/*

 * Copyright (C) 2024 Niklas Haas

 * Copyright (C) 2001-2003 Michael Niedermayer <michaelni@gmx.at>

 *

 * This file is part of FFmpeg.

 *

 * FFmpeg is free software; you can redistribute it and/or

 * modify it under the terms of the GNU Lesser General Public

 * License as published by the Free Software Foundation; either

 * version 2.1 of the License, or (at your option) any later version.

 *

 * FFmpeg is distributed in the hope that it will be useful,

 * but WITHOUT ANY WARRANTY; without even the implied warranty of

 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

 * Lesser General Public License for more details.

 *

 * You should have received a copy of the GNU Lesser General Public

 * License along with FFmpeg; if not, write to the Free Software

 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

 */

#include "config.h"

#define _DEFAULT_SOURCE

#define _SVID_SOURCE // needed for MAP_ANONYMOUS

#define _DARWIN_C_SOURCE // needed for MAP_ANON

#include <inttypes.h>

#include <math.h>

#include <stdio.h>

#include <string.h>

#if HAVE_MMAP

#include <sys/mman.h>

#if defined(MAP_ANON) && !defined(MAP_ANONYMOUS)

#define MAP_ANONYMOUS MAP_ANON

#endif

#endif

#if HAVE_VIRTUALALLOC

#include <windows.h>

#endif

#include "libavutil/attributes.h"

#include "libavutil/avassert.h"

#include "libavutil/cpu.h"

#include "libavutil/csp.h"

#include "libavutil/emms.h"

#include "libavutil/imgutils.h"

#include "libavutil/intreadwrite.h"

#include "libavutil/libm.h"

#include "libavutil/mathematics.h"

#include "libavutil/mem.h"

#include "libavutil/opt.h"

#include "libavutil/pixdesc.h"

#include "libavutil/refstruct.h"

#include "libavutil/slicethread.h"

#include "libavutil/thread.h"

#include "libavutil/aarch64/cpu.h"

#include "libavutil/ppc/cpu.h"

#include "libavutil/x86/asm.h"

#include "libavutil/x86/cpu.h"

#include "libavutil/loongarch/cpu.h"

#include "rgb2rgb.h"

#include "swscale.h"

#include "swscale_internal.h"

#include "graph.h"

#if CONFIG_VULKAN

#include "vulkan/ops.h"

#endif

/**

 * Allocate and return an SwsContext without performing initialization.

 */

static SwsContext *alloc_set_opts(int srcW, int srcH, enum AVPixelFormat srcFormat,

                                  int dstW, int dstH, enum AVPixelFormat dstFormat,

                                  int flags, const double *param)

{

    SwsContext *sws = sws_alloc_context();

    if (!sws)

        return NULL;

    sws->flags = flags;

    sws->src_w = srcW;

    sws->src_h = srcH;

    sws->dst_w = dstW;

    sws->dst_h      = dstH;

    sws->src_format = srcFormat;

    sws->dst_format = dstFormat;

    for (int i = 0; param && i < SWS_NUM_SCALER_PARAMS; i++)

        sws->scaler_params[i] = param[i];

    return sws;

}

int ff_shuffle_filter_coefficients(SwsInternal *c, int *filterPos,

                                   int filterSize, int16_t *filter,

                                   int dstW)

{

#if ARCH_X86_64

    int i, j, k;

    int cpu_flags = av_get_cpu_flags();

    if (!filter)

        return 0;

    if (EXTERNAL_AVX2_FAST(cpu_flags) && !(cpu_flags & AV_CPU_FLAG_SLOW_GATHER)) {

        if ((c->srcBpc == 8) && (c->dstBpc <= 14)) {

           int16_t *filterCopy = NULL;

           if (filterSize > 4) {

               filterCopy = av_malloc_array(dstW, filterSize * sizeof(*filterCopy));

               if (!filterCopy)

                   return AVERROR(ENOMEM);

               memcpy(filterCopy, filter, dstW * filterSize * sizeof(int16_t));

           }

           // Do not swap filterPos for pixels which won't be processed by

           // the main loop.

           for (i = 0; i + 16 <= dstW; i += 16) {

               FFSWAP(int, filterPos[i + 2], filterPos[i + 4]);

               FFSWAP(int, filterPos[i + 3], filterPos[i + 5]);

               FFSWAP(int, filterPos[i + 10], filterPos[i + 12]);

               FFSWAP(int, filterPos[i + 11], filterPos[i + 13]);

           }

           if (filterSize > 4) {

               // 16 pixels are processed at a time.

               for (i = 0; i + 16 <= dstW; i += 16) {

                   // 4 filter coeffs are processed at a time.

