v811_spc009/packages/services/Car/cpp/evs/sampleDriver/bufferCopy.cpp

/*
 * 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 "bufferCopy.h"

#include <android-base/logging.h>
#include <libyuv.h>

namespace android {
namespace hardware {
namespace automotive {
namespace evs {
namespace V1_1 {
namespace implementation {


// Round up to the nearest multiple of the given alignment value
template<unsigned alignment>
int align(int value) {
    static_assert((alignment && !(alignment & (alignment - 1))),
                  "alignment must be a power of 2");

    unsigned mask = alignment - 1;
    return (value + mask) & ~mask;
}


void fillNV21FromNV21(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned) {
    // The NV21 format provides a Y array of 8bit values, followed by a 1/2 x 1/2 interleave U/V array.
    // It assumes an even width and height for the overall image, and a horizontal stride that is
    // an even multiple of 16 bytes for both the Y and UV arrays.

    // Target  and source image layout properties (They match since the formats match!)
    const AHardwareBuffer_Desc* pDesc =
        reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);
    const unsigned strideLum = align<16>(pDesc->width);
    const unsigned sizeY = strideLum * pDesc->height;
    const unsigned strideColor = strideLum;   // 1/2 the samples, but two interleaved channels
    const unsigned sizeColor = strideColor * pDesc->height/2;
    const unsigned totalBytes = sizeY + sizeColor;

    // Simply copy the data byte for byte
    memcpy(tgt, imgData, totalBytes);
}


void fillNV21FromYUYV(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {
    // The YUYV format provides an interleaved array of pixel values with U and V subsampled in
    // the horizontal direction only.  Also known as interleaved 422 format.  A 4 byte
    // "macro pixel" provides the Y value for two adjacent pixels and the U and V values shared
    // between those two pixels.  The width of the image must be an even number.
    // We need to down sample the UV values and collect them together after all the packed Y values
    // to construct the NV21 format.
    // NV21 requires even width and height, so we assume that is the case for the incomming image
    // as well.
    uint32_t *srcDataYUYV = (uint32_t*)imgData;
    struct YUYVpixel {
        uint8_t Y1;
        uint8_t U;
        uint8_t Y2;
        uint8_t V;
    };

    // Target image layout properties
    const AHardwareBuffer_Desc* pDesc =
        reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);
    const unsigned strideLum = align<16>(pDesc->width);
    const unsigned sizeY = strideLum * pDesc->height;
    const unsigned strideColor = strideLum;   // 1/2 the samples, but two interleaved channels

    // Source image layout properties
    const unsigned srcRowPixels = imgStride/4;  // imgStride is in units of bytes
    const unsigned srcRowDoubleStep = srcRowPixels * 2;
    uint32_t* topSrcRow =  srcDataYUYV;
    uint32_t* botSrcRow =  srcDataYUYV + srcRowPixels;

    // We're going to work on one 2x2 cell in the output image at at time
    for (unsigned cellRow = 0; cellRow < pDesc->height/2; cellRow++) {

        // Set up the output pointers
        uint8_t* yTopRow = tgt + (cellRow*2) * strideLum;
        uint8_t* yBotRow = yTopRow + strideLum;
        uint8_t* uvRow   = (tgt + sizeY) + cellRow * strideColor;

        for (unsigned cellCol = 0; cellCol < pDesc->width/2; cellCol++) {
            // Collect the values from the YUYV interleaved data
            const YUYVpixel* pTopMacroPixel = (YUYVpixel*)&topSrcRow[cellCol];
            const YUYVpixel* pBotMacroPixel = (YUYVpixel*)&botSrcRow[cellCol];

            // Down sample the U/V values by linear average between rows
            const uint8_t uValue = (pTopMacroPixel->U + pBotMacroPixel->U) >> 1;
            const uint8_t vValue = (pTopMacroPixel->V + pBotMacroPixel->V) >> 1;

            // Store the values into the NV21 layout
            yTopRow[cellCol*2]   = pTopMacroPixel->Y1;
            yTopRow[cellCol*2+1] = pTopMacroPixel->Y2;
            yBotRow[cellCol*2]   = pBotMacroPixel->Y1;
            yBotRow[cellCol*2+1] = pBotMacroPixel->Y2;
            uvRow[cellCol*2]     = uValue;
            uvRow[cellCol*2+1]   = vValue;
        }

