfig(&fixed_info); if (!fixed_info.hdr_supported) { *out_num_types = 0; DLOGI("HDR is not supported"); return HWC2::Error::None; } if (out_types == nullptr) { // We support HDR10 and HLG *out_num_types = 2; } else { // HDR10 and HLG are supported out_types[0] = HAL_HDR_HDR10; out_types[1] = HAL_HDR_HLG; static const float kLuminanceFactor = 10000.0; // luminance is expressed in the unit of 0.0001 cd/m2, convert it to 1cd/m2. *out_max_luminance = FLOAT(fixed_info.max_luminance)/kLuminanceFactor; *out_max_average_luminance = FLOAT(fixed_info.average_luminance)/kLuminanceFactor; *out_min_luminance = FLOAT(fixed_info.min_luminance)/kLuminanceFactor; } return HWC2::Error::None; } HWC2::Error HWCDisplay::CommitLayerStack(void) { if (!validated_) { DLOGV_IF(kTagClient, "Display %d is not validated", id_); return HWC2::Error::NotValidated; } if (shutdown_pending_ || layer_set_.empty()) { return HWC2::Error::None; } DumpInputBuffers(); if (!flush_) { DisplayError error = kErrorUndefined; int status = 0; if (tone_mapper_) { if (layer_stack_.flags.hdr_present) { status = tone_mapper_->HandleToneMap(&layer_stack_); if (status != 0) { DLOGE("Error handling HDR in ToneMapper"); } } else { tone_mapper_->Terminate(); } } error = display_intf_->Commit(&layer_stack_); if (error == kErrorNone) { // A commit is successfully submitted, start flushing on failure now onwards. flush_on_error_ = true; } else { if (error == kErrorShutDown) { shutdown_pending_ = true; return HWC2::Error::Unsupported; } else if (error == kErrorNotValidated) { validated_ = false; return HWC2::Error::NotValidated; } else if (error != kErrorPermission) { DLOGE("Commit failed. Error = %d", error); // To prevent surfaceflinger infinite wait, flush the previous frame during Commit() // so that previous buffer and fences are released, and override the error. flush_ = true; } } } validate_state_ = kSkipValidate; return HWC2::Error::None; } HWC2::Error HWCDisplay::PostCommitLayerStack(int32_t *out_retire_fence) { auto status = HWC2::Error::None; // Do no call flush on errors, if a successful buffer is never submitted. if (flush_ && flush_on_error_) { display_intf_->Flush(); validated_ = false; } if (tone_mapper_ && tone_mapper_->IsActive()) { tone_mapper_->PostCommit(&layer_stack_); } // TODO(user): No way to set the client target release fence on SF int32_t &client_target_release_fence = client_target_->GetSDMLayer()->input_buffer.release_fence_fd; if (client_target_release_fence >= 0) { close(client_target_release_fence); client_target_release_fence = -1; } client_target_->ResetGeometryChanges(); for (auto hwc_layer : layer_set_) { hwc_layer->ResetGeometryChanges(); Layer *layer = hwc_layer->GetSDMLayer(); LayerBuffer *layer_buffer = &layer->input_buffer; if (!flush_) { // If swapinterval property is set to 0 or for single buffer layers, do not update f/w // release fences and discard fences from driver if (swap_interval_zero_ || layer->flags.single_buffer) { close(layer_buffer->release_fence_fd); } else if (layer->composition != kCompositionGPU) { hwc_layer->PushBackReleaseFence(layer_buffer->release_fence_fd); } else { hwc_layer->PushBackReleaseFence(-1); } } else { // In case of flush, we don't return an error to f/w, so it will get a release fence out of // the hwc_layer's release fence queue. We should push a -1 to preserve release fence // circulation semantics. hwc_layer->PushBackReleaseFence(-1); } layer_buffer->release_fence_fd = -1; if (layer_buffer->acquire_fence_fd >= 0) { close(layer_buffer->acquire_fence_fd); layer_buffer->acquire_fence_fd = -1; } layer->request.flags = {}; } client_target_->GetSDMLayer()->request.flags = {}; *out_retire_fence = -1; if (!flush_) { // if swapinterval property is set to 0 then close and reset the list retire fence if (swap_interval_zero_) { close(layer_stack_.retire_fence_fd); layer_stack_.retire_fence_fd = -1; } *out_retire_fence = layer_stack_.retire_fence_fd; layer_stack_.retire_fence_fd = -1; if (dump_frame_count_) { dump_frame_count_--; dump_frame_index_++; } } config_pending_ = false; geometry_changes_ = GeometryChanges::kNone; flush_ = false; return status; } void HWCDisplay::SetIdleTimeoutMs(uint32_t timeout_ms) { return; } DisplayError HWCDisplay::SetMaxMixerStages(uint32_t max_mixer_stages) { DisplayError error = kErrorNone; if (display_intf_) { error = display_intf_->SetMaxMixerStages(max_mixer_stages); validated_ = false; } return error; } LayerBufferFormat HWCDisplay::GetSDMFormat(const int32_t &source, const int flags) { LayerBufferFormat format = kFormatInvalid; if (flags & private_handle_t::PRIV_FLAGS_UBWC_ALIGNED) { switch (source) { case HAL_PIXEL_FORMAT_RGBA_8888: format = kFormatRGBA8888Ubwc; break; case HAL_PIXEL_FORMAT_RGBX_8888: format = kFormatRGBX8888Ubwc; break; case HAL_PIXEL_FORMAT_BGR_565: format = kFormatBGR565Ubwc; break; case HAL_PIXEL_FORMAT_YCbCr_420_SP_VENUS: case HAL_PIXEL_FORMAT_YCbCr_420_SP_VENUS_UBWC: case HAL_PIXEL_FORMAT_NV12_ENCODEABLE: format = kFormatYCbCr420SPVenusUbwc; break; case HAL_PIXEL_FORMAT_RGBA_1010102: format = kFormatRGBA1010102Ubwc; break; case HAL_PIXEL_FORMAT_RGBX_1010102: format = kFormatRGBX1010102Ubwc; break; case HAL_PIXEL_FORMAT_YCbCr_420_TP10_UBWC: format = kFormatYCbCr420TP10Ubwc; break; case HAL_PIXEL_FORMAT_YCbCr_420_P010_UBWC: format = kFormatYCbCr420P010Ubwc; break; default: DLOGE("Unsupported format type for UBWC %d", source); return kFormatInvalid; } return format; } switch (source) { case HAL_PIXEL_FORMAT_RGBA_8888: format = kFormatRGBA8888; break; case HAL_PIXEL_FORMAT_RGBA_5551: format = kFormatRGBA5551; break; case HAL_PIXEL_FORMAT_RGBA_4444: format = kFormatRGBA4444; break; case HAL_PIXEL_FORMAT_BGRA_8888: format = kFormatBGRA8888; break; case HAL_PIXEL_FORMAT_RGBX_8888: format = kFormatRGBX8888; break; case HAL_PIXEL_FORMAT_BGRX_8888: format = kFormatBGRX8888; break; case HAL_PIXEL_FORMAT_RGB_888: format = kFormatRGB888; break; case HAL_PIXEL_FORMAT_RGB_565: format = kFormatRGB565; break; case HAL_PIXEL_FORMAT_BGR_565: format = kFormatBGR565; break; case HAL_PIXEL_FORMAT_BGR_888: format = kFormatBGR888; break; case HAL_PIXEL_FORMAT_NV12_ENCODEABLE: case HAL_PIXEL_FORMAT_YCbCr_420_SP_VENUS: format = kFormatYCbCr420SemiPlanarVenus; break; case HAL_PIXEL_FORMAT_YCrCb_420_SP_VENUS: format = kFormatYCrCb420SemiPlanarVenus; break; case HAL_PIXEL_FORMAT_YCbCr_420_SP_VENUS_UBWC: format = kFormatYCbCr420SPVenusUbwc; break; case HAL_PIXEL_FORMAT_YV12: format = kFormatYCrCb420PlanarStride16; break; case HAL_PIXEL_FORMAT_YCrCb_420_SP: format = kFormatYCrCb420SemiPlanar; break; case HAL_PIXEL_FORMAT_YCbCr_420_SP: format = kFormatYCbCr420SemiPlanar; break; case HAL_PIXEL_FORMAT_YCbCr_422_SP: format = kFormatYCbCr422H2V1SemiPlanar; break; case HAL_PIXEL_FORMAT_YCbCr_422_I: format = kFormatYCbCr422H2V1Packed; break; case HAL_PIXEL_FORMAT_CbYCrY_422_I: format = kFormatCbYCrY422H2V1Packed; break; case