/* SPDX-License-Identifier: LGPL-2.1-or-later */ /* * Copyright (C) 2023, Linaro Ltd * Copyright (C) 2023, Red Hat Inc. * * Authors: * Hans de Goede * * debayer_cpu.cpp - CPU based debayering class */ #include "debayer_cpu.h" #include #include #include #include #include "libcamera/internal/bayer_format.h" #include "libcamera/internal/framebuffer.h" #include "libcamera/internal/mapped_framebuffer.h" namespace libcamera { /** * \class DebayerCpu * \brief Class for debayering on the CPU * * Implementation for CPU based debayering */ /** * \brief Constructs a DebayerCpu object * \param[in] stats Pointer to the stats object to use */ DebayerCpu::DebayerCpu(std::unique_ptr stats) : stats_(std::move(stats)), gammaCorrection_(1.0), blackLevel_(0) { /* * Reading from uncached buffers may be very slow. * In such a case, it's better to copy input buffer data to normal memory. * But in case of cached buffers, copying the data is unnecessary overhead. * enable_input_memcpy_ makes this behavior configurable. At the moment, we * always set it to true as the safer choice but this should be changed in * future. */ enableInputMemcpy_ = true; /* Initialize gamma to 1.0 curve */ for (unsigned int i = 0; i < kGammaLookupSize; i++) gamma_[i] = i / (kGammaLookupSize / kRGBLookupSize); for (unsigned int i = 0; i < kMaxLineBuffers; i++) lineBuffers_[i] = nullptr; } DebayerCpu::~DebayerCpu() { for (unsigned int i = 0; i < kMaxLineBuffers; i++) free(lineBuffers_[i]); } #define DECLARE_SRC_POINTERS(pixel_t) \ const pixel_t *prev = (const pixel_t *)src[0] + xShift_; \ const pixel_t *curr = (const pixel_t *)src[1] + xShift_; \ const pixel_t *next = (const pixel_t *)src[2] + xShift_; /* * RGR * GBG * RGR */ #define BGGR_BGR888(p, n, div) \ *dst++ = blue_[curr[x] / (div)]; \ *dst++ = green_[(prev[x] + curr[x - p] + curr[x + n] + next[x]) / (4 * (div))]; \ *dst++ = red_[(prev[x - p] + prev[x + n] + next[x - p] + next[x + n]) / (4 * (div))]; \ x++; /* * GBG * RGR * GBG */ #define GRBG_BGR888(p, n, div) \ *dst++ = blue_[(prev[x] + next[x]) / (2 * (div))]; \ *dst++ = green_[curr[x] / (div)]; \ *dst++ = red_[(curr[x - p] + curr[x + n]) / (2 * (div))]; \ x++; /* * GRG * BGB * GRG */ #define GBRG_BGR888(p, n, div) \ *dst++ = blue_[(curr[x - p] + curr[x + n]) / (2 * (div))]; \ *dst++ = green_[curr[x] / (div)]; \ *dst++ = red_[(prev[x] + next[x]) / (2 * (div))]; \ x++; /* * BGB * GRG * BGB */ #define RGGB_BGR888(p, n, div) \ *dst++ = blue_[(prev[x - p] + prev[x + n] + next[x - p] + next[x + n]) / (4 * (div))]; \ *dst++ = green_[(prev[x] + curr[x - p] + curr[x + n] + next[x]) / (4 * (div))]; \ *dst++ = red_[curr[x] / (div)]; \ x++; void DebayerCpu::debayer8_BGBG_BGR888(uint8_t *dst, const uint8_t *src[]) { DECLARE_SRC_POINTERS(uint8_t) for (int x = 0; x < (int)window_.width;) { BGGR_BGR888(1, 1, 1) GBRG_BGR888(1, 1, 1) } } void DebayerCpu::debayer8_GRGR_BGR888(uint8_t *dst, const uint8_t *src[]) { DECLARE_SRC_POINTERS(uint8_t) for (int x = 0; x < (int)window_.width;) { GRBG_BGR888(1, 1, 1) RGGB_BGR888(1, 1, 1) } } void DebayerCpu::debayer10_BGBG_BGR888(uint8_t *dst, const uint8_t *src[]) { DECLARE_SRC_POINTERS(uint16_t) for (int x = 0; x < (int)window_.width;) { /* divide values by 4 for 10 -> 8 bpp value */ BGGR_BGR888(1, 1, 4) GBRG_BGR888(1, 1, 4) } } void DebayerCpu::debayer10_GRGR_BGR888(uint8_t *dst, const uint8_t *src[]) { DECLARE_SRC_POINTERS(uint16_t) for (int x = 0; x < (int)window_.width;) { /* divide values by 4 for 10 -> 8 bpp value */ GRBG_BGR888(1, 1, 4) RGGB_BGR888(1, 1, 4) } } void DebayerCpu::debayer12_BGBG_BGR888(uint8_t *dst, const uint8_t *src[]) { DECLARE_SRC_POINTERS(uint16_t) for (int x = 0; x < (int)window_.width;) { /* divide values by 16 for 12 -> 8 bpp value */ BGGR_BGR888(1, 1, 16) GBRG_BGR888(1, 1, 16) } } void DebayerCpu::debayer12_GRGR_BGR888(uint8_t *dst, const uint8_t *src[]) { DECLARE_SRC_POINTERS(uint16_t) for (int x = 0; x < (int)window_.width;) { /* divide values by 16 for 12 -> 8 bpp value */ GRBG_BGR888(1, 1, 16) RGGB_BGR888(1, 1, 16) } } void DebayerCpu::debayer10P_BGBG_BGR888(uint8_t *dst, const uint8_t *src[]) { const int widthInBytes = window_.width * 5 / 4; const uint8_t *prev = src[0]; const uint8_t *curr = src[1]; const uint8_t *next = src[2]; /* * For the first pixel getting a pixel from the previous column uses * x - 2 to skip the 5th byte with least-significant bits for 4 pixels. * Same for last pixel (uses x + 2) and looking at the next column. */ for (int x = 0; x < widthInBytes;) { /* First pixel */ BGGR_BGR888(2, 1, 1) /* Second pixel BGGR -> GBRG */ GBRG_BGR888(1, 1, 1) /* Same thing for third and fourth pixels */ BGGR_BGR888(1, 1, 1) GBRG_BGR888(1, 2, 1) /* Skip 5th src byte with 4 x 2 least-significant-bits */ x++; } } void DebayerCpu::debayer10P_GRGR_BGR888(uint8_t *dst, const uint8_t *src[]) { const int widthInBytes = window_.width * 5 / 4; const uint8_t *prev = src[0]; const uint8_t *curr = src[1]; const uint8_t *next = src[2]; for (int x = 0; x < widthInBytes;) { /* First pixel */ GRBG_BGR888(2, 1, 1) /* Second pixel GRBG -> RGGB */ RGGB_BGR888(1, 1, 1) /* Same thing for third and fourth pixels */ GRBG_BGR888(1, 1, 1) RGGB_BGR888(1, 2, 1) /* Skip 5th src byte with 4 x 2 least-significant-bits */ x++; } } void DebayerCpu::debayer10P_GBGB_BGR888(uint8_t *dst, const uint8_t *src[]) { const int widthInBytes = window_.width * 5 / 4; const uint8_t *prev = src[0]; const uint8_t *curr = src[1]; const uint8_t *next = src[2]; for (int x = 0; x < widthInBytes;) { /* Even pixel */ GBRG_BGR888(2, 1, 1) /* Odd pixel GBGR -> BGGR */ BGGR_BGR888(1, 1, 1) /* Same thing for next 2 pixels */ GBRG_BGR888(1, 1, 1) BGGR_BGR888(1, 2, 1) /* Skip 5th src byte with 4 x 2 least-significant-bits */ x++; } } void DebayerCpu::debayer10P_RGRG_BGR888(uint8_t *dst, const uint8_t *src[]) { const int widthInBytes = window_.width * 5 / 4; const uint8_t *prev = src[0]; const uint8_t *curr = src[1]; const uint8_t *next = src[2]; for (int x = 0; x < widthInBytes;) { /* Even pixel */ RGGB_BGR888(2, 1, 1) /* Odd pixel RGGB -> GRBG */ GRBG_BGR888(1, 1, 1) /* Same thing for next 2 pixels */ RGGB_BGR888(1, 1, 1) GRBG_BGR888(1, 2, 1) /* Skip 5th src byte with 4 x 2 least-significant-bits */ x++; } } static bool isStandardBayerOrder(BayerFormat::Order order) { return order == BayerFormat::BGGR || order == BayerFormat::GBRG || order == BayerFormat::GRBG || order == BayerFormat::RGGB; } /* * Setup the Debayer object according to the passed in parameters. * Return 0 on success, a negative errno value on failure * (unsupported parameters). */ int DebayerCpu::getInputConfig(PixelFormat inputFormat, DebayerInputConfig &config) { BayerFormat bayerFormat = BayerFormat::fromPixelFormat(inputFormat); if ((bayerFormat.bitDepth == 8 || bayerFormat.bitDepth == 10 || bayerFormat.bitDepth == 12) && bayerFormat.packing == BayerFormat::Packing::None && isStandardBayerOrder(bayerFormat.order)) { config.bpp = (bayerFormat.bitDepth + 7) & ~7; config.patternSize.width = 2; config.patternSize.height = 2; config.outputFormats = std::vector({ formats::RGB888, formats::BGR888 }); return 0; } if (bayerFormat.bitDepth == 10 && bayerFormat.packing == BayerFormat::Packing::CSI2 && isStandardBayerOrder(bayerFormat.order)) { config.bpp = 10; config.patternSize.width = 4; /* 5 bytes per *4* pixels */ config.patternSize.height = 2; config.outputFormats = std::vector({ formats::RGB888, formats::BGR888 }); return 0; } LOG(Debayer, Info) << "Unsupported input format " << inputFormat.toString(); return -EINVAL; } int DebayerCpu::getOutputConfig(PixelFormat outputFormat, DebayerOutputConfig &config) { if (outputFormat == formats::RGB888 || outputFormat == formats::BGR888) { config.bpp = 24; return 0; } LOG(Debayer, Info) << "Unsupported output format " << outputFormat.toString(); return -EINVAL; } /* * Check for standard Bayer orders and set xShift_ and swap debayer0/1, so that * a single pair of BGGR debayer functions can be used for all 4 standard orders. */ int DebayerCpu::setupStandardBayerOrder(BayerFormat::Order order) { switch (order) { case BayerFormat::BGGR: break; case BayerFormat::GBRG: xShift_ = 1; /* BGGR -> GBRG */ break; case BayerFormat::GRBG: std::swap(debayer0_, debayer1_); /* BGGR -> GRBG */ break; case BayerFormat::RGGB: xShift_ = 1; /* BGGR -> GBRG */ std::swap(debayer0_, debayer1_); /* GBRG -> RGGB */ break; default: return -EINVAL; } return 0; } int DebayerCpu::setDebayerFunctions(PixelFormat inputFormat, PixelFormat outputFormat) { BayerFormat bayerFormat = BayerFormat::fromPixelFormat(inputFormat); xShift_ = 0; swapRedBlueGains_ = false; auto invalidFmt = []() -> int { LOG(Debayer, Error) << "Unsupported input output format combination"; return -EINVAL; }; switch (outputFormat) { case formats::RGB888: break; case formats::BGR888: /* Swap R and B in bayer order to generate BGR888 instead of RGB888 */ swapRedBlueGains_ = true; switch (bayerFormat.order) { case BayerFormat::BGGR: bayerFormat.order = BayerFormat::RGGB; break; case BayerFormat::GBRG: bayerFormat.order = BayerFormat::GRBG; break; case BayerFormat::GRBG: bayerFormat.order = BayerFormat::GBRG; break; case BayerFormat::RGGB: bayerFormat.order = BayerFormat::BGGR; break; default: return invalidFmt(); } break; default: return invalidFmt(); } if ((bayerFormat.bitDepth == 8 || bayerFormat.bitDepth == 10 || bayerFormat.bitDepth == 12) && bayerFormat.packing == BayerFormat::Packing::None && isStandardBayerOrder(bayerFormat.order)) { switch (bayerFormat.bitDepth) { case 8: debayer0_ = &DebayerCpu::debayer8_BGBG_BGR888; debayer1_ = &DebayerCpu::debayer8_GRGR_BGR888; break; case 10: debayer0_ = &DebayerCpu::debayer10_BGBG_BGR888; debayer1_ = &DebayerCpu::debayer10_GRGR_BGR888; break; case 12: debayer0_ = &DebayerCpu::debayer12_BGBG_BGR888; debayer1_ = &DebayerCpu::debayer12_GRGR_BGR888; break; } setupStandardBayerOrder(bayerFormat.order); return 0; } if (bayerFormat.bitDepth == 10 && bayerFormat.packing == BayerFormat::Packing::CSI2) { switch (bayerFormat.order) { case BayerFormat::BGGR: debayer0_ = &DebayerCpu::debayer10P_BGBG_BGR888; debayer1_ = &DebayerCpu::debayer10P_GRGR_BGR888; return 0; case BayerFormat::GBRG: debayer0_ = &DebayerCpu::debayer10P_GBGB_BGR888; debayer1_ = &DebayerCpu::debayer10P_RGRG_BGR888; return 0; case BayerFormat::GRBG: debayer0_ = &DebayerCpu::debayer10P_GRGR_BGR888; debayer1_ = &DebayerCpu::debayer10P_BGBG_BGR888; return 0; case BayerFormat::RGGB: debayer0_ = &DebayerCpu::debayer10P_RGRG_BGR888; debayer1_ = &DebayerCpu::debayer10P_GBGB_BGR888; return 0; default: break; } } return invalidFmt(); } int DebayerCpu::configure(const StreamConfiguration &inputCfg, const std::vector> &outputCfgs) { if (getInputConfig(inputCfg.pixelFormat, inputConfig_) != 