                   for (k = 0; k + 4 <= filterSize; k += 4) {

                       for (j = 0; j < 16; ++j) {

                           int from = (i + j) * filterSize + k;

                           int to = i * filterSize + j * 4 + k * 16;

                           memcpy(&filter[to], &filterCopy[from], 4 * sizeof(int16_t));

                       }

                   }

               }

               // 4 pixels are processed at a time in the tail.

               for (; i < dstW; i += 4) {

                   // 4 filter coeffs are processed at a time.

                   int rem = dstW - i >= 4 ? 4 : dstW - i;

                   for (k = 0; k + 4 <= filterSize; k += 4) {

                       for (j = 0; j < rem; ++j) {

                           int from = (i + j) * filterSize + k;

                           int to = i * filterSize + j * 4 + k * 4;

                           memcpy(&filter[to], &filterCopy[from], 4 * sizeof(int16_t));

                       }

                   }

               }

           }

           av_free(filterCopy);

        }

    }

#endif

    return 0;

}

static double getSplineCoeff(double a, double b, double c, double d,

                             double dist)

{

    if (dist <= 1.0)

        return ((d * dist + c) * dist + b) * dist + a;

    else

        return getSplineCoeff(0.0,

                               b + 2.0 * c + 3.0 * d,

                               c + 3.0 * d,

                              -b - 3.0 * c - 6.0 * d,

                              dist - 1.0);

}

static av_cold int get_local_pos(SwsInternal *s, int chr_subsample, int pos, int dir)

{

    if (pos == -1 || pos <= -513) {

        pos = (128 << chr_subsample) - 128;

    }

    pos += 128; // relative to ideal left edge

    return pos >> chr_subsample;

}

typedef struct {

    int flag;                   ///< flag associated to the algorithm

    const char *description;    ///< human-readable description

    int size_factor;            ///< size factor used when initing the filters

} ScaleAlgorithm;

static const ScaleAlgorithm scale_algorithms[] = {

    { SWS_AREA,          "area averaging",                  1 /* downscale only, for upscale it is bilinear */ },

    { SWS_BICUBIC,       "bicubic",                         4 },

    { SWS_BICUBLIN,      "luma bicubic / chroma bilinear", -1 },

    { SWS_BILINEAR,      "bilinear",                        2 },

    { SWS_FAST_BILINEAR, "fast bilinear",                  -1 },

    { SWS_GAUSS,         "Gaussian",                        8 /* infinite ;) */ },

    { SWS_LANCZOS,       "Lanczos",                        -1 /* custom */ },

    { SWS_POINT,         "nearest neighbor / point",       -1 },

    { SWS_SINC,          "sinc",                           20 /* infinite ;) */ },

    { SWS_SPLINE,        "bicubic spline",                 20 /* infinite :)*/ },

    { SWS_X,             "experimental",                    8 },

};

static av_cold int initFilter(int16_t **outFilter, int32_t **filterPos,

                              int *outFilterSize, int xInc, int srcW,

                              int dstW, int filterAlign, int one,

                              int scaler, int flags, int cpu_flags,

                              SwsVector *srcFilter, SwsVector *dstFilter,

                              double param[SWS_NUM_SCALER_PARAMS], int srcPos, int dstPos)

{

    int i;

    int filterSize;

    int filter2Size;

    int minFilterSize;

    int64_t *filter    = NULL;

    int64_t *filter2   = NULL;

    const int64_t fone = 1LL << (54 - FFMIN(av_log2(srcW/dstW), 8));

    int ret            = -1;

    emms_c(); // FIXME should not be required but IS (even for non-MMX versions)

    // NOTE: the +3 is for the MMX(+1) / SSE(+3) scaler which reads over the end

    if (!FF_ALLOC_TYPED_ARRAY(*filterPos, dstW + 3))

        goto nomem;

    if (FFABS(xInc - 0x10000) < 10 && srcPos == dstPos) { // unscaled

        int i;

        filterSize = 1;

        if (!FF_ALLOCZ_TYPED_ARRAY(filter, dstW * filterSize))

            goto nomem;

        for (i = 0; i < dstW; i++) {

            filter[i * filterSize] = fone;

            (*filterPos)[i]        = i;

        }

    } else if (scaler == SWS_POINT) { // lame looking point sampling mode

        int i;

        int64_t xDstInSrc;

        filterSize = 1;

        if (!FF_ALLOC_TYPED_ARRAY(filter, dstW * filterSize))

            goto nomem;

        xDstInSrc = ((dstPos*(int64_t)xInc)>>8) - ((srcPos*0x8000LL)>>7);

        for (i = 0; i < dstW; i++) {

            int xx = (xDstInSrc - ((filterSize - 1) << 15) + (1 << 15)) >> 16;

