diff options
Diffstat (limited to 'src/3rdparty/libwebp/src/dsp/lossless_enc.c')
| -rw-r--r-- | src/3rdparty/libwebp/src/dsp/lossless_enc.c | 953 |
1 files changed, 239 insertions, 714 deletions
diff --git a/src/3rdparty/libwebp/src/dsp/lossless_enc.c b/src/3rdparty/libwebp/src/dsp/lossless_enc.c index 256f6f5..4e46fba 100644 --- a/src/3rdparty/libwebp/src/dsp/lossless_enc.c +++ b/src/3rdparty/libwebp/src/dsp/lossless_enc.c @@ -17,16 +17,12 @@ #include <math.h> #include <stdlib.h> -#include "../dec/vp8li.h" -#include "../utils/endian_inl.h" +#include "../dec/vp8li_dec.h" +#include "../utils/endian_inl_utils.h" #include "./lossless.h" +#include "./lossless_common.h" #include "./yuv.h" -#define MAX_DIFF_COST (1e30f) - -static const int kPredLowEffort = 11; -static const uint32_t kMaskAlpha = 0xff000000; - // lookup table for small values of log2(int) const float kLog2Table[LOG_LOOKUP_IDX_MAX] = { 0.0000000000000000f, 0.0000000000000000f, @@ -380,26 +376,9 @@ static float FastLog2Slow(uint32_t v) { } } -// Mostly used to reduce code size + readability -static WEBP_INLINE int GetMin(int a, int b) { return (a > b) ? b : a; } -static WEBP_INLINE int GetMax(int a, int b) { return (a < b) ? b : a; } - //------------------------------------------------------------------------------ // Methods to calculate Entropy (Shannon). -static float PredictionCostSpatial(const int counts[256], int weight_0, - double exp_val) { - const int significant_symbols = 256 >> 4; - const double exp_decay_factor = 0.6; - double bits = weight_0 * counts[0]; - int i; - for (i = 1; i < significant_symbols; ++i) { - bits += exp_val * (counts[i] + counts[256 - i]); - exp_val *= exp_decay_factor; - } - return (float)(-0.1 * bits); -} - // Compute the combined Shanon's entropy for distribution {X} and {X+Y} static float CombinedShannonEntropy(const int X[256], const int Y[256]) { int i; @@ -422,18 +401,6 @@ static float CombinedShannonEntropy(const int X[256], const int Y[256]) { return (float)retval; } -static float PredictionCostSpatialHistogram(const int accumulated[4][256], - const int tile[4][256]) { - int i; - double retval = 0; - for (i = 0; i < 4; ++i) { - const double kExpValue = 0.94; - retval += PredictionCostSpatial(tile[i], 1, kExpValue); - retval += VP8LCombinedShannonEntropy(tile[i], accumulated[i]); - } - return (float)retval; -} - void VP8LBitEntropyInit(VP8LBitEntropy* const entropy) { entropy->entropy = 0.; entropy->sum = 0; @@ -486,9 +453,9 @@ static WEBP_INLINE void GetEntropyUnrefinedHelper( *i_prev = i; } -void VP8LGetEntropyUnrefined(const uint32_t* const X, int length, - VP8LBitEntropy* const bit_entropy, - VP8LStreaks* const stats) { +static void GetEntropyUnrefined(const uint32_t X[], int length, + VP8LBitEntropy* const bit_entropy, + VP8LStreaks* const stats) { int i; int i_prev = 0; uint32_t x_prev = X[0]; @@ -499,18 +466,18 @@ void VP8LGetEntropyUnrefined(const uint32_t* const X, int length, for (i = 1; i < length; ++i) { const uint32_t x = X[i]; if (x != x_prev) { - VP8LGetEntropyUnrefinedHelper(x, i, &x_prev, &i_prev, bit_entropy, stats); + GetEntropyUnrefinedHelper(x, i, &x_prev, &i_prev, bit_entropy, stats); } } - VP8LGetEntropyUnrefinedHelper(0, i, &x_prev, &i_prev, bit_entropy, stats); + GetEntropyUnrefinedHelper(0, i, &x_prev, &i_prev, bit_entropy, stats); bit_entropy->entropy += VP8LFastSLog2(bit_entropy->sum); } -void VP8LGetCombinedEntropyUnrefined(const uint32_t* const X, - const uint32_t* const Y, int length, - VP8LBitEntropy* const bit_entropy, - VP8LStreaks* const stats) { +static void GetCombinedEntropyUnrefined(const uint32_t X[], const uint32_t Y[], + int length, + VP8LBitEntropy* const bit_entropy, + VP8LStreaks* const stats) { int i = 1; int i_prev = 0; uint32_t xy_prev = X[0] + Y[0]; @@ -521,439 +488,29 @@ void VP8LGetCombinedEntropyUnrefined(const uint32_t* const X, for (i = 1; i < length; ++i) { const uint32_t xy = X[i] + Y[i]; if (xy != xy_prev) { - VP8LGetEntropyUnrefinedHelper(xy, i, &xy_prev, &i_prev, bit_entropy, - stats); + GetEntropyUnrefinedHelper(xy, i, &xy_prev, &i_prev, bit_entropy, stats); } } - VP8LGetEntropyUnrefinedHelper(0, i, &xy_prev, &i_prev, bit_entropy, stats); + GetEntropyUnrefinedHelper(0, i, &xy_prev, &i_prev, bit_entropy, stats); bit_entropy->entropy += VP8LFastSLog2(bit_entropy->sum); } -static WEBP_INLINE void UpdateHisto(int histo_argb[4][256], uint32_t argb) { - ++histo_argb[0][argb >> 24]; - ++histo_argb[1][(argb >> 16) & 0xff]; - ++histo_argb[2][(argb >> 8) & 0xff]; - ++histo_argb[3][argb & 0xff]; -} - //------------------------------------------------------------------------------ -static WEBP_INLINE uint32_t Predict(VP8LPredictorFunc pred_func, - int x, int y, - const uint32_t* current_row, - const uint32_t* upper_row) { - if (y == 0) { - return (x == 0) ? ARGB_BLACK : current_row[x - 1]; // Left. - } else if (x == 0) { - return upper_row[x]; // Top. - } else { - return pred_func(current_row[x - 1], upper_row + x); - } -} - -static int MaxDiffBetweenPixels(uint32_t p1, uint32_t p2) { - const int diff_a = abs((int)(p1 >> 24) - (int)(p2 >> 24)); - const int diff_r = abs((int)((p1 >> 16) & 0xff) - (int)((p2 >> 16) & 0xff)); - const int diff_g = abs((int)((p1 >> 8) & 0xff) - (int)((p2 >> 8) & 0xff)); - const int diff_b = abs((int)(p1 & 0xff) - (int)(p2 & 0xff)); - return GetMax(GetMax(diff_a, diff_r), GetMax(diff_g, diff_b)); -} - -static int MaxDiffAroundPixel(uint32_t current, uint32_t up, uint32_t down, - uint32_t left, uint32_t right) { - const int diff_up = MaxDiffBetweenPixels(current, up); - const int diff_down = MaxDiffBetweenPixels(current, down); - const int diff_left = MaxDiffBetweenPixels(current, left); - const int diff_right = MaxDiffBetweenPixels(current, right); - return GetMax(GetMax(diff_up, diff_down), GetMax(diff_left, diff_right)); -} - -static uint32_t AddGreenToBlueAndRed(uint32_t argb) { - const uint32_t green = (argb >> 8) & 0xff; - uint32_t red_blue = argb & 0x00ff00ffu; - red_blue += (green << 16) | green; - red_blue &= 0x00ff00ffu; - return (argb & 0xff00ff00u) | red_blue; -} - -static void MaxDiffsForRow(int width, int stride, const uint32_t* const argb, - uint8_t* const max_diffs, int used_subtract_green) { - uint32_t current, up, down, left, right; - int x; - if (width <= 2) return; - current = argb[0]; - right = argb[1]; - if (used_subtract_green) { - current = AddGreenToBlueAndRed(current); - right = AddGreenToBlueAndRed(right); - } - // max_diffs[0] and max_diffs[width - 1] are never used. - for (x = 1; x < width - 1; ++x) { - up = argb[-stride + x]; - down = argb[stride + x]; - left = current; - current = right; - right = argb[x + 1]; - if (used_subtract_green) { - up = AddGreenToBlueAndRed(up); - down = AddGreenToBlueAndRed(down); - right = AddGreenToBlueAndRed(right); - } - max_diffs[x] = MaxDiffAroundPixel(current, up, down, left, right); - } -} - -// Quantize the difference between the actual component value and its prediction -// to a multiple of quantization, working modulo 256, taking care not to cross -// a boundary (inclusive upper limit). -static uint8_t NearLosslessComponent(uint8_t value, uint8_t predict, - uint8_t boundary, int quantization) { - const int residual = (value - predict) & 0xff; - const int boundary_residual = (boundary - predict) & 0xff; - const int lower = residual & ~(quantization - 1); - const int upper = lower + quantization; - // Resolve ties towards a value closer to the prediction (i.e. towards lower - // if value comes after prediction and towards upper otherwise). - const int bias = ((boundary - value) & 0xff) < boundary_residual; - if (residual - lower < upper - residual + bias) { - // lower is closer to residual than upper. - if (residual > boundary_residual && lower <= boundary_residual) { - // Halve quantization step to avoid crossing boundary. This midpoint is - // on the same side of boundary as residual because midpoint >= residual - // (since lower is closer than upper) and residual is above the boundary. - return lower + (quantization >> 1); - } - return lower; - } else { - // upper is closer to residual than lower. - if (residual <= boundary_residual && upper > boundary_residual) { - // Halve quantization step to avoid crossing boundary. This midpoint is - // on the same side of boundary as residual because midpoint <= residual - // (since upper is closer than lower) and residual is below the boundary. - return lower + (quantization >> 1); - } - return upper & 0xff; - } -} - -// Quantize every component of the difference between the actual pixel value and -// its prediction to a multiple of a quantization (a power of 2, not larger than -// max_quantization which is a power of 2, smaller than max_diff). Take care if -// value and predict have undergone subtract green, which means that red and -// blue are represented as offsets from green. -static uint32_t NearLossless(uint32_t value, uint32_t predict, - int max_quantization, int max_diff, - int used_subtract_green) { - int quantization; - uint8_t new_green = 0; - uint8_t green_diff = 0; - uint8_t a, r, g, b; - if (max_diff <= 2) { - return VP8LSubPixels(value, predict); - } - quantization = max_quantization; - while (quantization >= max_diff) { - quantization >>= 1; - } - if ((value >> 24) == 0 || (value >> 24) == 0xff) { - // Preserve transparency of fully transparent or fully opaque pixels. - a = ((value >> 24) - (predict >> 24)) & 0xff; - } else { - a = NearLosslessComponent(value >> 24, predict >> 24, 0xff, quantization); - } - g = NearLosslessComponent((value >> 8) & 0xff, (predict >> 8) & 0xff, 0xff, - quantization); - if (used_subtract_green) { - // The green offset will be added to red and blue components during decoding - // to obtain the actual red and blue values. - new_green = ((predict >> 8) + g) & 0xff; - // The amount by which green has been adjusted during quantization. It is - // subtracted from red and blue for compensation, to avoid accumulating two - // quantization errors in them. - green_diff = (new_green - (value >> 8)) & 0xff; - } - r = NearLosslessComponent(((value >> 16) - green_diff) & 0xff, - (predict >> 16) & 0xff, 0xff - new_green, - quantization); - b = NearLosslessComponent((value - green_diff) & 0xff, predict & 0xff, - 0xff - new_green, quantization); - return ((uint32_t)a << 24) | ((uint32_t)r << 16) | ((uint32_t)g << 8) | b; -} - -// Returns the difference between the pixel and its prediction. In case of a -// lossy encoding, updates the source image to avoid propagating the deviation -// further to pixels which depend on the current pixel for their predictions. -static WEBP_INLINE uint32_t GetResidual(int width, int height, - uint32_t* const upper_row, - uint32_t* const current_row, - const uint8_t* const max_diffs, - int mode, VP8LPredictorFunc pred_func, - int x, int y, int max_quantization, - int exact, int used_subtract_green) { - const uint32_t predict = Predict(pred_func, x, y, current_row, upper_row); - uint32_t residual; - if (max_quantization == 1 || mode == 0 || y == 0 || y == height - 1 || - x == 0 || x == width - 1) { - residual = VP8LSubPixels(current_row[x], predict); - } else { - residual = NearLossless(current_row[x], predict, max_quantization, - max_diffs[x], used_subtract_green); - // Update the source image. - current_row[x] = VP8LAddPixels(predict, residual); - // x is never 0 here so we do not need to update upper_row like below. - } - if (!exact && (current_row[x] & kMaskAlpha) == 0) { - // If alpha is 0, cleanup RGB. We can choose the RGB values of the residual - // for best compression. The prediction of alpha itself can be non-zero and - // must be kept though. We choose RGB of the residual to be 0. - residual &= kMaskAlpha; - // Update the source image. - current_row[x] = predict & ~kMaskAlpha; - // The prediction for the rightmost pixel in a row uses the leftmost pixel - // in that row as its top-right context pixel. Hence if we change the - // leftmost pixel of current_row, the corresponding change must be applied - // to upper_row as well where top-right context is being read from. - if (x == 0 && y != 0) upper_row[width] = current_row[0]; - } - return residual; -} - -// Returns best predictor and updates the accumulated histogram. -// If