/* * Copyright (c) 2013 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "modules/desktop_capture/linux/x11/x_server_pixel_buffer.h" #include #include #include #include #include #include "modules/desktop_capture/desktop_frame.h" #include "modules/desktop_capture/linux/x11/window_list_utils.h" #include "modules/desktop_capture/linux/x11/x_error_trap.h" #include "modules/desktop_capture/linux/x11/x_window_property.h" #include "rtc_base/checks.h" #include "rtc_base/logging.h" namespace webrtc { namespace { // Returns the number of bits `mask` has to be shifted left so its last // (most-significant) bit set becomes the most-significant bit of the word. // When `mask` is 0 the function returns 31. uint32_t MaskToShift(uint32_t mask) { int shift = 0; if ((mask & 0xffff0000u) == 0) { mask <<= 16; shift += 16; } if ((mask & 0xff000000u) == 0) { mask <<= 8; shift += 8; } if ((mask & 0xf0000000u) == 0) { mask <<= 4; shift += 4; } if ((mask & 0xc0000000u) == 0) { mask <<= 2; shift += 2; } if ((mask & 0x80000000u) == 0) shift += 1; return shift; } // Returns true if `image` is in RGB format. bool IsXImageRGBFormat(XImage* image) { return image->bits_per_pixel == 32 && image->red_mask == 0xff0000 && image->green_mask == 0xff00 && image->blue_mask == 0xff; } // We expose two forms of blitting to handle variations in the pixel format. // In FastBlit(), the operation is effectively a memcpy. void FastBlit(XImage* x_image, uint8_t* src_pos, const DesktopRect& rect, DesktopFrame* frame) { RTC_DCHECK_LE(frame->top_left().x(), rect.left()); RTC_DCHECK_LE(frame->top_left().y(), rect.top()); int src_stride = x_image->bytes_per_line; int dst_x = rect.left() - frame->top_left().x(); int dst_y = rect.top() - frame->top_left().y(); uint8_t* dst_pos = frame->data() + frame->stride() * dst_y; dst_pos += dst_x * DesktopFrame::kBytesPerPixel; int height = rect.height(); int row_bytes = rect.width() * DesktopFrame::kBytesPerPixel; for (int y = 0; y < height; ++y) { memcpy(dst_pos, src_pos, row_bytes); src_pos += src_stride; dst_pos += frame->stride(); } } void SlowBlit(XImage* x_image, uint8_t* src_pos, const DesktopRect& rect, DesktopFrame* frame) { RTC_DCHECK_LE(frame->top_left().x(), rect.left()); RTC_DCHECK_LE(frame->top_left().y(), rect.top()); int src_stride = x_image->bytes_per_line; int dst_x = rect.left() - frame->top_left().x(); int dst_y = rect.top() - frame->top_left().y(); int width = rect.width(), height = rect.height(); uint32_t red_mask = x_image->red_mask; uint32_t green_mask = x_image->red_mask; uint32_t blue_mask = x_image->blue_mask; uint32_t red_shift = MaskToShift(red_mask); uint32_t green_shift = MaskToShift(green_mask); uint32_t blue_shift = MaskToShift(blue_mask); int bits_per_pixel = x_image->bits_per_pixel; uint8_t* dst_pos = frame->data() + frame->stride() * dst_y; dst_pos += dst_x * DesktopFrame::kBytesPerPixel; // TODO(hclam): Optimize, perhaps using MMX code or by converting to // YUV directly. // TODO(sergeyu): This code doesn't handle XImage byte order properly and // won't work with 24bpp images. Fix it. for (int y = 0; y < height; y++) { uint32_t* dst_pos_32 = reinterpret_cast(dst_pos); uint32_t* src_pos_32 = reinterpret_cast(src_pos); uint16_t* src_pos_16 = reinterpret_cast(src_pos); for (int