            (*filterPos)[i] = xx;

            filter[i]       = fone;

            xDstInSrc      += xInc;

        }

    } else if ((xInc <= (1 << 16) && (scaler == SWS_AREA)) ||

               (scaler == SWS_FAST_BILINEAR)) { // bilinear upscale

        int i;

        int64_t xDstInSrc;

        filterSize = 2;

        if (!FF_ALLOC_TYPED_ARRAY(filter, dstW * filterSize))

            goto nomem;

        xDstInSrc = ((dstPos*(int64_t)xInc)>>8) - ((srcPos*0x8000LL)>>7);

        for (i = 0; i < dstW; i++) {

            int xx = (xDstInSrc - ((filterSize - 1) << 15) + (1 << 15)) >> 16;

            int j;

            (*filterPos)[i] = xx;

            // bilinear upscale / linear interpolate / area averaging

            for (j = 0; j < filterSize; j++) {

                int64_t coeff = fone - FFABS((int64_t)xx * (1 << 16) - xDstInSrc) * (fone >> 16);

                if (coeff < 0)

                    coeff = 0;

                filter[i * filterSize + j] = coeff;

                xx++;

            }

            xDstInSrc += xInc;

        }

    } else {

        int64_t xDstInSrc;

        int sizeFactor = -1;

        for (i = 0; i < FF_ARRAY_ELEMS(scale_algorithms); i++) {

            if (scaler == scale_algorithms[i].flag && scale_algorithms[i].size_factor > 0) {

                sizeFactor = scale_algorithms[i].size_factor;

                break;

            }

        }

        if (scaler == SWS_LANCZOS)

            sizeFactor = param[0] != SWS_PARAM_DEFAULT ? ceil(2 * param[0]) : 6;

        av_assert0(sizeFactor > 0);

        if (sizeFactor > 50) {

            ret = AVERROR(EINVAL);

            goto fail;

        }

        if (xInc <= 1 << 16)

            filterSize = 1 + sizeFactor;    // upscale

        else

            filterSize = 1 + (sizeFactor * srcW + dstW - 1) / dstW;

        filterSize = FFMIN(filterSize, srcW - 2);

        filterSize = FFMAX(filterSize, 1);

        filter = av_malloc_array(dstW, filterSize * sizeof(*filter));

        if (!filter)

            goto nomem;

        xDstInSrc = ((dstPos*(int64_t)xInc)>>7) - ((srcPos*0x10000LL)>>7);

        for (i = 0; i < dstW; i++) {

            int xx = (xDstInSrc - (filterSize - 2) * (1LL<<16)) / (1 << 17);

            int j;

            (*filterPos)[i] = xx;

            for (j = 0; j < filterSize; j++) {

                int64_t d = (FFABS(((int64_t)xx * (1 << 17)) - xDstInSrc)) << 13;

                double floatd;

                int64_t coeff;

                if (xInc > 1 << 16)

                    d = d * dstW / srcW;

                floatd = d * (1.0 / (1 << 30));

                if (scaler == SWS_BICUBIC) {

                    int64_t B = (param[0] != SWS_PARAM_DEFAULT ? param[0] :   0) * (1 << 24);

                    int64_t C = (param[1] != SWS_PARAM_DEFAULT ? param[1] : 0.6) * (1 << 24);

                    if (d >= 1LL << 31) {

                        coeff = 0.0;

                    } else {

                        int64_t dd  = (d  * d) >> 30;

                        int64_t ddd = (dd * d) >> 30;

                        if (d < 1LL << 30)

                            coeff =  (12 * (1 << 24) -  9 * B - 6 * C) * ddd +

                                    (-18 * (1 << 24) + 12 * B + 6 * C) *  dd +

                                      (6 * (1 << 24) -  2 * B)         * (1 << 30);

                        else

                            coeff =      (-B -  6 * C) * ddd +

                                      (6 * B + 30 * C) * dd  +

                                    (-12 * B - 48 * C) * d   +

                                      (8 * B + 24 * C) * (1 << 30);

                    }

                    coeff /= (1LL<<54)/fone;

                } else if (scaler == SWS_X) {

                    double A = param[0] != SWS_PARAM_DEFAULT ? param[0] : 1.0;

                    double c;

                    if (floatd < 1.0)

                        c = cos(floatd * M_PI);

                    else

                        c = -1.0;

                    if (c < 0.0)

                        c = -pow(-c, A);

                    else

                        c = pow(c, A);

                    coeff = (c * 0.5 + 0.5) * fone;

                } else if (scaler == SWS_AREA) {

                    int64_t d2 = d - (1 << 29);

                    if (d2 * xInc < -(1LL << (29 + 16)))