        // Skipping two rows to get to the next set of two source rows
        topSrcRow += srcRowDoubleStep;
        botSrcRow += srcRowDoubleStep;
    }
}


void fillRGBAFromYUYV(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {
    const AHardwareBuffer_Desc* pDesc =
        reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);
    // Converts YUY2ToARGB (little endian).  Please note that libyuv uses the
    // little endian while we're using the big endian in RGB format names.
    const auto dstStrideInBytes = pDesc->stride * 4;  // 4-byte per pixel
    auto result = libyuv::YUY2ToARGB((const uint8_t*)imgData,
                                     imgStride,             // input stride in bytes
                                     tgt,
                                     dstStrideInBytes,      // output stride in bytes
                                     pDesc->width,
                                     pDesc->height);
    if (result) {
        LOG(ERROR) << "Failed to convert YUYV to BGRA.";
        return;
    }

    // Swaps R and B pixels to convert BGRA to RGBA in place.
    // TODO(b/190783702): Consider allocating an extra space to store ARGB data
    //                    temporarily if below operation is too slow.
    result = libyuv::ABGRToARGB(tgt, dstStrideInBytes, tgt, dstStrideInBytes,
                                pDesc->width, pDesc->height);
    if (result) {
        LOG(ERROR) << "Failed to convert BGRA to RGBA.";
    }
}


void fillYUYVFromYUYV(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {
    const AHardwareBuffer_Desc* pDesc =
        reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);
    unsigned width = pDesc->width;
    unsigned height = pDesc->height;
    uint8_t* src = (uint8_t*)imgData;
    uint8_t* dst = (uint8_t*)tgt;
    unsigned srcStrideBytes = imgStride;
    unsigned dstStrideBytes = pDesc->stride * 2;

    for (unsigned r=0; r<height; r++) {
        // Copy a pixel row at a time (2 bytes per pixel, averaged over a YUYV macro pixel)
        memcpy(dst+r*dstStrideBytes, src+r*srcStrideBytes, width*2);
    }
}


void fillYUYVFromUYVY(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {
    const AHardwareBuffer_Desc* pDesc =
        reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);
    unsigned width = pDesc->width;
    unsigned height = pDesc->height;
    uint32_t* src = (uint32_t*)imgData;
    uint32_t* dst = (uint32_t*)tgt;
    unsigned srcStridePixels = imgStride / 2;
    unsigned dstStridePixels = pDesc->stride;

    const int srcRowPadding32 = srcStridePixels/2 - width/2;  // 2 bytes per pixel, 4 bytes per word
    const int dstRowPadding32 = dstStridePixels/2 - width/2;  // 2 bytes per pixel, 4 bytes per word

    for (unsigned r=0; r<height; r++) {
        for (unsigned c=0; c<width/2; c++) {
            // Note:  we're walking two pixels at a time here (even/odd)
            uint32_t srcPixel = *src++;

            uint8_t Y1 = (srcPixel)       & 0xFF;
            uint8_t U  = (srcPixel >> 8)  & 0xFF;
            uint8_t Y2 = (srcPixel >> 16) & 0xFF;
            uint8_t V  = (srcPixel >> 24) & 0xFF;

            // Now we write back the pair of pixels with the components swizzled
            *dst++ = (U)        |
                     (Y1 << 8)  |
                     (V  << 16) |
                     (Y2 << 24);
        }

        // Skip over any extra data or end of row alignment padding
        src += srcRowPadding32;
        dst += dstRowPadding32;
    }
}


} // namespace implementation
} // namespace V1_1
} // namespace evs
} // namespace automotive
} // namespace hardware
} // namespace android
v811_spc009_project 4 months ago			`/*`
			`* 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 "bufferCopy.h"`

			`#include <android-base/logging.h>`
			`#include <libyuv.h>`

			`namespace android {`
			`namespace hardware {`
			`namespace automotive {`
			`namespace evs {`
			`namespace V1_1 {`
			`namespace implementation {`