HAL_PIXEL_FORMAT_RGBA_1010102: format = kFormatRGBA1010102; break; case HAL_PIXEL_FORMAT_ARGB_2101010: format = kFormatARGB2101010; break; case HAL_PIXEL_FORMAT_RGBX_1010102: format = kFormatRGBX1010102; break; case HAL_PIXEL_FORMAT_XRGB_2101010: format = kFormatXRGB2101010; break; case HAL_PIXEL_FORMAT_BGRA_1010102: format = kFormatBGRA1010102; break; case HAL_PIXEL_FORMAT_ABGR_2101010: format = kFormatABGR2101010; break; case HAL_PIXEL_FORMAT_BGRX_1010102: format = kFormatBGRX1010102; break; case HAL_PIXEL_FORMAT_XBGR_2101010: format = kFormatXBGR2101010; break; case HAL_PIXEL_FORMAT_YCbCr_420_P010: format = kFormatYCbCr420P010; break; case HAL_PIXEL_FORMAT_YCbCr_420_TP10_UBWC: format = kFormatYCbCr420TP10Ubwc; break; case HAL_PIXEL_FORMAT_YCbCr_420_P010_UBWC: format = kFormatYCbCr420P010Ubwc; break; case HAL_PIXEL_FORMAT_YCbCr_420_P010_VENUS: format = kFormatYCbCr420P010Venus; break; default: DLOGW("Unsupported format type = %d", source); return kFormatInvalid; } return format; } void HWCDisplay::DumpInputBuffers() { char dir_path[PATH_MAX]; int status; if (!dump_frame_count_ || flush_ || !dump_input_layers_) { return; } DLOGI("dump_frame_count %d dump_input_layers %d", dump_frame_count_, dump_input_layers_); snprintf(dir_path, sizeof(dir_path), "%s/frame_dump_%s", HWCDebugHandler::DumpDir(), GetDisplayString()); status = mkdir(dir_path, 777); if ((status != 0) && errno != EEXIST) { DLOGW("Failed to create %s directory errno = %d, desc = %s", dir_path, errno, strerror(errno)); return; } // Even if directory exists already, need to explicitly change the permission. if (chmod(dir_path, 0777) != 0) { DLOGW("Failed to change permissions on %s directory", dir_path); return; } for (uint32_t i = 0; i < layer_stack_.layers.size(); i++) { auto layer = layer_stack_.layers.at(i); const private_handle_t *pvt_handle = reinterpret_cast(layer->input_buffer.buffer_id); auto acquire_fence_fd = layer->input_buffer.acquire_fence_fd; if (acquire_fence_fd >= 0) { int error = sync_wait(acquire_fence_fd, 1000); if (error < 0) { DLOGW("sync_wait error errno = %d, desc = %s", errno, strerror(errno)); return; } } DLOGI("Dump layer[%d] of %d pvt_handle %x pvt_handle->base %x", i, layer_stack_.layers.size(), pvt_handle, pvt_handle? pvt_handle->base : 0); if (!pvt_handle) { DLOGE("Buffer handle is null"); return; } if (!pvt_handle->base) { DisplayError error = buffer_allocator_->MapBuffer(pvt_handle, -1); if (error != kErrorNone) { DLOGE("Failed to map buffer, error = %d", error); return; } } char dump_file_name[PATH_MAX]; size_t result = 0; snprintf(dump_file_name, sizeof(dump_file_name), "%s/input_layer%d_%dx%d_%s_frame%d.raw", dir_path, i, pvt_handle->width, pvt_handle->height, qdutils::GetHALPixelFormatString(pvt_handle->format), dump_frame_index_); FILE *fp = fopen(dump_file_name, "w+"); if (fp) { result = fwrite(reinterpret_cast(pvt_handle->base), pvt_handle->size, 1, fp); fclose(fp); } int release_fence = -1; DisplayError error = buffer_allocator_->UnmapBuffer(pvt_handle, &release_fence); if (error != kErrorNone) { DLOGE("Failed to unmap buffer, error = %d", error); return; } DLOGI("Frame Dump %s: is %s", dump_file_name, result ? "Successful" : "Failed"); } } void HWCDisplay::DumpOutputBuffer(const BufferInfo &buffer_info, void *base, int fence) { char dir_path[PATH_MAX]; int status; snprintf(dir_path, sizeof(dir_path), "%s/frame_dump_%s", HWCDebugHandler::DumpDir(), GetDisplayString()); status = mkdir(dir_path, 777); if ((status != 0) && errno != EEXIST) { DLOGW("Failed to create %s directory errno = %d, desc = %s", dir_path, errno, strerror(errno)); return; } // Even if directory exists already, need to explicitly change the permission. if (chmod(dir_path, 0777) != 0) { DLOGW("Failed to change permissions on %s directory", dir_path); return; } if (base) { char dump_file_name[PATH_MAX]; size_t result = 0; if (fence >= 0) { int error = sync_wait(fence, 1000); if (error < 0) { DLOGW("sync_wait error errno = %d, desc = %s", errno, strerror(errno)); return; } } snprintf(dump_file_name, sizeof(dump_file_name), "%s/output_layer_%dx%d_%s_frame%d.raw", dir_path, buffer_info.alloc_buffer_info.aligned_width, buffer_info.alloc_buffer_info.aligned_height, GetFormatString(buffer_info.buffer_config.format), dump_frame_index_); FILE *fp = fopen(dump_file_name, "w+"); if (fp) { result = fwrite(base, buffer_info.alloc_buffer_info.size, 1, fp); fclose(fp); } DLOGI("Frame Dump of %s is %s", dump_file_name, result ? "Successful" : "Failed"); } } const char *HWCDisplay::GetDisplayString() { switch (type_) { case kPrimary: return "primary"; case kHDMI: return "hdmi"; case kVirtual: return "virtual"; default: return "invalid"; } } int HWCDisplay::SetFrameBufferResolution(uint32_t x_pixels, uint32_t y_pixels) { if (x_pixels <= 0 || y_pixels <= 0) { DLOGW("Unsupported config: x_pixels=%d, y_pixels=%d", x_pixels, y_pixels); return -EINVAL; } DisplayConfigVariableInfo fb_config; DisplayError error = display_intf_->GetFrameBufferConfig(&fb_config); if (error != kErrorNone) { DLOGV("Get frame buffer config failed. Error = %d", error); return -EINVAL; } fb_config.x_pixels = x_pixels; fb_config.y_pixels = y_pixels; error = display_intf_->SetFrameBufferConfig(fb_config); if (error != kErrorNone) { DLOGV("Set frame buffer config failed. Error = %d", error); return -EINVAL; } // Create rects to represent the new source and destination crops LayerRect crop = LayerRect(0, 0, FLOAT(x_pixels), FLOAT(y_pixels)); hwc_rect_t scaled_display_frame = {0, 0, INT(x_pixels), INT(y_pixels)}; ApplyScanAdjustment(&scaled_display_frame); client_target_->SetLayerDisplayFrame(scaled_display_frame); client_target_->ResetPerFrameData(); auto client_target_layer = client_target_->GetSDMLayer(); client_target_layer->src_rect = crop; int aligned_width; int aligned_height; uint32_t usage = GRALLOC_USAGE_HW_FB; int format = HAL_PIXEL_FORMAT_RGBA_8888; int ubwc_disabled = 0; int flags = 0; // By default UBWC is enabled and below property is global enable/disable for all // buffers allocated through gralloc , including framebuffer targets. HWCDebugHandler::Get()->GetProperty(DISABLE_UBWC_PROP, &ubwc_disabled); if (!ubwc_disabled) { usage |= GRALLOC_USAGE_PRIVATE_ALLOC_UBWC; flags |= private_handle_t::PRIV_FLAGS_UBWC_ALIGNED; } buffer_allocator_->GetAlignedWidthAndHeight(INT(x_pixels), INT(y_pixels), format, usage, &aligned_width, &aligned_height); // TODO(user): How does the dirty region get set on the client target? File bug on Google client_target_layer->composition = kCompositionGPUTarget; client_target_layer->input_buffer.format = GetSDMFormat(format, flags); client_target_layer->input_buffer.width = UINT32(aligned_width); client_target_layer->input_buffer.height = UINT32(aligned_height); client_target_layer->input_buffer.unaligned_width = x_pixels; client_target_layer->input_buffer.unaligned_height = y_pixels; client_target_layer->plane_alpha = 255; DLOGI("New framebuffer resolution (%dx%d)", fb_config.x_pixels, fb_config.y_pixels); return 0; } void HWCDisplay::GetFrameBufferResolution(uint32_t *x_pixels, uint32_t *y_pixels) { DisplayConfigVariableInfo fb_config; display_intf_->GetFrameBufferConfig(&fb_config); *x_pixels = fb_config.x_pixels; *y_pixels = fb_config.y_pixels; } DisplayError HWCDisplay::GetMixerResolution(uint32_t *x_pixels, uint32_t *y_pixels) { return display_intf_->GetMixerResolution(x_pixels, y_pixels); } void HWCDisplay::GetPanelResolution(uint32_t *x_pixels, uint32_t *y_pixels) { DisplayConfigVariableInfo display_config; uint32_t active_index = 0; display_intf_->GetActiveConfig(&active_index); display_intf_->GetConfig(active_index, &display_config); *x_pixels = display_config.x_pixels; *y_pixels = display_config.y_pixels; } int HWCDisplay::SetDisplayStatus(DisplayStatus display_status) { int status = 0; switch (display_status) { case kDisplayStatusResume: display_paused_ = false; status = INT32(SetPowerMode(HWC2::PowerMode::On)); break; case kDisplayStatusOnline: status = INT32(SetPowerMode(HWC2::PowerMode::On)); break; case kDisplayStatusPause: display_paused_ = true; status = INT32(SetPowerMode(HWC2::PowerMode::Off)); break; case kDisplayStatusOffline: status = INT32(SetPowerMode(HWC2::PowerMode::Off)); break; default: DLOGW("Invalid display status %d", display_status); return -EINVAL; } if (display_status == kDisplayStatusResume || display_status == kDisplayStatusPause) { callbacks_->Refresh(HWC_DISPLAY_PRIMARY); validated_ = false; } return status; } HWC2::Error HWCDisplay::SetCursorPosition(hwc2_layer_t layer, int x, int y) { if (shutdown_pending_) { return HWC2::Error::None; } HWCLayer *hwc_layer = GetHWCLayer(layer); if (hwc_layer == nullptr) { return HWC2::Error::BadLayer; } if (hwc_layer->GetDeviceSelectedCompositionType() != HWC2::Composition::Cursor) { return HWC2::Error::None; } if ((validate_state_ != kSkipValidate) && validated_) { // the device is currently in the middle of the validate/present sequence, // cannot set the Position(as per HWC2 spec) return HWC2::Error::NotValidated; } DisplayState state; if (display_intf_->GetDisplayState(&state) == kErrorNone) { if (state != kStateOn) { return HWC2::Error::None; } } // TODO(user): HWC1.5 was not letting SetCursorPosition before validateDisplay, // but HWC2.0 doesn't let setting cursor position after validate before present. // Need to revisit. auto error = display_intf_->SetCursorPosition(x, y); if (error != kErrorNone) { if (error == kErrorShutDown) { shutdown_pending_ = true; return HWC2::Error::None; } DLOGE("Failed for x = %d y = %d, Error = %d", x, y, error); return HWC2::Error::BadDisplay; } return HWC2::Error::None; } int HWCDisplay::OnMinHdcpEncryptionLevelChange(uint32_t min_enc_level) { DisplayError error = display_intf_->OnMinHdcpEncryptionLevelChange(min_enc_level); if (error != kErrorNone) { DLOGE("Failed. Error = %d", error); return -1; } validated_ = false; return 0; } void HWCDisplay::MarkLayersForGPUBypass() { for (auto hwc_layer : layer_set_) { auto layer = hwc_layer->GetSDMLayer(); layer->composition = kCompositionSDE; } validated_ = true; } void HWCDisplay::MarkLayersForClientComposition() { // ClientComposition - GPU comp, to acheive this, set skip flag so that // SDM does not handle this layer and hwc_layer composition will be // set correctly