0) return -EINVAL; if (stats_->configure(inputCfg) != 0) return -EINVAL; const Size &statsPatternSize = stats_->patternSize(); if (inputConfig_.patternSize.width != statsPatternSize.width || inputConfig_.patternSize.height != statsPatternSize.height) { LOG(Debayer, Error) << "mismatching stats and debayer pattern sizes for " << inputCfg.pixelFormat.toString(); return -EINVAL; } inputConfig_.stride = inputCfg.stride; if (outputCfgs.size() != 1) { LOG(Debayer, Error) << "Unsupported number of output streams: " << outputCfgs.size(); return -EINVAL; } const StreamConfiguration &outputCfg = outputCfgs[0]; SizeRange outSizeRange = sizes(inputCfg.pixelFormat, inputCfg.size); std::tie(outputConfig_.stride, outputConfig_.frameSize) = strideAndFrameSize(outputCfg.pixelFormat, outputCfg.size); if (!outSizeRange.contains(outputCfg.size) || outputConfig_.stride != outputCfg.stride) { LOG(Debayer, Error) << "Invalid output size/stride: " << "\n " << outputCfg.size << " (" << outSizeRange << ")" << "\n " << outputCfg.stride << " (" << outputConfig_.stride << ")"; return -EINVAL; } if (setDebayerFunctions(inputCfg.pixelFormat, outputCfg.pixelFormat) != 0) return -EINVAL; window_.x = ((inputCfg.size.width - outputCfg.size.width) / 2) & ~(inputConfig_.patternSize.width - 1); window_.y = ((inputCfg.size.height - outputCfg.size.height) / 2) & ~(inputConfig_.patternSize.height - 1); window_.width = outputCfg.size.width; window_.height = outputCfg.size.height; /* Don't pass x,y since process() already adjusts src before passing it */ stats_->setWindow(Rectangle(window_.size())); /* pad with patternSize.Width on both left and right side */ lineBufferPadding_ = inputConfig_.patternSize.width * inputConfig_.bpp / 8; lineBufferLength_ = window_.width * inputConfig_.bpp / 8 + 2 * lineBufferPadding_; for (unsigned int i = 0; i < (inputConfig_.patternSize.height + 1) && enableInputMemcpy_; i++) { free(lineBuffers_[i]); lineBuffers_[i] = (uint8_t *)malloc(lineBufferLength_); if (!lineBuffers_[i]) return -ENOMEM; } measuredFrames_ = 0; frameProcessTime_ = 0; return 0; } /* * Get width and height at which the bayer-pattern repeats. * Return pattern-size or an empty Size for an unsupported inputFormat. */ Size DebayerCpu::patternSize(PixelFormat inputFormat) { DebayerCpu::DebayerInputConfig config; if (getInputConfig(inputFormat, config) != 0) return {}; return config.patternSize; } std::vector DebayerCpu::formats(PixelFormat inputFormat) { DebayerCpu::DebayerInputConfig config; if (getInputConfig(inputFormat, config) != 0) return std::vector(); return config.outputFormats; } std::tuple DebayerCpu::strideAndFrameSize(const PixelFormat &outputFormat, const Size &size) { DebayerCpu::DebayerOutputConfig config; if (getOutputConfig(outputFormat, config) != 0) return std::make_tuple(0, 0); /* round up to multiple of 8 for 64 bits alignment */ unsigned int stride = (size.width * config.bpp / 8 + 7) & ~7; return std::make_tuple(stride, stride * size.height); } void DebayerCpu::setupInputMemcpy(const uint8_t *linePointers[]) { const unsigned int patternHeight = inputConfig_.patternSize.height; if (!enableInputMemcpy_) return; for (unsigned int i = 0; i < patternHeight; i++) { memcpy(lineBuffers_[i], linePointers[i + 1] - lineBufferPadding_, lineBufferLength_); linePointers[i + 1] = lineBuffers_[i] + lineBufferPadding_; } /* Point lineBufferIndex_ to first unused lineBuffer */ lineBufferIndex_ = patternHeight; } void DebayerCpu::shiftLinePointers(const uint8_t *linePointers[], const uint8_t *src) { const unsigned int