mirror of
https://github.com/cwinfo/matterbridge.git
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53cafa9f3d
This commit adds support for go/cgo tgs conversion when building with the -tags `cgo` The default binaries are still "pure" go and uses the old way of converting. * Move lottie_convert.py conversion code to its own file * Add optional libtgsconverter * Update vendor * Apply suggestions from code review * Update bridge/helper/libtgsconverter.go Co-authored-by: Wim <wim@42.be>
160 lines
5.2 KiB
C
160 lines
5.2 KiB
C
// Copyright 2017 Google Inc. All Rights Reserved.
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//
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// Use of this source code is governed by a BSD-style license
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// that can be found in the COPYING file in the root of the source
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// tree. An additional intellectual property rights grant can be found
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// in the file PATENTS. All contributing project authors may
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// be found in the AUTHORS file in the root of the source tree.
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// -----------------------------------------------------------------------------
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//
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// distortion calculation
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//
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// Author: Skal (pascal.massimino@gmail.com)
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#include <assert.h>
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#include <stdlib.h> // for abs()
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#include "dsp_dsp.h"
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#if !defined(WEBP_REDUCE_SIZE)
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//------------------------------------------------------------------------------
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// SSIM / PSNR
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// hat-shaped filter. Sum of coefficients is equal to 16.
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static const uint32_t kWeight[2 * VP8_SSIM_KERNEL + 1] = {
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1, 2, 3, 4, 3, 2, 1
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};
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static const uint32_t kWeightSum = 16 * 16; // sum{kWeight}^2
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static WEBP_INLINE double SSIMCalculation(
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const VP8DistoStats* const stats, uint32_t N /*num samples*/) {
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const uint32_t w2 = N * N;
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const uint32_t C1 = 20 * w2;
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const uint32_t C2 = 60 * w2;
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const uint32_t C3 = 8 * 8 * w2; // 'dark' limit ~= 6
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const uint64_t xmxm = (uint64_t)stats->xm * stats->xm;
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const uint64_t ymym = (uint64_t)stats->ym * stats->ym;
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if (xmxm + ymym >= C3) {
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const int64_t xmym = (int64_t)stats->xm * stats->ym;
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const int64_t sxy = (int64_t)stats->xym * N - xmym; // can be negative
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const uint64_t sxx = (uint64_t)stats->xxm * N - xmxm;
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const uint64_t syy = (uint64_t)stats->yym * N - ymym;
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// we descale by 8 to prevent overflow during the fnum/fden multiply.
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const uint64_t num_S = (2 * (uint64_t)(sxy < 0 ? 0 : sxy) + C2) >> 8;
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const uint64_t den_S = (sxx + syy + C2) >> 8;
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const uint64_t fnum = (2 * xmym + C1) * num_S;
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const uint64_t fden = (xmxm + ymym + C1) * den_S;
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const double r = (double)fnum / fden;
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assert(r >= 0. && r <= 1.0);
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return r;
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}
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return 1.; // area is too dark to contribute meaningfully
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}
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double VP8SSIMFromStats(const VP8DistoStats* const stats) {
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return SSIMCalculation(stats, kWeightSum);
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}
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double VP8SSIMFromStatsClipped(const VP8DistoStats* const stats) {
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return SSIMCalculation(stats, stats->w);
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}
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static double SSIMGetClipped_C(const uint8_t* src1, int stride1,
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const uint8_t* src2, int stride2,
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int xo, int yo, int W, int H) {
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VP8DistoStats stats = { 0, 0, 0, 0, 0, 0 };
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const int ymin = (yo - VP8_SSIM_KERNEL < 0) ? 0 : yo - VP8_SSIM_KERNEL;
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const int ymax = (yo + VP8_SSIM_KERNEL > H - 1) ? H - 1
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: yo + VP8_SSIM_KERNEL;
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const int xmin = (xo - VP8_SSIM_KERNEL < 0) ? 0 : xo - VP8_SSIM_KERNEL;
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const int xmax = (xo + VP8_SSIM_KERNEL > W - 1) ? W - 1
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: xo + VP8_SSIM_KERNEL;
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int x, y;
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src1 += ymin * stride1;
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src2 += ymin * stride2;
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for (y = ymin; y <= ymax; ++y, src1 += stride1, src2 += stride2) {
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for (x = xmin; x <= xmax; ++x) {
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const uint32_t w = kWeight[VP8_SSIM_KERNEL + x - xo]
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* kWeight[VP8_SSIM_KERNEL + y - yo];
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const uint32_t s1 = src1[x];
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const uint32_t s2 = src2[x];
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stats.w += w;
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stats.xm += w * s1;
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stats.ym += w * s2;
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stats.xxm += w * s1 * s1;
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stats.xym += w * s1 * s2;
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stats.yym += w * s2 * s2;
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}
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}
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return VP8SSIMFromStatsClipped(&stats);
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}
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static double SSIMGet_C(const uint8_t* src1, int stride1,
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const uint8_t* src2, int stride2) {
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VP8DistoStats stats = { 0, 0, 0, 0, 0, 0 };
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int x, y;
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for (y = 0; y <= 2 * VP8_SSIM_KERNEL; ++y, src1 += stride1, src2 += stride2) {
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for (x = 0; x <= 2 * VP8_SSIM_KERNEL; ++x) {
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const uint32_t w = kWeight[x] * kWeight[y];
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const uint32_t s1 = src1[x];
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const uint32_t s2 = src2[x];
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stats.xm += w * s1;
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stats.ym += w * s2;
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stats.xxm += w * s1 * s1;
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stats.xym += w * s1 * s2;
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stats.yym += w * s2 * s2;
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}
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}
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return VP8SSIMFromStats(&stats);
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}
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#endif // !defined(WEBP_REDUCE_SIZE)
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//------------------------------------------------------------------------------
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#if !defined(WEBP_DISABLE_STATS)
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static uint32_t AccumulateSSE_C(const uint8_t* src1,
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const uint8_t* src2, int len) {
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int i;
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uint32_t sse2 = 0;
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assert(len <= 65535); // to ensure that accumulation fits within uint32_t
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for (i = 0; i < len; ++i) {
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const int32_t diff = src1[i] - src2[i];
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sse2 += diff * diff;
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}
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return sse2;
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}
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#endif
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//------------------------------------------------------------------------------
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#if !defined(WEBP_REDUCE_SIZE)
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VP8SSIMGetFunc VP8SSIMGet;
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VP8SSIMGetClippedFunc VP8SSIMGetClipped;
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#endif
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#if !defined(WEBP_DISABLE_STATS)
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VP8AccumulateSSEFunc VP8AccumulateSSE;
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#endif
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extern void VP8SSIMDspInitSSE2(void);
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WEBP_DSP_INIT_FUNC(VP8SSIMDspInit) {
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#if !defined(WEBP_REDUCE_SIZE)
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VP8SSIMGetClipped = SSIMGetClipped_C;
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VP8SSIMGet = SSIMGet_C;
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#endif
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#if !defined(WEBP_DISABLE_STATS)
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VP8AccumulateSSE = AccumulateSSE_C;
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#endif
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if (VP8GetCPUInfo != NULL) {
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#if defined(WEBP_USE_SSE2)
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if (VP8GetCPUInfo(kSSE2)) {
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VP8SSIMDspInitSSE2();
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}
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#endif
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}
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}
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