                        coeff = 1.0 * (1LL << (30 + 16));

                    else if (d2 * xInc < (1LL << (29 + 16)))

                        coeff = -d2 * xInc + (1LL << (29 + 16));

                    else

                        coeff = 0.0;

                    coeff *= fone >> (30 + 16);

                } else if (scaler == SWS_GAUSS) {

                    double p = param[0] != SWS_PARAM_DEFAULT ? param[0] : 3.0;

                    coeff = exp2(-p * floatd * floatd) * fone;

                } else if (scaler == SWS_SINC) {

                    coeff = (d ? sin(floatd * M_PI) / (floatd * M_PI) : 1.0) * fone;

                } else if (scaler == SWS_LANCZOS) {

                    double p = param[0] != SWS_PARAM_DEFAULT ? param[0] : 3.0;

                    coeff = (d ? sin(floatd * M_PI) * sin(floatd * M_PI / p) /

                             (floatd * floatd * M_PI * M_PI / p) : 1.0) * fone;

                    if (floatd > p)

                        coeff = 0;

                } else if (scaler == SWS_BILINEAR) {

                    coeff = (1 << 30) - d;

                    if (coeff < 0)

                        coeff = 0;

                    coeff *= fone >> 30;

                } else if (scaler == SWS_SPLINE) {

                    double p = -2.196152422706632;

                    coeff = getSplineCoeff(1.0, 0.0, p, -p - 1.0, floatd) * fone;

                } else {

                    av_assert0(0);

                }

                filter[i * filterSize + j] = coeff;

                xx++;

            }

            xDstInSrc += 2LL * xInc;

        }

    }

    /* apply src & dst Filter to filter -> filter2

     * av_free(filter);

     */

    av_assert0(filterSize > 0);

    filter2Size = filterSize;

    if (srcFilter)

        filter2Size += srcFilter->length - 1;

    if (dstFilter)

        filter2Size += dstFilter->length - 1;

    av_assert0(filter2Size > 0);

    filter2 = av_calloc(dstW, filter2Size * sizeof(*filter2));

    if (!filter2)

        goto nomem;

    for (i = 0; i < dstW; i++) {

        int j, k;

        if (srcFilter) {

            for (k = 0; k < srcFilter->length; k++) {

                for (j = 0; j < filterSize; j++)

                    filter2[i * filter2Size + k + j] +=

                        srcFilter->coeff[k] * filter[i * filterSize + j];

            }

        } else {

            for (j = 0; j < filterSize; j++)

                filter2[i * filter2Size + j] = filter[i * filterSize + j];

        }

        // FIXME dstFilter

        (*filterPos)[i] += (filterSize - 1) / 2 - (filter2Size - 1) / 2;

    }

    av_freep(&filter);

    /* try to reduce the filter-size (step1 find size and shift left) */

    // Assume it is near normalized (*0.5 or *2.0 is OK but * 0.001 is not).

    minFilterSize = 0;

    for (i = dstW - 1; i >= 0; i--) {

        int min = filter2Size;

        int j;

        int64_t cutOff = 0.0;

        /* get rid of near zero elements on the left by shifting left */

        for (j = 0; j < filter2Size; j++) {

            int k;

            cutOff += FFABS(filter2[i * filter2Size]);

            if (cutOff > SWS_MAX_REDUCE_CUTOFF * fone)

                break;

            /* preserve monotonicity because the core can't handle the

             * filter otherwise */

            if (i < dstW - 1 && (*filterPos)[i] >= (*filterPos)[i + 1])

                break;

            // move filter coefficients left

            for (k = 1; k < filter2Size; k++)

                filter2[i * filter2Size + k - 1] = filter2[i * filter2Size + k];

            filter2[i * filter2Size + k - 1] = 0;

            (*filterPos)[i]++;

        }

        cutOff = 0;

        /* count near zeros on the right */

        for (j = filter2Size - 1; j > 0; j--) {

            cutOff += FFABS(filter2[i * filter2Size + j]);

            if (cutOff > SWS_MAX_REDUCE_CUTOFF * fone)

                break;

            min--;

        }

        if (min > minFilterSize)

            minFilterSize = min;

    }

    if (PPC_ALTIVEC(cpu_flags)) {

        // we can handle the special case 4, so we don't want to go the full 8

        if (minFilterSize < 5)

            filterAlign = 4;

        /* We really don't want to waste our time doing useless computation, so

         * fall back on the scalar C code for very small filters.