at the end of Prepare. DLOGV_IF(kTagClient, "HWC Layers marked for GPU comp"); for (auto hwc_layer : layer_set_) { Layer *layer = hwc_layer->GetSDMLayer(); layer->flags.skip = true; } layer_stack_.flags.skip_present = true; } void HWCDisplay::ApplyScanAdjustment(hwc_rect_t *display_frame) { } int HWCDisplay::SetPanelBrightness(int level) { int ret = 0; if (display_intf_) { ret = display_intf_->SetPanelBrightness(level); validated_ = false; } else { ret = -EINVAL; } return ret; } int HWCDisplay::GetPanelBrightness(int *level) { return display_intf_->GetPanelBrightness(level); } int HWCDisplay::ToggleScreenUpdates(bool enable) { display_paused_ = enable ? false : true; callbacks_->Refresh(HWC_DISPLAY_PRIMARY); validated_ = false; return 0; } int HWCDisplay::ColorSVCRequestRoute(const PPDisplayAPIPayload &in_payload, PPDisplayAPIPayload *out_payload, PPPendingParams *pending_action) { int ret = 0; if (display_intf_) ret = display_intf_->ColorSVCRequestRoute(in_payload, out_payload, pending_action); else ret = -EINVAL; return ret; } void HWCDisplay::SolidFillPrepare() { if (solid_fill_enable_) { if (solid_fill_layer_ == NULL) { // Create a dummy layer here solid_fill_layer_ = new Layer(); } uint32_t primary_width = 0, primary_height = 0; GetMixerResolution(&primary_width, &primary_height); LayerBuffer *layer_buffer = &solid_fill_layer_->input_buffer; layer_buffer->width = primary_width; layer_buffer->height = primary_height; layer_buffer->unaligned_width = primary_width; layer_buffer->unaligned_height = primary_height; layer_buffer->acquire_fence_fd = -1; layer_buffer->release_fence_fd = -1; solid_fill_layer_->composition = kCompositionGPU; solid_fill_layer_->src_rect = solid_fill_rect_; solid_fill_layer_->dst_rect = solid_fill_rect_; solid_fill_layer_->blending = kBlendingPremultiplied; solid_fill_layer_->solid_fill_color = 0; solid_fill_layer_->solid_fill_info.bit_depth = solid_fill_color_.bit_depth; solid_fill_layer_->solid_fill_info.red = solid_fill_color_.red; solid_fill_layer_->solid_fill_info.blue = solid_fill_color_.blue; solid_fill_layer_->solid_fill_info.green = solid_fill_color_.green; solid_fill_layer_->solid_fill_info.alpha = solid_fill_color_.alpha; solid_fill_layer_->frame_rate = 60; solid_fill_layer_->visible_regions.push_back(solid_fill_layer_->dst_rect); solid_fill_layer_->flags.updating = 1; solid_fill_layer_->flags.solid_fill = true; } else { // delete the dummy layer delete solid_fill_layer_; solid_fill_layer_ = NULL; } if (solid_fill_enable_ && solid_fill_layer_) { BuildSolidFillStack(); MarkLayersForGPUBypass(); } return; } void HWCDisplay::SolidFillCommit() { if (solid_fill_enable_ && solid_fill_layer_) { LayerBuffer *layer_buffer = &solid_fill_layer_->input_buffer; if (layer_buffer->release_fence_fd > 0) { close(layer_buffer->release_fence_fd); layer_buffer->release_fence_fd = -1; } if (layer_stack_.retire_fence_fd > 0) { close(layer_stack_.retire_fence_fd); layer_stack_.retire_fence_fd = -1; } } } int HWCDisplay::GetVisibleDisplayRect(hwc_rect_t *visible_rect) { if (!IsValid(display_rect_)) { return -EINVAL; } visible_rect->left = INT(display_rect_.left); visible_rect->top = INT(display_rect_.top); visible_rect->right = INT(display_rect_.right); visible_rect->bottom = INT(display_rect_.bottom); DLOGI("Dpy = %d Visible Display Rect(%d %d %d %d)", visible_rect->left, visible_rect->top, visible_rect->right, visible_rect->bottom); return 0; } void