/* * Copyright (C) 2016 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 "vsoc_composer.h" #include #include #include #include #include #include #include #include #include #include "common/vsoc/lib/screen_region_view.h" #include "geometry_utils.h" using vsoc::screen::ScreenRegionView; namespace cvd { namespace { bool LayerNeedsScaling(const vsoc_hwc_layer& layer) { int from_w = layer.sourceCrop.right - layer.sourceCrop.left; int from_h = layer.sourceCrop.bottom - layer.sourceCrop.top; int to_w = layer.displayFrame.right - layer.displayFrame.left; int to_h = layer.displayFrame.bottom - layer.displayFrame.top; bool not_rot_scale = from_w != to_w || from_h != to_h; bool rot_scale = from_w != to_h || from_h != to_w; bool needs_rot = layer.transform & HAL_TRANSFORM_ROT_90; return needs_rot ? rot_scale : not_rot_scale; } bool LayerNeedsBlending(const vsoc_hwc_layer& layer) { return layer.blending != HWC_BLENDING_NONE; } bool LayerNeedsAttenuation(const vsoc_hwc_layer& layer) { return layer.blending == HWC_BLENDING_COVERAGE; } struct BufferSpec; typedef int (*ConverterFunction)(const BufferSpec& src, const BufferSpec& dst, bool v_flip); int DoCopy(const BufferSpec& src, const BufferSpec& dst, bool v_flip); int ConvertFromYV12(const BufferSpec& src, const BufferSpec& dst, bool v_flip); ConverterFunction GetConverter(uint32_t format) { switch (format) { case HAL_PIXEL_FORMAT_RGBA_8888: case HAL_PIXEL_FORMAT_RGBX_8888: case HAL_PIXEL_FORMAT_IMPLEMENTATION_DEFINED: return &DoCopy; case HAL_PIXEL_FORMAT_YV12: return &ConvertFromYV12; // Unsupported formats // TODO(jemoreira): Conversion from these formats should be implemented as // we find evidence of its usage. // case HAL_PIXEL_FORMAT_BGRA_8888: // case HAL_PIXEL_FORMAT_RGB_888: // case HAL_PIXEL_FORMAT_RGB_565: // case HAL_PIXEL_FORMAT_sRGB_A_8888: // case HAL_PIXEL_FORMAT_sRGB_X_8888: // case HAL_PIXEL_FORMAT_Y8: // case HAL_PIXEL_FORMAT_Y16: // case HAL_PIXEL_FORMAT_RAW_SENSOR: // case HAL_PIXEL_FORMAT_BLOB: // case HAL_PIXEL_FORMAT_YCbCr_420_888: // case HAL_PIXEL_FORMAT_YCbCr_422_SP: // case HAL_PIXEL_FORMAT_YCrCb_420_SP: // case HAL_PIXEL_FORMAT_YCbCr_422_I: default: ALOGW("Unsupported format: 0x%04x, returning null converter function", format); } return NULL; } // Whether we support a given format bool IsFormatSupported(uint32_t format) { return GetConverter(format) != NULL; } bool CanCompositeLayer(const vsoc_hwc_layer& layer) { if (layer.handle == NULL) { ALOGW("%s received a layer with a null handler", __FUNCTION__); return false; } int format = reinterpret_cast(layer.handle)->format; if (!IsFormatSupported(format)) { ALOGD("Unsupported pixel format: 0x%x, doing software composition instead", format); return false; } return true; } /******************************************************************************* Libyuv's convert functions only allow the combination of any rotation (multiple of 90 degrees) and a vertical flip, but not horizontal flips. Surfaceflinger's transformations are expressed in terms of a vertical flip, a horizontal flip and/or a single 90 degrees clockwise rotation (see NATIVE_WINDOW_TRANSFORM_HINT documentation on system/window.h for more insight). The following code allows to turn a horizontal flip into a 180 degrees rotation and a vertical flip. *******************************************************************************/ libyuv::RotationMode GetRotationFromTransform(uint32_t transform) { uint32_t rotation = (transform & HAL_TRANSFORM_ROT_90) ? 1 : 0; // 1 * ROT90 bit rotation += (transform & HAL_TRANSFORM_FLIP_H) ? 