patternHeight = inputConfig_.patternSize.height; for (unsigned int i = 0; i < patternHeight; i++) linePointers[i] = linePointers[i + 1]; linePointers[patternHeight] = src + (patternHeight / 2) * (int)inputConfig_.stride; } void DebayerCpu::memcpyNextLine(const uint8_t *linePointers[]) { const unsigned int patternHeight = inputConfig_.patternSize.height; if (!enableInputMemcpy_) return; memcpy(lineBuffers_[lineBufferIndex_], linePointers[patternHeight] - lineBufferPadding_, lineBufferLength_); linePointers[patternHeight] = lineBuffers_[lineBufferIndex_] + lineBufferPadding_; lineBufferIndex_ = (lineBufferIndex_ + 1) % (patternHeight + 1); } void DebayerCpu::process2(const uint8_t *src, uint8_t *dst) { unsigned int yEnd = window_.y + window_.height; /* Holds [0] previous- [1] current- [2] next-line */ const uint8_t *linePointers[3]; /* Adjust src to top left corner of the window */ src += window_.y * inputConfig_.stride + window_.x * inputConfig_.bpp / 8; /* [x] becomes [x - 1] after initial shiftLinePointers() call */ if (window_.y) { linePointers[1] = src - inputConfig_.stride; /* previous-line */ linePointers[2] = src; } else { /* window_.y == 0, use the next line as prev line */ linePointers[1] = src + inputConfig_.stride; linePointers[2] = src; /* Last 2 lines also need special handling */ yEnd -= 2; } setupInputMemcpy(linePointers); for (unsigned int y = window_.y; y < yEnd; y += 2) { shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); stats_->processLine0(y, linePointers); (this->*debayer0_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); (this->*debayer1_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; } if (window_.y == 0) { shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); stats_->processLine0(yEnd, linePointers); (this->*debayer0_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; shiftLinePointers(linePointers, src); /* next line may point outside of src, use prev. */ linePointers[2] = linePointers[0]; (this->*debayer1_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; } } void DebayerCpu::process4(const uint8_t *src, uint8_t *dst) { const unsigned int yEnd = window_.y + window_.height; /* * This holds pointers to [0] 2-lines-up [1] 1-line-up [2] current-line * [3] 1-line-down [4] 2-lines-down. */ const uint8_t *linePointers[5]; /* Adjust src to top left corner of the window */ src += window_.y * inputConfig_.stride + window_.x * inputConfig_.bpp / 8; /* [x] becomes [x - 1] after initial shiftLinePointers() call */ linePointers[1] = src - 2 * inputConfig_.stride; linePointers[2] = src - inputConfig_.stride; linePointers[3] = src; linePointers[4] = src + inputConfig_.stride; setupInputMemcpy(linePointers); for (unsigned int y = window_.y; y < yEnd; y += 4) { shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); stats_->processLine0(y, linePointers); (this->*debayer0_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); (this->*debayer1_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); stats_->processLine2(y, linePointers); (this->*debayer2_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; shiftLinePointers(linePointers, src); memcpyNextLine(linePointers); (this->*debayer3_)(dst, linePointers); src += inputConfig_.stride; dst += outputConfig_.stride; } } static inline int64_t timeDiff(timespec &after, timespec &before) { return (after.tv_sec - before.tv_sec) * 1000000000LL + (int64_t)after.tv_nsec - (int64_t)before.tv_nsec; } void DebayerCpu::process(FrameBuffer *input, FrameBuffer *output, DebayerParams params) { timespec frameStartTime; if (measuredFrames_ < DebayerCpu::kLastFrameToMeasure) { frameStartTime = {}; clock_gettime(CLOCK_MONOTONIC_RAW, &frameStartTime); } /* Apply DebayerParams */ if (params.gamma != gammaCorrection_ || params.blackLevel != blackLevel_) { const unsigned int blackIndex = params.blackLevel * kGammaLookupSize / 256; std::fill(gamma_.begin(), gamma_.begin() + blackIndex, 0); const float divisor = kGammaLookupSize - blackIndex - 1.0; for (unsigned int i = blackIndex; i < kGammaLookupSize; i++) gamma_[i] = UINT8_MAX * powf((i - blackIndex) / divisor, params.gamma); gammaCorrection_ = params.gamma; blackLevel_ = params.blackLevel; } if (swapRedBlueGains_) std::swap(params.gainR, params.gainB); for (unsigned int i = 0; i < kRGBLookupSize; i++) { constexpr unsigned int div = kRGBLookupSize * DebayerParams::kGain10 / kGammaLookupSize; unsigned int idx; /* Apply gamma after gain! */ idx = std::min({ i * params.gainR / div, (kGammaLookupSize - 1) }); red_[i] = gamma_[idx]; idx = std::min({ i * params.gainG / div, (kGammaLookupSize - 1) }); green_[i] = gamma_[idx]; idx = std::min({ i * params.gainB / div, (kGammaLookupSize - 1) }); blue_[i] = gamma_[idx]; } /* Copy metadata from the input buffer */ FrameMetadata &metadata = output->_d()->metadata(); metadata.status = input->metadata().status; metadata.sequence = input->metadata().sequence; metadata.timestamp = input->metadata().timestamp; MappedFrameBuffer in(input, MappedFrameBuffer::MapFlag::Read); MappedFrameBuffer out(output, MappedFrameBuffer::MapFlag::Write); if (!in.isValid() || !out.isValid()) { LOG(Debayer, Error) << "mmap-ing buffer(s) failed"; metadata.status = FrameMetadata::FrameError; return; } stats_->startFrame(); if (inputConfig_.patternSize.height == 2) process2(in.planes()[0].data(), out.planes()[0].data()); else process4(in.planes()[0].data(), out.planes()[0].data()); metadata.planes()[0].bytesused = out.planes()[0].size(); /* Measure before emitting signals */ if (measuredFrames_ < DebayerCpu::kLastFrameToMeasure && ++measuredFrames_ > DebayerCpu::kFramesToSkip) { timespec frameEndTime = {}; clock_gettime(CLOCK_MONOTONIC_RAW, &frameEndTime); frameProcessTime_ += timeDiff(frameEndTime, frameStartTime); if (measuredFrames_ == DebayerCpu::kLastFrameToMeasure) { const unsigned int measuredFrames = DebayerCpu::kLastFrameToMeasure - DebayerCpu::kFramesToSkip; LOG(Debayer, Info) << "Processed " << measuredFrames << " frames in " << frameProcessTime_ / 1000 << "us, " << frameProcessTime_ / (1000 * measuredFrames) << " us/frame"; } } stats_->finishFrame(); outputBufferReady.emit(output); inputBufferReady.emit(input); } SizeRange DebayerCpu::sizes(PixelFormat inputFormat, const Size &inputSize) { Size patternSize = this->patternSize(inputFormat); unsigned int borderHeight = patternSize.height; if (patternSize.isNull()) return {}; /* No need for top/bottom border with a pattern height of 2 */ if (patternSize.height == 2) borderHeight = 0; /* * For debayer interpolation a border is kept around the entire image * and the minimum output size is pattern-height x pattern-width. */ if (inputSize.width < (3 * patternSize.width) || inputSize.height < (2 * borderHeight + patternSize.height)) { LOG(Debayer, Warning) << "Input format size too small: " << inputSize.toString(); return {}; } return SizeRange(Size(patternSize.width, patternSize.height), Size((inputSize.width - 2 * patternSize.width) & ~(patternSize.width - 1), (inputSize.height - 2 * borderHeight) & ~(patternSize.height - 1)), patternSize.width, patternSize.height); } } /* namespace libcamera */