         * Vectorizing is worth it only if you have a decent-sized vector. */

        if (minFilterSize < 3)

            filterAlign = 1;

    }

    if (HAVE_MMX && cpu_flags & AV_CPU_FLAG_MMX || have_neon(cpu_flags)) {

        // special case for unscaled vertical filtering

        if (minFilterSize == 1 && filterAlign == 2)

            filterAlign = 1;

    }

    if (have_lasx(cpu_flags) || have_lsx(cpu_flags)) {

        int reNum = minFilterSize & (0x07);

        if (minFilterSize < 5)

            filterAlign = 4;

        if (reNum < 3)

            filterAlign = 1;

    }

    av_assert0(minFilterSize > 0);

    filterSize = (minFilterSize + (filterAlign - 1)) & (~(filterAlign - 1));

    av_assert0(filterSize > 0);

    filter = av_malloc_array(dstW, filterSize * sizeof(*filter));

    if (!filter)

        goto nomem;

    if (filterSize >= MAX_FILTER_SIZE * 16 /

                      ((flags & SWS_ACCURATE_RND) ? APCK_SIZE : 16)) {

        ret = RETCODE_USE_CASCADE;

        goto fail;

    }

    *outFilterSize = filterSize;

    if (flags & SWS_PRINT_INFO)

        av_log(NULL, AV_LOG_VERBOSE,

               "SwScaler: reducing / aligning filtersize %d -> %d\n",

               filter2Size, filterSize);

    /* try to reduce the filter-size (step2 reduce it) */

    for (i = 0; i < dstW; i++) {

        int j;

        for (j = 0; j < filterSize; j++) {

            if (j >= filter2Size)

                filter[i * filterSize + j] = 0;

            else

                filter[i * filterSize + j] = filter2[i * filter2Size + j];

            if ((flags & SWS_BITEXACT) && j >= minFilterSize)

                filter[i * filterSize + j] = 0;

        }

    }

    // FIXME try to align filterPos if possible

    // fix borders

    for (i = 0; i < dstW; i++) {

        int j;

        if ((*filterPos)[i] < 0) {

            // move filter coefficients left to compensate for filterPos

            for (j = 1; j < filterSize; j++) {

                int left = FFMAX(j + (*filterPos)[i], 0);

                filter[i * filterSize + left] += filter[i * filterSize + j];

                filter[i * filterSize + j]     = 0;

            }

            (*filterPos)[i]= 0;

        }

        if ((*filterPos)[i] + filterSize > srcW) {

            int shift = (*filterPos)[i] + FFMIN(filterSize - srcW, 0);

            int64_t acc = 0;

            for (j = filterSize - 1; j >= 0; j--) {

                if ((*filterPos)[i] + j >= srcW) {

                    acc += filter[i * filterSize + j];

                    filter[i * filterSize + j] = 0;

                }

            }

            for (j = filterSize - 1; j >= 0; j--) {

                if (j < shift) {

                    filter[i * filterSize + j] = 0;

                } else {

                    filter[i * filterSize + j] = filter[i * filterSize + j - shift];

                }

            }

            (*filterPos)[i]-= shift;

            filter[i * filterSize + srcW - 1 - (*filterPos)[i]] += acc;

        }

        av_assert0((*filterPos)[i] >= 0);

        av_assert0((*filterPos)[i] < srcW);

        if ((*filterPos)[i] + filterSize > srcW) {

            for (j = 0; j < filterSize; j++) {

                av_assert0((*filterPos)[i] + j < srcW || !filter[i * filterSize + j]);

            }

        }

    }

    // Note the +1 is for the MMX scaler which reads over the end

    /* align at 16 for AltiVec (needed by hScale_altivec_real) */

    *outFilter = av_calloc(dstW + 3, *outFilterSize * sizeof(**outFilter));

    if (!*outFilter)

        goto nomem;

    /* normalize & store in outFilter */

    for (i = 0; i < dstW; i++) {

        int j;

        int64_t error = 0;

        int64_t sum   = 0;

        for (j = 0; j < filterSize; j++) {

            sum += filter[i * filterSize + j];

        }

        sum = (sum + one / 2) / one;

        if (!sum) {

            av_log(NULL, AV_LOG_WARNING, "SwScaler: zero vector in scaling\n");

            sum = 1;

        }

        for (j = 0; j < *outFilterSize; j++) {

            int64_t v = filter[i * filterSize + j] + error;

            int intV  = ROUNDED_DIV(v, sum);

            (*outFilter)[i * (*outFilterSize) + j] = intV;

            error                                  = v - intV * sum;

        }

    }

    (*filterPos)[dstW + 0] =

    (*filterPos)[dstW + 1] =

    (*filterPos)[dstW + 2] = (*filterPos)[dstW - 1]; /* the MMX/SSE scaler will

                                                      * read over the end */

    for (i = 0; i < *outFilterSize; i++) {

        int k = (dstW - 1) * (*outFilterSize) + i;