2 : 0; // 2 * VFLIP bit return static_cast(90 * rotation); } bool GetVFlipFromTransform(uint32_t transform) { // vertical flip xor horizontal flip return ((transform & HAL_TRANSFORM_FLIP_V) >> 1) ^ (transform & HAL_TRANSFORM_FLIP_H); } struct BufferSpec { uint8_t* buffer; size_t size; int width; int height; int stride; int crop_x; int crop_y; int crop_width; int crop_height; uint32_t format; BufferSpec(uint8_t* buffer, size_t size, int width, int height, int stride) : buffer(buffer), size(size), width(width), height(height), stride(stride), crop_x(0), crop_y(0), crop_width(width), crop_height(height), format(HAL_PIXEL_FORMAT_RGBA_8888) {} }; int ConvertFromYV12(const BufferSpec& src, const BufferSpec& dst, bool v_flip) { // use the stride in pixels as the source width int stride_in_pixels = src.stride / formatToBytesPerPixel(src.format); // The following calculation of plane offsets and alignments are based on // swiftshader's Sampler::setTextureLevel() implementation // (Renderer/Sampler.cpp:225) uint8_t* src_y = src.buffer; int stride_y = stride_in_pixels; uint8_t* src_v = src_y + stride_y * src.height; int stride_v = ScreenRegionView::align(stride_y / 2, 16); uint8_t* src_u = src_v + stride_v * src.height / 2; int stride_u = ScreenRegionView::align(stride_y / 2, 16); // Adjust for crop src_y += src.crop_y * stride_y + src.crop_x; src_v += (src.crop_y / 2) * stride_v + (src.crop_x / 2); src_u += (src.crop_y / 2) * stride_u + (src.crop_x / 2); uint8_t* dst_buffer = dst.buffer + dst.crop_y * dst.stride + dst.crop_x * formatToBytesPerPixel(dst.format); // YV12 is the same as I420, with the U and V planes swapped return libyuv::I420ToARGB(src_y, stride_y, src_v, stride_v, src_u, stride_u, dst_buffer, dst.stride, dst.crop_width, v_flip ? -dst.crop_height : dst.crop_height); } int DoConversion(const BufferSpec& src, const BufferSpec& dst, bool v_flip) { return (*GetConverter(src.format))(src, dst, v_flip); } int DoCopy(const BufferSpec& src, const BufferSpec& dst, bool v_flip) { // Point to the upper left corner of the crop rectangle uint8_t* src_buffer = src.buffer + src.crop_y * src.stride + src.crop_x * formatToBytesPerPixel(src.format); uint8_t* dst_buffer = dst.buffer + dst.crop_y * dst.stride + dst.crop_x * formatToBytesPerPixel(dst.format); int width = src.crop_width; int height = src.crop_height; if (v_flip) { height = -height; } // HAL formats are named based on the order of the pixel componets on the // byte stream, while libyuv formats are named based on the order of those // pixel components in an integer written from left to right. So // libyuv::FOURCC_ARGB is equivalent to HAL_PIXEL_FORMAT_BGRA_8888. return libyuv::ARGBCopy(src_buffer, src.stride, dst_buffer, dst.stride, width, height); } int DoRotation(const BufferSpec& src, const BufferSpec& dst, libyuv::RotationMode rotation, bool v_flip) { // Point to the upper left corner of the crop rectangles uint8_t* src_buffer = src.buffer + src.crop_y * src.stride + src.crop_x * formatToBytesPerPixel(src.format); uint8_t* dst_buffer = dst.buffer + dst.crop_y * dst.stride + dst.crop_x * formatToBytesPerPixel(dst.format); int width = src.crop_width; int height = src.crop_height; if (v_flip) { height = -height; } return libyuv::ARGBRotate(src_buffer, src.stride, dst_buffer, dst.stride, width, height, rotation); } int DoScaling(const BufferSpec& src, const BufferSpec& dst, bool v_flip) { // Point to the upper left corner of the crop rectangles uint8_t* src_buffer = src.buffer + src.crop_y * src.stride + src.crop_x * formatToBytesPerPixel(src.format); uint8_t* dst_buffer = dst.buffer + dst.crop_y * dst.stride + dst.crop_x * formatToBytesPerPixel(dst.format); int src_width = src.crop_width; int src_height = src.crop_height; int dst_width = dst.crop_width; int dst_height = dst.crop_height; if (v_flip) { src_height = -src_height; } return libyuv::ARGBScale(src_buffer, src.stride, src_width, src_height, dst_buffer, dst.stride, dst_width, dst_height, libyuv::kFilterBilinear); } int DoAttenuation(const BufferSpec& src, const BufferSpec& dest, bool v_flip) { // Point to the upper left corner of the crop rectangles uint8_t* src_buffer = src.buffer + src.crop_y * src.stride + src.crop_x * formatToBytesPerPixel(src.format); uint8_t* dst_buffer = dest.buffer + dest.crop_y * dest.stride + dest.crop_x * formatToBytesPerPixel(dest.format); int width = dest.crop_width; int height = dest.crop_height; if (v_flip) { height = -height; } return libyuv::ARGBAttenuate(src_buffer, src.stride, dst_buffer, dest.stride, width, height); } int DoBlending(const BufferSpec& src, const BufferSpec& dest, bool v_flip) { // Point to the upper left corner of the crop rectangles uint8_t* src_buffer = src.buffer + src.crop_y * src.stride + src.crop_x * formatToBytesPerPixel(src.format); uint8_t* dst_buffer = dest.buffer + dest.crop_y * dest.stride + dest.crop_x * formatToBytesPerPixel(dest.format); int width = dest.crop_width; int height = dest.crop_height; if (v_flip) { height = -height; } // libyuv's ARGB format is hwcomposer's BGRA format, since blending only cares // for the position of alpha in the pixel and not the position of the colors // this function is perfectly usable. return libyuv::ARGBBlend(src_buffer, src.stride, dst_buffer, dest.stride, dst_buffer, dest.stride, width, height); } } // namespace void VSoCComposer::CompositeLayer(vsoc_hwc_layer* src_layer, int buffer_idx) { libyuv::RotationMode rotation = GetRotationFromTransform(src_layer->transform); const private_handle_t* src_priv_handle = reinterpret_cast(src_layer->handle); // TODO(jemoreira): Remove the hardcoded fomat. bool needs_conversion = src_priv_handle->format != HAL_PIXEL_FORMAT_RGBX_8888; bool needs_scaling = LayerNeedsScaling(*src_layer); bool needs_rotation = rotation != libyuv::kRotate0; bool needs_transpose = needs_rotation && rotation != libyuv::kRotate180; bool needs_vflip = GetVFlipFromTransform(src_layer->transform); bool needs_attenuation = LayerNeedsAttenuation(*src_layer); bool needs_blending = LayerNeedsBlending(*src_layer); bool needs_copy = !(needs_conversion || needs_scaling || needs_rotation || needs_vflip || needs_attenuation || needs_blending); uint8_t* src_buffer; uint8_t* dst_buffer = reinterpret_cast( ScreenRegionView::GetInstance()->GetBuffer(buffer_idx)); int retval = gralloc_module_->lock( gralloc_module_, src_layer->handle, GRALLOC_USAGE_SW_READ_OFTEN, 0, 0, src_priv_handle->x_res, src_priv_handle->y_res, reinterpret_cast(&src_buffer)); if (retval) { ALOGE("Got error code %d from lock function", retval); return; } if (retval) { ALOGE("Got error code %d from lock function", retval); // TODO(jemoreira): Use a lock_guard-like object. gralloc_module_->unlock(gralloc_module_, src_priv_handle); return; } BufferSpec src_layer_spec(src_buffer, src_priv_handle->total_size, src_priv_handle->x_res, src_priv_handle->y_res, src_priv_handle->stride_in_pixels * formatToBytesPerPixel(src_priv_handle->format)); src_layer_spec.crop_x = src_layer->sourceCrop.left; src_layer_spec.crop_y = src_layer->sourceCrop.top; src_layer_spec.crop_width = src_layer->sourceCrop.right - src_layer->sourceCrop.left; src_layer_spec.crop_height = src_layer->sourceCrop.bottom - src_layer->sourceCrop.top; src_layer_spec.format = src_priv_handle->format; auto screen_view = ScreenRegionView::GetInstance(); BufferSpec dst_layer_spec(dst_buffer, screen_view->buffer_size(), screen_view->x_res(), screen_view->y_res(), screen_view->line_length()); dst_layer_spec.crop_x = src_layer->displayFrame.left; dst_layer_spec.crop_y = src_layer->displayFrame.top; dst_layer_spec.crop_width = src_layer->displayFrame.right - src_layer->displayFrame.left; dst_layer_spec.crop_height = src_layer->displayFrame.bottom - src_layer->displayFrame.top; // TODO(jemoreira): Remove the hardcoded fomat. dst_layer_spec.format = HAL_PIXEL_FORMAT_RGBX_8888; // Add the destination layer to the bottom of the buffer stack std::vector dest_buffer_stack(1, dst_layer_spec); // If more than operation is to be performed, a temporary buffer is needed for // each additional operation // N operations need N destination buffers, the destination layer (the // framebuffer) is one of them, so only N-1 temporary buffers are needed. // Vertical flip is not taken into account because it can be done together // with any other operation. int needed_tmp_buffers = (needs_conversion ? 1 : 0) + (needs_scaling ? 1 : 0) + (needs_rotation ? 