HWCDisplay::SetSecureDisplay(bool secure_display_active) { if (secure_display_active_ != secure_display_active) { DLOGI("SecureDisplay state changed from %d to %d Needs Flush!!", secure_display_active_, secure_display_active); secure_display_active_ = secure_display_active; skip_prepare_ = true; } return; } int HWCDisplay::SetActiveDisplayConfig(uint32_t config) { if (display_config_ == config) { return 0; } display_config_ = config; config_pending_ = true; validated_ = false; callbacks_->Refresh(id_); return 0; } int HWCDisplay::GetActiveDisplayConfig(uint32_t *config) { if (config_pending_) { *config = display_config_; return 0; } return display_intf_->GetActiveConfig(config) == kErrorNone ? 0 : -1; } int HWCDisplay::GetDisplayConfigCount(uint32_t *count) { return display_intf_->GetNumVariableInfoConfigs(count) == kErrorNone ? 0 : -1; } int HWCDisplay::GetDisplayAttributesForConfig(int config, DisplayConfigVariableInfo *display_attributes) { return display_intf_->GetConfig(UINT32(config), display_attributes) == kErrorNone ? 0 : -1; } uint32_t HWCDisplay::GetUpdatingLayersCount(void) { uint32_t updating_count = 0; for (uint i = 0; i < layer_stack_.layers.size(); i++) { auto layer = layer_stack_.layers.at(i); if (layer->flags.updating) { updating_count++; } } return updating_count; } bool HWCDisplay::IsLayerUpdating(HWCLayer *hwc_layer) { auto layer = hwc_layer->GetSDMLayer(); // Layer should be considered updating if // a) layer is in single buffer mode, or // b) valid dirty_regions(android specific hint for updating status), or // c) layer stack geometry has changed (TODO(user): Remove when SDM accepts // geometry_changed as bit fields). return (layer->flags.single_buffer || hwc_layer->IsSurfaceUpdated() || geometry_changes_); } uint32_t HWCDisplay::SanitizeRefreshRate(uint32_t req_refresh_rate) { uint32_t refresh_rate = req_refresh_rate; if (refresh_rate < min_refresh_rate_) { // Pick the next multiple of request which is within the range refresh_rate = (((min_refresh_rate_ / refresh_rate) + ((min_refresh_rate_ % refresh_rate) ? 1 : 0)) * refresh_rate); } if (refresh_rate > max_refresh_rate_) { refresh_rate = max_refresh_rate_; } return refresh_rate; } DisplayClass HWCDisplay::GetDisplayClass() { return display_class_; } std::string HWCDisplay::Dump() { std::ostringstream os; os << "\n------------HWC----------------\n"; os << "HWC2 display_id: " << id_ << std::endl; for (auto layer : layer_set_) { auto sdm_layer = layer->GetSDMLayer(); auto transform = sdm_layer->transform; os << "layer: " << std::setw(4) << layer->GetId(); os << " z: " << layer->GetZ(); os << " composition: " << to_string(layer->GetClientRequestedCompositionType()).c_str(); os << "/" << to_string(layer->GetDeviceSelectedCompositionType()).c_str(); os << " alpha: " << std::to_string(sdm_layer->plane_alpha).c_str(); os << " format: " << std::setw(22) << GetFormatString(sdm_layer->input_buffer.format); os << " dataspace:" << std::hex << "0x" << std::setw(8) << std::setfill('0') << layer->GetLayerDataspace() << std::dec << std::setfill(' '); os << " transform: " << transform.rotation << "/" << transform.flip_horizontal << "/"<< transform.flip_vertical; os << " buffer_id: " << std::hex << "0x" << sdm_layer->input_buffer.buffer_id << std::dec << std::endl; } if (layer_stack_invalid_) { os << "\n Layers added or removed but not reflected to SDM's layer stack yet\n"; return os.str(); } if (color_mode_) { os << "\n----------Color Modes---------\n"; color_mode_->Dump(&os); } if (display_intf_) { os << "\n------------SDM----------------\n"; os << display_intf_->Dump(); } os << "\n"; return os.str(); } bool HWCDisplay::CanSkipValidate() { if (!validated_ || solid_fill_enable_) { return false; } // Layer Stack checks if ((layer_stack_.flags.hdr_present && (tone_mapper_ && tone_mapper_->IsActive())) || layer_stack_.flags.single_buffered_layer_present) { DLOGV_IF(kTagClient, "HDR content present with tone mapping enabled. Returning false."); return false; } if (client_target_->NeedsValidation()) { DLOGV_IF(kTagClient, "Framebuffer target needs validation. Returning false."); return false; } for (auto hwc_layer : layer_set_) { if (hwc_layer->NeedsValidation()) { DLOGV_IF(kTagClient, "hwc_layer[%d] needs validation. Returning false.", hwc_layer->GetId()); return false; } // Do not allow Skip Validate, if any layer needs GPU Composition. if (hwc_layer->GetDeviceSelectedCompositionType() == HWC2::Composition::Client) { DLOGV_IF(kTagClient, "hwc_layer[%d] is GPU composed. Returning false.", hwc_layer->GetId()); return false; } } return true; } HWC2::Error HWCDisplay::GetValidateDisplayOutput(uint32_t *out_num_types, uint32_t *out_num_requests) { *out_num_types = UINT32(layer_changes_.size()); *out_num_requests = UINT32(layer_requests_.size()); return ((*out_num_types > 0) ? HWC2::Error::HasChanges : HWC2::Error::None); } HWC2::Error HWCDisplay::SetDisplayedContentSamplingEnabledVndService(bool enabled) { return HWC2::Error::Unsupported; } HWC2::Error HWCDisplay::SetDisplayedContentSamplingEnabled(int32_t enabled, uint8_t component_mask, uint64_t max_frames) { DLOGV("Request to start/stop histogram thread not supported on this display"); return HWC2::Error::Unsupported; } HWC2::Error HWCDisplay::GetDisplayedContentSamplingAttributes(int32_t* format, int32_t* dataspace, uint8_t* supported_components) { return HWC2::Error::Unsupported; } HWC2::Error HWCDisplay::GetDisplayedContentSample(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 HWC2::Error::Unsupported; } void HWCDisplay::UpdateRefreshRate() { for (auto hwc_layer : layer_set_) { if (hwc_layer->HasMetaDataRefreshRate()) { continue; } auto layer = hwc_layer->GetSDMLayer(); layer->frame_rate = current_refresh_rate_; } Layer *sdm_client_target = client_target_->GetSDMLayer(); sdm_client_target->frame_rate = current_refresh_rate_; } // Skip SDM prepare if all the layers in the current draw cycle are marked as Skip and // previous draw cycle had GPU Composition, as the resources for GPU Target layer have // already been validated and configured to the driver. bool HWCDisplay::CanSkipSdmPrepare(uint32_t *num_types, uint32_t *num_requests) { if (!validated_ || layer_set_.empty()) { return false; } bool skip_prepare = true; for (auto hwc_layer : layer_set_) { if (!hwc_layer->GetSDMLayer()->flags.skip || (hwc_layer->GetDeviceSelectedCompositionType() != HWC2::Composition::Client)) { skip_prepare = false; layer_changes_.clear(); break; } if (hwc_layer->GetClientRequestedCompositionType() != HWC2::Composition::Client) { layer_changes_[hwc_layer->GetId()] = HWC2::Composition::Client; } } if (skip_prepare) { *num_types = UINT32(layer_changes_.size()); *num_requests = 0; layer_stack_invalid_ = false; has_client_composition_ = true; client_target_->ResetValidation(); validate_state_ = kNormalValidate; } return skip_prepare; } } // namespace sdm