        (*outFilter)[k + 1 * (*outFilterSize)] =

        (*outFilter)[k + 2 * (*outFilterSize)] =

        (*outFilter)[k + 3 * (*outFilterSize)] = (*outFilter)[k];

    }

    ret = 0;

    goto done;

nomem:

    ret = AVERROR(ENOMEM);

fail:

    if(ret < 0)

        av_log(NULL, ret == RETCODE_USE_CASCADE ? AV_LOG_DEBUG : AV_LOG_ERROR, "sws: initFilter failed\n");

done:

    av_free(filter);

    av_free(filter2);

    return ret;

}

static void fill_rgb2yuv_table(SwsInternal *c, const int table[4], int dstRange)

{

    int64_t W, V, Z, Cy, Cu, Cv;

    int64_t vr =  table[0];

    int64_t ub =  table[1];

    int64_t ug = -table[2];

    int64_t vg = -table[3];

    int64_t ONE = 65536;

    int64_t cy = ONE;

    uint8_t *p = (uint8_t*)c->input_rgb2yuv_table;

    int i;

    static const int8_t map[] = {

    BY_IDX, GY_IDX, -1    , BY_IDX, BY_IDX, GY_IDX, -1    , BY_IDX,

    RY_IDX, -1    , GY_IDX, RY_IDX, RY_IDX, -1    , GY_IDX, RY_IDX,

    RY_IDX, GY_IDX, -1    , RY_IDX, RY_IDX, GY_IDX, -1    , RY_IDX,

    BY_IDX, -1    , GY_IDX, BY_IDX, BY_IDX, -1    , GY_IDX, BY_IDX,

    BU_IDX, GU_IDX, -1    , BU_IDX, BU_IDX, GU_IDX, -1    , BU_IDX,

    RU_IDX, -1    , GU_IDX, RU_IDX, RU_IDX, -1    , GU_IDX, RU_IDX,

    RU_IDX, GU_IDX, -1    , RU_IDX, RU_IDX, GU_IDX, -1    , RU_IDX,

    BU_IDX, -1    , GU_IDX, BU_IDX, BU_IDX, -1    , GU_IDX, BU_IDX,

    BV_IDX, GV_IDX, -1    , BV_IDX, BV_IDX, GV_IDX, -1    , BV_IDX,

    RV_IDX, -1    , GV_IDX, RV_IDX, RV_IDX, -1    , GV_IDX, RV_IDX,

    RV_IDX, GV_IDX, -1    , RV_IDX, RV_IDX, GV_IDX, -1    , RV_IDX,

    BV_IDX, -1    , GV_IDX, BV_IDX, BV_IDX, -1    , GV_IDX, BV_IDX,

    RY_IDX, BY_IDX, RY_IDX, BY_IDX, RY_IDX, BY_IDX, RY_IDX, BY_IDX,

    BY_IDX, RY_IDX, BY_IDX, RY_IDX, BY_IDX, RY_IDX, BY_IDX, RY_IDX,

    GY_IDX, -1    , GY_IDX, -1    , GY_IDX, -1    , GY_IDX, -1    ,

    -1    , GY_IDX, -1    , GY_IDX, -1    , GY_IDX, -1    , GY_IDX,

    RU_IDX, BU_IDX, RU_IDX, BU_IDX, RU_IDX, BU_IDX, RU_IDX, BU_IDX,

    BU_IDX, RU_IDX, BU_IDX, RU_IDX, BU_IDX, RU_IDX, BU_IDX, RU_IDX,

    GU_IDX, -1    , GU_IDX, -1    , GU_IDX, -1    , GU_IDX, -1    ,

    -1    , GU_IDX, -1    , GU_IDX, -1    , GU_IDX, -1    , GU_IDX,

    RV_IDX, BV_IDX, RV_IDX, BV_IDX, RV_IDX, BV_IDX, RV_IDX, BV_IDX,

    BV_IDX, RV_IDX, BV_IDX, RV_IDX, BV_IDX, RV_IDX, BV_IDX, RV_IDX,

    GV_IDX, -1    , GV_IDX, -1    , GV_IDX, -1    , GV_IDX, -1    ,

    -1    , GV_IDX, -1    , GV_IDX, -1    , GV_IDX, -1    , GV_IDX, //23

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //24

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //25

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //26

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //27

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //28

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //29

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //30

    -1    , -1    , -1    , -1    , -1    , -1    , -1    , -1    , //31

    BY_IDX, GY_IDX, RY_IDX, -1    , -1    , -1    , -1    , -1    , //32

    BU_IDX, GU_IDX, RU_IDX, -1    , -1    , -1    , -1    , -1    , //33

    BV_IDX, GV_IDX, RV_IDX, -1    , -1    , -1    , -1    , -1    , //34

    };

    dstRange = 0; //FIXME range = 1 is handled elsewhere

    if (!dstRange) {

        cy = cy * 255 / 219;

