// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Note: ported from Chromium commit head: 09ea0d2 // Note: it's also merged with generic_v4l2_device.cc (head: a9d98e6) #include #include #include #include #include #include #include #include "base/numerics/safe_conversions.h" #include "base/posix/eintr_wrapper.h" #include "base/strings/stringprintf.h" #include "v4l2_device.h" #define DVLOGF(level) DVLOG(level) << __func__ << "(): " #define VLOGF(level) VLOG(level) << __func__ << "(): " #define VPLOGF(level) VPLOG(level) << __func__ << "(): " namespace media { V4L2Device::V4L2Device() {} V4L2Device::~V4L2Device() { CloseDevice(); } // static VideoPixelFormat V4L2Device::V4L2PixFmtToVideoPixelFormat(uint32_t pix_fmt) { switch (pix_fmt) { case V4L2_PIX_FMT_NV12: case V4L2_PIX_FMT_NV12M: return PIXEL_FORMAT_NV12; case V4L2_PIX_FMT_MT21: return PIXEL_FORMAT_MT21; case V4L2_PIX_FMT_YUV420: case V4L2_PIX_FMT_YUV420M: return PIXEL_FORMAT_I420; case V4L2_PIX_FMT_YVU420: return PIXEL_FORMAT_YV12; case V4L2_PIX_FMT_YUV422M: return PIXEL_FORMAT_I422; case V4L2_PIX_FMT_RGB32: return PIXEL_FORMAT_ARGB; default: DVLOGF(1) << "Add more cases as needed"; return PIXEL_FORMAT_UNKNOWN; } } // static uint32_t V4L2Device::VideoPixelFormatToV4L2PixFmt(VideoPixelFormat format) { switch (format) { case PIXEL_FORMAT_NV12: return V4L2_PIX_FMT_NV12M; case PIXEL_FORMAT_MT21: return V4L2_PIX_FMT_MT21; case PIXEL_FORMAT_I420: return V4L2_PIX_FMT_YUV420M; case PIXEL_FORMAT_YV12: return V4L2_PIX_FMT_YVU420; default: LOG(FATAL) << "Add more cases as needed"; return 0; } } // static uint32_t V4L2Device::VideoCodecProfileToV4L2PixFmt(VideoCodecProfile profile) { if (profile >= H264PROFILE_MIN && profile <= H264PROFILE_MAX) { return V4L2_PIX_FMT_H264; } else if (profile >= VP8PROFILE_MIN && profile <= VP8PROFILE_MAX) { return V4L2_PIX_FMT_VP8; } else if (profile >= VP9PROFILE_MIN && profile <= VP9PROFILE_MAX) { return V4L2_PIX_FMT_VP9; } else { LOG(FATAL) << "Add more cases as needed"; return 0; } } // static std::vector V4L2Device::V4L2PixFmtToVideoCodecProfiles( uint32_t pix_fmt, bool is_encoder) { VideoCodecProfile min_profile, max_profile; std::vector profiles; switch (pix_fmt) { case V4L2_PIX_FMT_H264: if (is_encoder) { // TODO(posciak): need to query the device for supported H.264 profiles, // for now choose Main as a sensible default. min_profile = H264PROFILE_MAIN; max_profile = H264PROFILE_MAIN; } else { min_profile = H264PROFILE_MIN; max_profile = H264PROFILE_MAX; } break; case V4L2_PIX_FMT_VP8: min_profile = VP8PROFILE_MIN; max_profile = VP8PROFILE_MAX; break; case V4L2_PIX_FMT_VP9: min_profile = VP9PROFILE_MIN; max_profile = VP9PROFILE_MAX; break; default: VLOGF(1) << "Unhandled pixelformat " << std::hex << "0x" << pix_fmt; return profiles; } for (int profile = min_profile; profile <= max_profile; ++profile) profiles.push_back(static_cast(profile)); return profiles; } int V4L2Device::Ioctl(int request, void* arg) { DCHECK(device_fd_.is_valid()); return HANDLE_EINTR(ioctl(device_fd_.get(), request, arg)); } bool V4L2Device::Poll(bool poll_device, bool* event_pending) { struct pollfd pollfds[2]; nfds_t nfds; int pollfd = -1; pollfds[0].fd = device_poll_interrupt_fd_.get(); pollfds[0].events = POLLIN | POLLERR; nfds = 1; if (poll_device) { DVLOGF(5) << "Poll(): adding device fd to poll() set"; pollfds[nfds].fd = device_fd_.get(); pollfds[nfds].events = POLLIN | POLLOUT | POLLERR | POLLPRI; pollfd = nfds; nfds++; } if (HANDLE_EINTR(poll(pollfds, nfds, -1)) == -1) { VPLOGF(1) << "poll() failed"; return false; } *event_pending = (pollfd != -1 && pollfds[pollfd].revents & POLLPRI); return true; } void* V4L2Device::Mmap(void* addr, unsigned int len, int prot, int flags, unsigned int offset) { DCHECK(device_fd_.is_valid()); return mmap(addr, len, prot, flags, device_fd_.get(), offset); } void