max_quantization > 1, assumes that near lossless processing will be -// applied, quantizing residuals to multiples of quantization levels up to -// max_quantization (the actual quantization level depends on smoothness near -// the given pixel). -static int GetBestPredictorForTile(int width, int height, - int tile_x, int tile_y, int bits, - int accumulated[4][256], - uint32_t* const argb_scratch, - const uint32_t* const argb, - int max_quantization, - int exact, int used_subtract_green) { - const int kNumPredModes = 14; - const int start_x = tile_x << bits; - const int start_y = tile_y << bits; - const int tile_size = 1 << bits; - const int max_y = GetMin(tile_size, height - start_y); - const int max_x = GetMin(tile_size, width - start_x); - // Whether there exist columns just outside the tile. - const int have_left = (start_x > 0); - const int have_right = (max_x < width - start_x); - // Position and size of the strip covering the tile and adjacent columns if - // they exist. - const int context_start_x = start_x - have_left; - const int context_width = max_x + have_left + have_right; - // The width of upper_row and current_row is one pixel larger than image width - // to allow the top right pixel to point to the leftmost pixel of the next row - // when at the right edge. - uint32_t* upper_row = argb_scratch; - uint32_t* current_row = upper_row + width + 1; - uint8_t* const max_diffs = (uint8_t*)(current_row + width + 1); - float best_diff = MAX_DIFF_COST; - int best_mode = 0; - int mode; - int histo_stack_1[4][256]; - int histo_stack_2[4][256]; - // Need pointers to be able to swap arrays. - int (*histo_argb)[256] = histo_stack_1; - int (*best_histo)[256] = histo_stack_2; - int i, j; - - for (mode = 0; mode < kNumPredModes; ++mode) { - const VP8LPredictorFunc pred_func = VP8LPredictors[mode]; - float cur_diff; - int relative_y; - memset(histo_argb, 0, sizeof(histo_stack_1)); - if (start_y > 0) { - // Read the row above the tile which will become the first upper_row. - // Include a pixel to the left if it exists; include a pixel to the right - // in all cases (wrapping to the leftmost pixel of the next row if it does - // not exist). - memcpy(current_row + context_start_x, - argb + (start_y - 1) * width + context_start_x, - sizeof(*argb) * (max_x + have_left + 1)); - } - for (relative_y = 0; relative_y < max_y; ++relative_y) { - const int y = start_y + relative_y; - int relative_x; - uint32_t* tmp = upper_row; - upper_row = current_row; - current_row = tmp; - // Read current_row. Include a pixel to the left if it exists; include a - // pixel to the right in all cases except at the bottom right corner of - // the image (wrapping to the leftmost pixel of the next row if it does - // not exist in the current row). - memcpy(current_row + context_start_x, - argb + y * width + context_start_x, - sizeof(*argb) * (max_x + have_left + (y + 1 < height))); - if (max_quantization > 1 && y >= 1 && y + 1 < height) { - MaxDiffsForRow(context_width, width, argb + y * width + context_start_x, - max_diffs + context_start_x, used_subtract_green); - } - - for (relative_x = 0; relative_x < max_x; ++relative_x) { - const int x = start_x + relative_x; - UpdateHisto(histo_argb, - GetResidual(width, height, upper_row, current_row, - max_diffs, mode, pred_func, x, y, - max_quantization, exact, used_subtract_green)); - } - } - cur_diff = PredictionCostSpatialHistogram( - (const int (*)[256])accumulated, (const int (*)[256])histo_argb); - if (cur_diff < best_diff) { - int (*tmp)[256] = histo_argb; - histo_argb = best_histo; - best_histo = tmp; - best_diff = cur_diff; - best_mode = mode; - } - } - - for (i = 0; i < 4; i++) { - for (j = 0; j < 256; j++) { - accumulated[i][j] += best_histo[i][j]; - } - } - - return best_mode; -} - -// Converts pixels of the image to residuals with respect to predictions. -// If max_quantization > 1, applies near lossless processing, quantizing -// residuals to multiples of quantization levels up to max_quantization -// (the actual quantization level depends on smoothness near the