    } else {

        vr = vr * 224 / 255;

        ub = ub * 224 / 255;

        ug = ug * 224 / 255;

        vg = vg * 224 / 255;

    }

    W = ROUNDED_DIV(ONE*ONE*ug, ub);

    V = ROUNDED_DIV(ONE*ONE*vg, vr);

    Z = ONE*ONE-W-V;

    Cy = ROUNDED_DIV(cy*Z, ONE);

    Cu = ROUNDED_DIV(ub*Z, ONE);

    Cv = ROUNDED_DIV(vr*Z, ONE);

    c->input_rgb2yuv_table[RY_IDX] = -ROUNDED_DIV((1 << RGB2YUV_SHIFT)*V        , Cy);

    c->input_rgb2yuv_table[GY_IDX] =  ROUNDED_DIV((1 << RGB2YUV_SHIFT)*ONE*ONE  , Cy);

    c->input_rgb2yuv_table[BY_IDX] = -ROUNDED_DIV((1 << RGB2YUV_SHIFT)*W        , Cy);

    c->input_rgb2yuv_table[RU_IDX] =  ROUNDED_DIV((1 << RGB2YUV_SHIFT)*V        , Cu);

    c->input_rgb2yuv_table[GU_IDX] = -ROUNDED_DIV((1 << RGB2YUV_SHIFT)*ONE*ONE  , Cu);

    c->input_rgb2yuv_table[BU_IDX] =  ROUNDED_DIV((1 << RGB2YUV_SHIFT)*(Z+W)    , Cu);

    c->input_rgb2yuv_table[RV_IDX] =  ROUNDED_DIV((1 << RGB2YUV_SHIFT)*(V+Z)    , Cv);

    c->input_rgb2yuv_table[GV_IDX] = -ROUNDED_DIV((1 << RGB2YUV_SHIFT)*ONE*ONE  , Cv);

    c->input_rgb2yuv_table[BV_IDX] =  ROUNDED_DIV((1 << RGB2YUV_SHIFT)*W        , Cv);

    if(/*!dstRange && */!memcmp(table, ff_yuv2rgb_coeffs[SWS_CS_DEFAULT], sizeof(ff_yuv2rgb_coeffs[SWS_CS_DEFAULT]))) {

        c->input_rgb2yuv_table[BY_IDX] =  ((int)(0.114 * 219 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[BV_IDX] = (-(int)(0.081 * 224 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[BU_IDX] =  ((int)(0.500 * 224 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[GY_IDX] =  ((int)(0.587 * 219 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[GV_IDX] = (-(int)(0.419 * 224 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[GU_IDX] = (-(int)(0.331 * 224 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[RY_IDX] =  ((int)(0.299 * 219 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[RV_IDX] =  ((int)(0.500 * 224 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

        c->input_rgb2yuv_table[RU_IDX] = (-(int)(0.169 * 224 / 255 * (1 << RGB2YUV_SHIFT) + 0.5));

    }

    for(i=0; i<FF_ARRAY_ELEMS(map); i++)

        AV_WL16(p + 16*4 + 2*i, map[i] >= 0 ? c->input_rgb2yuv_table[map[i]] : 0);

}

#if CONFIG_SMALL

static void init_xyz_tables(uint16_t xyzgamma_tab[4096],  uint16_t xyzgammainv_tab[65536],

                            uint16_t rgbgamma_tab[65536], uint16_t rgbgammainv_tab[4096])

#else

static uint16_t xyzgamma_tab[4096],  rgbgammainv_tab[4096];

static uint16_t rgbgamma_tab[65536], xyzgammainv_tab[65536];

static av_cold void init_xyz_tables(void)

#endif

{

    double xyzgamma    = XYZ_GAMMA;

    double rgbgamma    = 1.0 / RGB_GAMMA;

    double xyzgammainv = 1.0 / XYZ_GAMMA;

    double rgbgammainv = RGB_GAMMA;

    /* set input gamma vectors */

    for (int i = 0; i < 4096; i++) {

        xyzgamma_tab[i]    = lrint(pow(i / 4095.0, xyzgamma)    * 65535.0);

        rgbgammainv_tab[i] = lrint(pow(i / 4095.0, rgbgammainv) * 65535.0);