V4L2Device::Munmap(void* addr, unsigned int len) { munmap(addr, len); } bool V4L2Device::SetDevicePollInterrupt() { DVLOGF(4); const uint64_t buf = 1; if (HANDLE_EINTR(write(device_poll_interrupt_fd_.get(), &buf, sizeof(buf))) == -1) { VPLOGF(1) << "write() failed"; return false; } return true; } bool V4L2Device::ClearDevicePollInterrupt() { DVLOGF(5); uint64_t buf; if (HANDLE_EINTR(read(device_poll_interrupt_fd_.get(), &buf, sizeof(buf))) == -1) { if (errno == EAGAIN) { // No interrupt flag set, and we're reading nonblocking. Not an error. return true; } else { VPLOGF(1) << "read() failed"; return false; } } return true; } bool V4L2Device::Open(Type type, uint32_t v4l2_pixfmt) { VLOGF(2); std::string path = GetDevicePathFor(type, v4l2_pixfmt); if (path.empty()) { VLOGF(1) << "No devices supporting " << std::hex << "0x" << v4l2_pixfmt << " for type: " << static_cast(type); return false; } if (!OpenDevicePath(path, type)) { VLOGF(1) << "Failed opening " << path; return false; } device_poll_interrupt_fd_.reset(eventfd(0, EFD_NONBLOCK | EFD_CLOEXEC)); if (!device_poll_interrupt_fd_.is_valid()) { VLOGF(1) << "Failed creating a poll interrupt fd"; return false; } return true; } std::vector V4L2Device::GetDmabufsForV4L2Buffer( int index, size_t num_planes, enum v4l2_buf_type buf_type) { VLOGF(2); DCHECK(V4L2_TYPE_IS_MULTIPLANAR(buf_type)); std::vector dmabuf_fds; for (size_t i = 0; i < num_planes; ++i) { struct v4l2_exportbuffer expbuf; memset(&expbuf, 0, sizeof(expbuf)); expbuf.type = buf_type; expbuf.index = index; expbuf.plane = i; expbuf.flags = O_CLOEXEC; if (Ioctl(VIDIOC_EXPBUF, &expbuf) != 0) { dmabuf_fds.clear(); break; } dmabuf_fds.push_back(base::ScopedFD(expbuf.fd)); } return dmabuf_fds; } VideoDecodeAccelerator::SupportedProfiles V4L2Device::GetSupportedDecodeProfiles(const size_t num_formats, const uint32_t pixelformats[]) { VideoDecodeAccelerator::SupportedProfiles supported_profiles; Type type = Type::kDecoder; const auto& devices = GetDevicesForType(type); for (const auto& device : devices) { if (!OpenDevicePath(device.first, type)) { VLOGF(1) << "Failed opening " << device.first; continue; } const auto& profiles = EnumerateSupportedDecodeProfiles(num_formats, pixelformats); supported_profiles.insert(supported_profiles.end(), profiles.begin(), profiles.end()); CloseDevice(); } return supported_profiles; } void V4L2Device::GetSupportedResolution(uint32_t pixelformat, Size* min_resolution, Size* max_resolution) { max_resolution->SetSize(0, 0); min_resolution->SetSize(0, 0); v4l2_frmsizeenum frame_size; memset(&frame_size, 0, sizeof(frame_size)); frame_size.pixel_format = pixelformat; for (; Ioctl(VIDIOC_ENUM_FRAMESIZES, &frame_size) == 0; ++frame_size.index) { if (frame_size.type == V4L2_FRMSIZE_TYPE_DISCRETE) { if (frame_size.discrete.width >= base::checked_cast(max_resolution->width()) && frame_size.discrete.height >= base::checked_cast(max_resolution->height())) { max_resolution->SetSize(frame_size.discrete.width, frame_size.discrete.height); } if (min_resolution->IsEmpty() || (frame_size.discrete.width <= base::checked_cast(min_resolution->width()) && frame_size.discrete.height <= base::checked_cast(min_resolution->height()))) { min_resolution->SetSize(frame_size.discrete.width, frame_size.discrete.height); } } else if (frame_size.type == V4L2_FRMSIZE_TYPE_STEPWISE || frame_size.type == V4L2_FRMSIZE_TYPE_CONTINUOUS) { max_resolution->SetSize(frame_size.stepwise.max_width, frame_size.stepwise.max_height); min_resolution->SetSize(frame_size.stepwise.min_width, frame_size.stepwise.min_height); break; } } if (max_resolution->IsEmpty()) { max_resolution->SetSize(1920, 1088); VLOGF(1) << "GetSupportedResolution failed to get maximum resolution for " << "fourcc " << std::hex << pixelformat << ", fall back to " << max_resolution->ToString(); } if (min_resolution->IsEmpty()) { min_resolution->SetSize(16, 16); VLOGF(1) << "GetSupportedResolution failed to get minimum resolution for " << "fourcc " << std::hex << pixelformat << ", fall back to " << min_resolution->ToString(); } } std::vector V4L2Device::EnumerateSupportedPixelformats( v4l2_buf_type buf_type) { std::vector pixelformats; v4l2_fmtdesc fmtdesc; memset(&fmtdesc, 0, sizeof(fmtdesc)); fmtdesc.type = buf_type; for (; Ioctl(VIDIOC_ENUM_FMT, &fmtdesc) == 0; ++fmtdesc.index) { DVLOGF(3) << "Found " << fmtdesc.description << std::hex << " (0x" << fmtdesc.pixelformat << ")"; pixelformats.push_back(fmtdesc.pixelformat); } return pixelformats; } VideoDecodeAccelerator::SupportedProfiles V4L2Device::EnumerateSupportedDecodeProfiles(const size_t num_formats, const uint32_t pixelformats[]) { VideoDecodeAccelerator::SupportedProfiles profiles; const auto& supported_pixelformats = EnumerateSupportedPixelformats(V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE); for (uint32_t pixelformat : supported_pixelformats) { if (std::find(pixelformats, pixelformats + num_formats, pixelformat) == pixelformats + num_formats) continue; VideoDecodeAccelerator::SupportedProfile profile; GetSupportedResolution(pixelformat, &profile.min_resolution, &profile.max_resolution); const auto video_codec_profiles = V4L2PixFmtToVideoCodecProfiles(pixelformat, false); for (const auto& video_codec_profile : video_codec_profiles) { profile.profile = video_codec_profile; profiles.push_back(profile); DVLOGF(3) << "Found decoder profile " << GetProfileName(profile.profile) << ", resolutions: " << profile.min_resolution.ToString() << " " << profile.max_resolution.ToString(); } } return profiles; } bool V4L2Device::OpenDevicePath(const std::string& path, Type type) { DCHECK(!device_fd_.is_valid()); device_fd_.reset( HANDLE_EINTR(open(path.c_str(), O_RDWR | O_NONBLOCK | O_CLOEXEC))); if (!device_fd_.is_valid()) return false; return true; } void V4L2Device::CloseDevice() { VLOGF(2); device_fd_.reset(); } void V4L2Device::EnumerateDevicesForType(Type type) { static const std::string kDecoderDevicePattern = "/dev/video-dec"; std::string device_pattern; v4l2_buf_type buf_type; switch (type) { case Type::kDecoder: device_pattern = kDecoderDevicePattern; buf_type = V4L2_BUF_TYPE_VIDEO_OUTPUT_MPLANE; break; default: LOG(ERROR) << "Only decoder type is supported!!"; return; } std::vector candidate_paths; // TODO(posciak): Remove this legacy unnumbered device once // all platforms are updated to use numbered devices. candidate_paths.push_back(device_pattern); // We are sandboxed, so we can't query directory contents to check which // devices are actually available. Try to open the first 10; if not present, // we will just fail to open immediately. for (int i = 0; i < 10; ++i) { candidate_paths.push_back( base::StringPrintf("%s%d", device_pattern.c_str(), i)); } Devices devices; for (const auto& path : candidate_paths) { if (!OpenDevicePath(path, type)) continue; const auto& supported_pixelformats = EnumerateSupportedPixelformats(buf_type); if (!supported_pixelformats.empty()) { DVLOGF(3) << "Found device: " << path; devices.push_back(std::make_pair(path, supported_pixelformats)); } CloseDevice(); } DCHECK_EQ(devices_by_type_.count(type), 0u); devices_by_type_[type] = devices; } const V4L2Device::Devices& V4L2Device::GetDevicesForType(Type type) { if (devices_by_type_.count(type) == 0) EnumerateDevicesForType(type); DCHECK_NE(devices_by_type_.count(type), 0u); return devices_by_type_[type]; } std::string V4L2Device::GetDevicePathFor(Type type, uint32_t pixfmt) { const Devices& devices = GetDevicesForType(type); for (const auto& device : devices) { if (std::find(device.second.begin(), device.second.end(), pixfmt) != device.second.end()) return device.first; } return std::string(); } } // namespace media