1 : 0) + (needs_attenuation ? 1 : 0) + (needs_blending ? 1 : 0) + (needs_copy ? 1 : 0) - 1; int x_res = src_layer->displayFrame.right - src_layer->displayFrame.left; int y_res = src_layer->displayFrame.bottom - src_layer->displayFrame.top; size_t output_frame_size = x_res * ScreenRegionView::align(y_res * screen_view->bytes_per_pixel(), 16); while (needed_tmp_buffers > 0) { BufferSpec tmp(RotateTmpBuffer(needed_tmp_buffers), output_frame_size, x_res, y_res, ScreenRegionView::align( x_res * screen_view->bytes_per_pixel(), 16)); dest_buffer_stack.push_back(tmp); needed_tmp_buffers--; } // Conversion and scaling should always be the first operations, so that every // other operation works on equally sized frames (garanteed to fit in the tmp // buffers) // TODO(jemoreira): We are converting to ARGB as the first step under the // assumption that scaling ARGB is faster than scaling I420 (the most common). // This should be confirmed with testing. if (needs_conversion) { BufferSpec& dst_buffer_spec = dest_buffer_stack.back(); if (needs_scaling || needs_transpose) { // If a rotation or a scaling operation are needed the dimensions at the // top of the buffer stack are wrong (wrong sizes for scaling, swapped // width and height for 90 and 270 rotations). // Make width and height match the crop sizes on the source int src_width = src_layer_spec.crop_width; int src_height = src_layer_spec.crop_height; int dst_stride = ScreenRegionView::align( src_width * screen_view->bytes_per_pixel(), 16); size_t needed_size = dst_stride * src_height; dst_buffer_spec.width = src_width; dst_buffer_spec.height = src_height; // Ajust the stride accordingly dst_buffer_spec.stride = dst_stride; // Crop sizes also need to be adjusted dst_buffer_spec.crop_width = src_width; dst_buffer_spec.crop_height = src_height; dst_buffer_spec.size = needed_size; // crop_x and y are fine at 0, format is already set to match destination // In case of a scale, the source frame may be bigger than the default tmp // buffer size if (needed_size > tmp_buffer_.size() / kNumTmpBufferPieces) { dst_buffer_spec.buffer = GetSpecialTmpBuffer(needed_size); } } retval = DoConversion(src_layer_spec, dst_buffer_spec, needs_vflip); if (retval) { ALOGE("Got error code %d from DoConversion function", retval); } needs_vflip = false; src_layer_spec = dst_buffer_spec; dest_buffer_stack.pop_back(); } if (needs_scaling) { BufferSpec& dst_buffer_spec = dest_buffer_stack.back(); if (needs_transpose) { // If a rotation is needed, the temporary buffer has the correct size but // needs to be transposed and have its stride updated accordingly. The // crop sizes also needs to be transposed, but not the x and y since they // are both zero in a temporary buffer (and it is a temporary buffer // because a rotation will be performed next). std::swap(dst_buffer_spec.width, dst_buffer_spec.height); std::swap(dst_buffer_spec.crop_width, dst_buffer_spec.crop_height); // TODO (jemoreira): Aligment (To align here may cause the needed size to // be bigger than the buffer, so care should be taken) dst_buffer_spec.stride = dst_buffer_spec.width * screen_view->bytes_per_pixel(); } retval = DoScaling(src_layer_spec, dst_buffer_spec, needs_vflip); needs_vflip = false; if (retval) { ALOGE("Got error code %d from DoScaling function", retval); } src_layer_spec = dst_buffer_spec; dest_buffer_stack.pop_back(); } if (needs_rotation) { retval = DoRotation(src_layer_spec, dest_buffer_stack.back(), rotation, needs_vflip); needs_vflip = false; if (retval) { ALOGE("Got error code %d from DoTransform function", retval); } src_layer_spec = dest_buffer_stack.back(); dest_buffer_stack.pop_back(); } if (needs_attenuation) { retval = DoAttenuation(src_layer_spec, dest_buffer_stack.back(), needs_vflip); needs_vflip = false; if (retval) { ALOGE("Got error code %d from DoBlending function", retval); } src_layer_spec = dest_buffer_stack.back(); dest_buffer_stack.pop_back(); } if (needs_copy) { retval = DoCopy(src_layer_spec, dest_buffer_stack.back(), needs_vflip); needs_vflip = false; if (retval) { ALOGE("Got error code %d from DoBlending function", retval); } src_layer_spec = dest_buffer_stack.back(); dest_buffer_stack.pop_back(); } // Blending (if needed) should always be the last operation, so that it reads // and writes in the destination layer and not some temporary buffer. if (needs_blending) { retval = DoBlending(src_layer_spec, dest_buffer_stack.back(), needs_vflip); needs_vflip = false; if (retval) { ALOGE("Got error code %d from DoBlending function", retval); } // Don't need to assign destination to source in the last one dest_buffer_stack.pop_back(); } gralloc_module_->unlock(gralloc_module_, src_priv_handle); } /* static */ const int VSoCComposer::kNumTmpBufferPieces = 2; VSoCComposer::VSoCComposer(int64_t vsync_base_timestamp, int32_t vsync_period_ns) : BaseComposer(vsync_base_timestamp, vsync_period_ns), tmp_buffer_(kNumTmpBufferPieces * ScreenRegionView::GetInstance()->buffer_size()) {} VSoCComposer::~VSoCComposer() {} int VSoCComposer::PrepareLayers(size_t num_layers, vsoc_hwc_layer* layers) { int composited_layers_count = 0; // Loop over layers in inverse order of z-index for (size_t layer_index = num_layers; layer_index > 0;) { // Decrement here to be able to compare unsigned integer with 0 in the // loop condition --layer_index; if (IS_TARGET_FRAMEBUFFER(layers[layer_index].compositionType)) { continue; } if (layers[layer_index].flags & HWC_SKIP_LAYER) { continue; } if (layers[layer_index].compositionType == HWC_BACKGROUND) { layers[layer_index].compositionType = HWC_FRAMEBUFFER; continue; } layers[layer_index].compositionType = HWC_OVERLAY; // Hwcomposer cannot draw below software-composed layers, so we need // to mark those HWC_FRAMEBUFFER as well. for (size_t top_idx = layer_index + 1; top_idx < num_layers; ++top_idx) { // layers marked as skip are in a state that makes them unreliable to // read, so it's best to assume they cover the whole screen if (layers[top_idx].flags & HWC_SKIP_LAYER || (layers[top_idx].compositionType == HWC_FRAMEBUFFER && LayersOverlap(layers[layer_index], layers[top_idx]))) { layers[layer_index].compositionType = HWC_FRAMEBUFFER; break; } } if (layers[layer_index].compositionType == HWC_OVERLAY && !CanCompositeLayer(layers[layer_index])) { layers[layer_index].compositionType = HWC_FRAMEBUFFER; } if (layers[layer_index].compositionType == HWC_OVERLAY) { ++composited_layers_count; } } return composited_layers_count; } int VSoCComposer::SetLayers(size_t num_layers, vsoc_hwc_layer* layers) { int targetFbs = 0; int buffer_idx = NextScreenBuffer(); // The framebuffer target layer should be composed if at least one layers was // marked HWC_FRAMEBUFFER or if it's the only layer in the composition // (unlikely) bool fb_target = true; for (size_t idx = 0; idx < num_layers; idx++) { if (layers[idx].compositionType == HWC_FRAMEBUFFER) { // At least one was found fb_target = true; break; } if (layers[idx].compositionType == HWC_OVERLAY) { // Not the only layer in the composition fb_target = false; } } // When the framebuffer target needs to be composed, it has to go first. if (fb_target) { for (size_t idx = 0; idx < num_layers; idx++) { if (IS_TARGET_FRAMEBUFFER(layers[idx].compositionType)) { CompositeLayer(&layers[idx], buffer_idx); break; } } } for (size_t idx = 0; idx < num_layers; idx++) { if (IS_TARGET_FRAMEBUFFER(layers[idx].compositionType)) { ++targetFbs; } if (layers[idx].compositionType == HWC_OVERLAY && !(layers[idx].flags & HWC_SKIP_LAYER)) { CompositeLayer(&layers[idx], buffer_idx); } } if (targetFbs != 1) { ALOGW("Saw %zu layers, posted=%d", num_layers, targetFbs); } Broadcast(buffer_idx); return 0; } uint8_t* VSoCComposer::RotateTmpBuffer(unsigned int order) { return &tmp_buffer_[(order % kNumTmpBufferPieces) * tmp_buffer_.size() / kNumTmpBufferPieces]; } uint8_t* VSoCComposer::GetSpecialTmpBuffer(size_t needed_size) { special_tmp_buffer_.resize(needed_size); return &special_tmp_buffer_[0]; } } // namespace cvd