    }

    /* set output gamma vectors */

    for (int i = 0; i < 65536; i++) {

        rgbgamma_tab[i]    = lrint(pow(i / 65535.0, rgbgamma)    * 4095.0);

        xyzgammainv_tab[i] = lrint(pow(i / 65535.0, xyzgammainv) * 4095.0);

    }

}

av_cold int ff_sws_fill_xyztables(SwsInternal *c)

{

    static const int16_t xyz2rgb_matrix[3][3] = {

        {13270, -6295, -2041},

        {-3969,  7682,   170},

        {  228,  -835,  4329} };

    static const int16_t rgb2xyz_matrix[3][3] = {

        {1689, 1464,  739},

        { 871, 2929,  296},

        {  79,  488, 3891} };

    if (c->xyz2rgb.gamma.in)

        return 0;

    memcpy(c->xyz2rgb.mat, xyz2rgb_matrix, sizeof(c->xyz2rgb.mat));

    memcpy(c->rgb2xyz.mat, rgb2xyz_matrix, sizeof(c->rgb2xyz.mat));

#if CONFIG_SMALL

    c->xyz2rgb.gamma.in = av_malloc(sizeof(uint16_t) * 2 * (4096 + 65536));

    if (!c->xyz2rgb.gamma.in)

        return AVERROR(ENOMEM);

    c->rgb2xyz.gamma.in  = c->xyz2rgb.gamma.in  + 4096;

    c->xyz2rgb.gamma.out = c->rgb2xyz.gamma.in  + 4096;

    c->rgb2xyz.gamma.out = c->xyz2rgb.gamma.out + 65536;

    init_xyz_tables(c->xyz2rgb.gamma.in,  c->rgb2xyz.gamma.out,

                    c->xyz2rgb.gamma.out, c->rgb2xyz.gamma.in);

#else

    c->xyz2rgb.gamma.in  = xyzgamma_tab;

    c->xyz2rgb.gamma.out = rgbgamma_tab;

    c->rgb2xyz.gamma.in  = rgbgammainv_tab;

    c->rgb2xyz.gamma.out = xyzgammainv_tab;

    static AVOnce xyz_init_static_once = AV_ONCE_INIT;

    ff_thread_once(&xyz_init_static_once, init_xyz_tables);

#endif

    return 0;

}

static int handle_jpeg(/* enum AVPixelFormat */ int *format)

{

    switch (*format) {

    case AV_PIX_FMT_YUVJ420P:

        *format = AV_PIX_FMT_YUV420P;

        return 1;

    case AV_PIX_FMT_YUVJ411P:

        *format = AV_PIX_FMT_YUV411P;

        return 1;

    case AV_PIX_FMT_YUVJ422P:

        *format = AV_PIX_FMT_YUV422P;

        return 1;

    case AV_PIX_FMT_YUVJ444P:

        *format = AV_PIX_FMT_YUV444P;

        return 1;

    case AV_PIX_FMT_YUVJ440P:

        *format = AV_PIX_FMT_YUV440P;

        return 1;

    case AV_PIX_FMT_GRAY8:

    case AV_PIX_FMT_YA8:

    case AV_PIX_FMT_GRAY9LE:

    case AV_PIX_FMT_GRAY9BE:

    case AV_PIX_FMT_GRAY10LE:

    case AV_PIX_FMT_GRAY10BE:

    case AV_PIX_FMT_GRAY12LE:

    case AV_PIX_FMT_GRAY12BE:

    case AV_PIX_FMT_GRAY14LE:

    case AV_PIX_FMT_GRAY14BE:

    case AV_PIX_FMT_GRAY16LE:

    case AV_PIX_FMT_GRAY16BE:

    case AV_PIX_FMT_YA16BE:

    case AV_PIX_FMT_YA16LE:

        return 1;

    default:

        return 0;

    }

}

static int handle_0alpha(/* enum AVPixelFormat */ int *format)

{

    switch (*format) {

    case AV_PIX_FMT_0BGR    : *format = AV_PIX_FMT_ABGR   ; return 1;

    case AV_PIX_FMT_BGR0    : *format = AV_PIX_FMT_BGRA   ; return 4;

    case AV_PIX_FMT_0RGB    : *format = AV_PIX_FMT_ARGB   ; return 1;

    case AV_PIX_FMT_RGB0    : *format = AV_PIX_FMT_RGBA   ; return 4;

    default:                                          return 0;

    }

}

static int handle_xyz(/* enum AVPixelFormat */ int *format)

{

    switch (*format) {

    case AV_PIX_FMT_XYZ12BE : *format = AV_PIX_FMT_RGB48BE; return 1;

    case AV_PIX_FMT_XYZ12LE : *format = AV_PIX_FMT_RGB48LE; return 1;

    default:                                                return 0;

    }