			`// Round up to the nearest multiple of the given alignment value`
			`template<unsigned alignment>`
			`int align(int value) {`
			`static_assert((alignment && !(alignment & (alignment - 1))),`
			`"alignment must be a power of 2");`

			`unsigned mask = alignment - 1;`
			`return (value + mask) & ~mask;`
			`}`


			`void fillNV21FromNV21(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned) {`
			`// The NV21 format provides a Y array of 8bit values, followed by a 1/2 x 1/2 interleave U/V array.`
			`// It assumes an even width and height for the overall image, and a horizontal stride that is`
			`// an even multiple of 16 bytes for both the Y and UV arrays.`

			`// Target and source image layout properties (They match since the formats match!)`
			`const AHardwareBuffer_Desc* pDesc =`
			`reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);`
			`const unsigned strideLum = align<16>(pDesc->width);`
			`const unsigned sizeY = strideLum * pDesc->height;`
			`const unsigned strideColor = strideLum; // 1/2 the samples, but two interleaved channels`
			`const unsigned sizeColor = strideColor * pDesc->height/2;`
			`const unsigned totalBytes = sizeY + sizeColor;`

			`// Simply copy the data byte for byte`
			`memcpy(tgt, imgData, totalBytes);`
			`}`


			`void fillNV21FromYUYV(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {`
			`// The YUYV format provides an interleaved array of pixel values with U and V subsampled in`
			`// the horizontal direction only. Also known as interleaved 422 format. A 4 byte`
			`// "macro pixel" provides the Y value for two adjacent pixels and the U and V values shared`
			`// between those two pixels. The width of the image must be an even number.`
			`// We need to down sample the UV values and collect them together after all the packed Y values`
			`// to construct the NV21 format.`
			`// NV21 requires even width and height, so we assume that is the case for the incomming image`
			`// as well.`
			`uint32_t srcDataYUYV = (uint32_t)imgData;`
			`struct YUYVpixel {`
			`uint8_t Y1;`
			`uint8_t U;`
			`uint8_t Y2;`
			`uint8_t V;`
			`};`

			`// Target image layout properties`
			`const AHardwareBuffer_Desc* pDesc =`
			`reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);`
			`const unsigned strideLum = align<16>(pDesc->width);`
			`const unsigned sizeY = strideLum * pDesc->height;`
			`const unsigned strideColor = strideLum; // 1/2 the samples, but two interleaved channels`

			`// Source image layout properties`
			`const unsigned srcRowPixels = imgStride/4; // imgStride is in units of bytes`
			`const unsigned srcRowDoubleStep = srcRowPixels * 2;`
			`uint32_t* topSrcRow = srcDataYUYV;`
			`uint32_t* botSrcRow = srcDataYUYV + srcRowPixels;`

			`// We're going to work on one 2x2 cell in the output image at at time`
			`for (unsigned cellRow = 0; cellRow < pDesc->height/2; cellRow++) {`

			`// Set up the output pointers`
			`uint8_t* yTopRow = tgt + (cellRow2) strideLum;`
			`uint8_t* yBotRow = yTopRow + strideLum;`
			`uint8_t* uvRow = (tgt + sizeY) + cellRow * strideColor;`

			`for (unsigned cellCol = 0; cellCol < pDesc->width/2; cellCol++) {`
			`// Collect the values from the YUYV interleaved data`
			`const YUYVpixel* pTopMacroPixel = (YUYVpixel*)&topSrcRow[cellCol];`
			`const YUYVpixel* pBotMacroPixel = (YUYVpixel*)&botSrcRow[cellCol];`

			`// Down sample the U/V values by linear average between rows`
			`const uint8_t uValue = (pTopMacroPixel->U + pBotMacroPixel->U) >> 1;`
			`const uint8_t vValue = (pTopMacroPixel->V + pBotMacroPixel->V) >> 1;`

			`// Store the values into the NV21 layout`
			`yTopRow[cellCol*2] = pTopMacroPixel->Y1;`
			`yTopRow[cellCol*2+1] = pTopMacroPixel->Y2;`
			`yBotRow[cellCol*2] = pBotMacroPixel->Y1;`
			`yBotRow[cellCol*2+1] = pBotMacroPixel->Y2;`
			`uvRow[cellCol*2] = uValue;`
			`uvRow[cellCol*2+1] = vValue;`
			`}`