x = 0; x < width; x++) { // Dereference through an appropriately-aligned pointer. uint32_t pixel; if (bits_per_pixel == 32) { pixel = src_pos_32[x]; } else if (bits_per_pixel == 16) { pixel = src_pos_16[x]; } else { pixel = src_pos[x]; } uint32_t r = (pixel & red_mask) << red_shift; uint32_t g = (pixel & green_mask) << green_shift; uint32_t b = (pixel & blue_mask) << blue_shift; // Write as 32-bit RGB. dst_pos_32[x] = ((r >> 8) & 0xff0000) | ((g >> 16) & 0xff00) | ((b >> 24) & 0xff); } dst_pos += frame->stride(); src_pos += src_stride; } } } // namespace XServerPixelBuffer::XServerPixelBuffer() {} XServerPixelBuffer::~XServerPixelBuffer() { Release(); } void XServerPixelBuffer::Release() { if (x_image_) { XDestroyImage(x_image_); x_image_ = nullptr; } if (x_shm_image_) { XDestroyImage(x_shm_image_); x_shm_image_ = nullptr; } if (shm_pixmap_) { XFreePixmap(display_, shm_pixmap_); shm_pixmap_ = 0; } if (shm_gc_) { XFreeGC(display_, shm_gc_); shm_gc_ = nullptr; } ReleaseSharedMemorySegment(); window_ = 0; } void XServerPixelBuffer::ReleaseSharedMemorySegment() { if (!shm_segment_info_) return; if (shm_segment_info_->shmaddr != nullptr) shmdt(shm_segment_info_->shmaddr); if (shm_segment_info_->shmid != -1) shmctl(shm_segment_info_->shmid, IPC_RMID, 0); delete shm_segment_info_; shm_segment_info_ = nullptr; } bool XServerPixelBuffer::Init(XAtomCache* cache, Window window) { Release(); display_ = cache->display(); XWindowAttributes attributes; if (!GetWindowRect(display_, window, &window_rect_, &attributes)) { return false; } if (cache->IccProfile() != None) { // `window` is the root window when doing screen capture. XWindowProperty icc_profile_property(cache->display(), window, cache->IccProfile()); if (icc_profile_property.is_valid() && icc_profile_property.size() > 0) { icc_profile_ = std::vector( icc_profile_property.data(), icc_profile_property.data() + icc_profile_property.size()); } else { RTC_LOG(LS_WARNING) << "Failed to get icc profile"; } } window_ = window; InitShm(attributes); return true; } void XServerPixelBuffer::InitShm(const XWindowAttributes& attributes) { Visual* default_visual = attributes.visual; int default_depth = attributes.depth; int major, minor; Bool have_pixmaps; if (!XShmQueryVersion(display_, &major, &minor, &have_pixmaps)) { // Shared memory not supported. CaptureRect will use the XImage API instead. return; } bool using_shm = false; shm_segment_info_ = new XShmSegmentInfo; shm_segment_info_->shmid = -1; shm_segment_info_->shmaddr = nullptr; shm_segment_info_->readOnly = False; x_shm_image_ = XShmCreateImage(display_, default_visual, default_depth, ZPixmap, 0, shm_segment_info_, window_rect_.width(), window_rect_.height()); if (x_shm_image_) { shm_segment_info_->shmid = shmget(IPC_PRIVATE, x_shm_image_->bytes_per_line * x_shm_image_->height, IPC_CREAT | 0600); if (shm_segment_info_->shmid != -1) { void* shmat_result = shmat(shm_segment_info_->shmid, 0, 0); if (shmat_result != reinterpret_cast(-1)) { shm_segment_info_->shmaddr = reinterpret_cast(shmat_result); x_shm_image_->data = shm_segment_info_->shmaddr; XErrorTrap error_trap(display_); using_shm = XShmAttach(display_, shm_segment_info_); XSync(display_, False); if (error_trap.GetLastErrorAndDisable() != 0) using_shm = false; if (using_shm) { RTC_LOG(LS_VERBOSE) << "Using X shared memory segment " << shm_segment_info_->shmid; } } } else { RTC_LOG(LS_WARNING) << "Failed to get shared memory segment. " "Performance may be degraded."; } } if (!using_shm) { RTC_LOG(LS_WARNING) << "Not using shared memory. Performance may be degraded."; ReleaseSharedMemorySegment(); return; } if (have_pixmaps) have_pixmaps = InitPixmaps(default_depth); shmctl(shm_segment_info_->shmid, IPC_RMID, 0); shm_segment_info_->shmid = -1; RTC_LOG(LS_VERBOSE) << "Using X shared memory extension v" << major << "." << minor << " with" << (have_pixmaps ? "" : "out") << " pixmaps."; } bool XServerPixelBuffer::InitPixmaps(int depth) { if (XShmPixmapFormat(display_) != ZPixmap) return false; { XErrorTrap error_trap(display_); shm_pixmap_ = XShmCreatePixmap( display_, window_, shm_segment_info_->shmaddr, shm_segment_info_, window_rect_.width(), window_rect_.height(), depth); XSync(display_, False); if (error_trap.GetLastErrorAndDisable() != 0) { // `shm_pixmap_` is not not valid because the request was not processed // by the X Server, so zero it. shm_pixmap_ = 0; return false; } } { XErrorTrap error_trap(display_); XGCValues shm_gc_values; shm_gc_values.subwindow_mode = IncludeInferiors; shm_gc_values.graphics_exposures = False; shm_gc_ = XCreateGC(display_, window_, GCSubwindowMode | GCGraphicsExposures, &shm_gc_values); XSync(display_, False); if (error_trap.GetLastErrorAndDisable() != 0) { XFreePixmap(display_, shm_pixmap_); shm_pixmap_ = 0; shm_gc_ = 0; // See shm_pixmap_ comment above. return false; } } return true; } bool XServerPixelBuffer::IsWindowValid() const { XWindowAttributes attributes; { XErrorTrap error_trap(display_); if (!XGetWindowAttributes(display_, window_, &attributes) || error_trap.GetLastErrorAndDisable() != 0) { return false; } } return true; } void XServerPixelBuffer::Synchronize() { if (shm_segment_info_ && !shm_pixmap_) { // XShmGetImage can fail if the display is being reconfigured. XErrorTrap error_trap(display_); // XShmGetImage fails if the window is partially out of screen. xshm_get_image_succeeded_ = XShmGetImage(display_, window_, x_shm_image_, 0, 0, AllPlanes); } } bool XServerPixelBuffer::CaptureRect(const DesktopRect& rect, DesktopFrame* frame) { RTC_DCHECK_LE(rect.right(), window_rect_.width()); RTC_DCHECK_LE(rect.bottom(), window_rect_.height()); XImage* image; uint8_t* data; if (shm_segment_info_ && (shm_pixmap_ || xshm_get_image_succeeded_)) { if (shm_pixmap_) { XCopyArea(display_, window_, shm_pixmap_, shm_gc_, rect.left(), rect.top(), rect.width(), rect.height(), rect.left(), rect.top()); XSync(display_, False); } image = x_shm_image_; data = reinterpret_cast(image->data) + rect.top() * image->bytes_per_line + rect.left() * image->bits_per_pixel / 8; } else { if (x_image_) XDestroyImage(x_image_); x_image_ = XGetImage(display_, window_, rect.left(), rect.top(), rect.width(), rect.height(), AllPlanes, ZPixmap); if (!x_image_) return false; image = x_image_; data = reinterpret_cast(image->data); } if (IsXImageRGBFormat(image)) { FastBlit(image, data, rect, frame); } else { SlowBlit(image, data, rect, frame); } if (!icc_profile_.empty()) frame->set_icc_profile(icc_profile_); return true; } } // namespace webrtc