			`// Skipping two rows to get to the next set of two source rows`
			`topSrcRow += srcRowDoubleStep;`
			`botSrcRow += srcRowDoubleStep;`
			`}`
			`}`


			`void fillRGBAFromYUYV(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {`
			`const AHardwareBuffer_Desc* pDesc =`
			`reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);`
			`// Converts YUY2ToARGB (little endian). Please note that libyuv uses the`
			`// little endian while we're using the big endian in RGB format names.`
			`const auto dstStrideInBytes = pDesc->stride * 4; // 4-byte per pixel`
			`auto result = libyuv::YUY2ToARGB((const uint8_t*)imgData,`
			`imgStride, // input stride in bytes`
			`tgt,`
			`dstStrideInBytes, // output stride in bytes`
			`pDesc->width,`
			`pDesc->height);`
			`if (result) {`
			`LOG(ERROR) << "Failed to convert YUYV to BGRA.";`
			`return;`
			`}`

			`// Swaps R and B pixels to convert BGRA to RGBA in place.`
			`// TODO(b/190783702): Consider allocating an extra space to store ARGB data`
			`// temporarily if below operation is too slow.`
			`result = libyuv::ABGRToARGB(tgt, dstStrideInBytes, tgt, dstStrideInBytes,`
			`pDesc->width, pDesc->height);`
			`if (result) {`
			`LOG(ERROR) << "Failed to convert BGRA to RGBA.";`
			`}`
			`}`


			`void fillYUYVFromYUYV(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {`
			`const AHardwareBuffer_Desc* pDesc =`
			`reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);`
			`unsigned width = pDesc->width;`
			`unsigned height = pDesc->height;`
			`uint8_t* src = (uint8_t*)imgData;`
			`uint8_t* dst = (uint8_t*)tgt;`
			`unsigned srcStrideBytes = imgStride;`
			`unsigned dstStrideBytes = pDesc->stride * 2;`

			`for (unsigned r=0; r<height; r++) {`
			`// Copy a pixel row at a time (2 bytes per pixel, averaged over a YUYV macro pixel)`
			`memcpy(dst+rdstStrideBytes, src+rsrcStrideBytes, width*2);`
			`}`
			`}`


			`void fillYUYVFromUYVY(const BufferDesc& tgtBuff, uint8_t* tgt, void* imgData, unsigned imgStride) {`
			`const AHardwareBuffer_Desc* pDesc =`
			`reinterpret_cast<const AHardwareBuffer_Desc*>(&tgtBuff.buffer.description);`
			`unsigned width = pDesc->width;`
			`unsigned height = pDesc->height;`
			`uint32_t* src = (uint32_t*)imgData;`
			`uint32_t* dst = (uint32_t*)tgt;`
			`unsigned srcStridePixels = imgStride / 2;`
			`unsigned dstStridePixels = pDesc->stride;`

			`const int srcRowPadding32 = srcStridePixels/2 - width/2; // 2 bytes per pixel, 4 bytes per word`
			`const int dstRowPadding32 = dstStridePixels/2 - width/2; // 2 bytes per pixel, 4 bytes per word`

			`for (unsigned r=0; r<height; r++) {`
			`for (unsigned c=0; c<width/2; c++) {`
			`// Note: we're walking two pixels at a time here (even/odd)`
			`uint32_t srcPixel = *src++;`

			`uint8_t Y1 = (srcPixel) & 0xFF;`
			`uint8_t U = (srcPixel >> 8) & 0xFF;`
			`uint8_t Y2 = (srcPixel >> 16) & 0xFF;`
			`uint8_t V = (srcPixel >> 24) & 0xFF;`

			`// Now we write back the pair of pixels with the components swizzled`
			`*dst++ = (U) \|`
			`(Y1 << 8) \|`
			`(V << 16) \|`
			`(Y2 << 24);`
			`}`

			`// Skip over any extra data or end of row alignment padding`
			`src += srcRowPadding32;`
			`dst += dstRowPadding32;`
			`}`
			`}`


			`} // namespace implementation`
			`} // namespace V1_1`
			`} // namespace evs`
			`} // namespace automotive`
			`} // namespace hardware`
			`} // namespace android`