given pixel). -static void CopyImageWithPrediction(int width, int height, - int bits, uint32_t* const modes, - uint32_t* const argb_scratch, - uint32_t* const argb, - int low_effort, int max_quantization, - int exact, int used_subtract_green) { - const int tiles_per_row = VP8LSubSampleSize(width, bits); - const int mask = (1 << bits) - 1; - // The width of upper_row and current_row is one pixel larger than image width - // to allow the top right pixel to point to the leftmost pixel of the next row - // when at the right edge. - uint32_t* upper_row = argb_scratch; - uint32_t* current_row = upper_row + width + 1; - uint8_t* current_max_diffs = (uint8_t*)(current_row + width + 1); - uint8_t* lower_max_diffs = current_max_diffs + width; - int y; - int mode = 0; - VP8LPredictorFunc pred_func = NULL; - - for (y = 0; y < height; ++y) { - int x; - uint32_t* const tmp32 = upper_row; - upper_row = current_row; - current_row = tmp32; - memcpy(current_row, argb + y * width, - sizeof(*argb) * (width + (y + 1 < height))); - - if (low_effort) { - for (x = 0; x < width; ++x) { - const uint32_t predict = Predict(VP8LPredictors[kPredLowEffort], x, y, - current_row, upper_row); - argb[y * width + x] = VP8LSubPixels(current_row[x], predict); - } - } else { - if (max_quantization > 1) { - // Compute max_diffs for the lower row now, because that needs the - // contents of argb for the current row, which we will overwrite with - // residuals before proceeding with the next row. - uint8_t* const tmp8 = current_max_diffs; - current_max_diffs = lower_max_diffs; - lower_max_diffs = tmp8; - if (y + 2 < height) { - MaxDiffsForRow(width, width, argb + (y + 1) * width, lower_max_diffs, - used_subtract_green); - } - } - for (x = 0; x < width; ++x) { - if ((x & mask) == 0) { - mode = (modes[(y >> bits) * tiles_per_row + (x >> bits)] >> 8) & 0xff; - pred_func = VP8LPredictors[mode]; - } - argb[y * width + x] = GetResidual( - width, height, upper_row, current_row, current_max_diffs, mode, - pred_func, x, y, max_quantization, exact, used_subtract_green); - } - } - } -} - -// Finds the best predictor for each tile, and converts the image to residuals -// with respect to predictions. If near_lossless_quality < 100, applies -// near lossless processing, shaving off more bits of residuals for lower -// qualities. -void VP8LResidualImage(int width, int height, int bits, int low_effort, - uint32_t* const argb, uint32_t* const argb_scratch, - uint32_t* const image, int near_lossless_quality, - int exact, int used_subtract_green) { - const int tiles_per_row = VP8LSubSampleSize(width, bits); - const int tiles_per_col = VP8LSubSampleSize(height, bits); - int tile_y; - int histo[4][256]; - const int max_quantization = 1 << VP8LNearLosslessBits(near_lossless_quality); - if (low_effort) { - int i; - for (i = 0; i < tiles_per_row * tiles_per_col; ++i) { - image[i] = ARGB_BLACK | (kPredLowEffort << 8); - } - } else { - memset(histo, 0, sizeof(histo)); - for (tile_y = 0; tile_y < tiles_per_col; ++tile_y) { - int tile_x; - for (tile_x = 0; tile_x < tiles_per_row; ++tile_x) { - const int pred = GetBestPredictorForTile(width, height, tile_x, tile_y, - bits, histo, argb_scratch, argb, max_quantization, exact, - used_subtract_green); - image[tile_y * tiles_per_row + tile_x] = ARGB_BLACK | (pred << 8); - } - } - } - - CopyImageWithPrediction(width, height, bits, image, argb_scratch, argb, - low_effort, max_quantization, exact, - used_subtract_green); -} - void VP8LSubtractGreenFromBlueAndRed_C(uint32_t* argb_data, int num_pixels) { int i; for (i = 0; i < num_pixels; ++i) { - const uint32_t argb = argb_data[i]; - const uint32_t green = (argb >> 8) & 0xff; + const int argb = argb_data[i]; + const int green = (argb >> 8) & 0xff; const uint32_t new_r = (((argb >> 16) & 0xff) - green) & 0xff; - const uint32_t new_b = ((argb & 0xff) - green) & 0xff; - argb_data[i] = (argb & 0xff00ff00) | (new_r << 16) | new_b; + const uint32_t new_b = (((argb >> 0) & 0xff) - green) & 0xff; + argb_data[i] = (argb & 0xff00ff00u) | (new_r << 16) | new_b; } } -static WEBP_INLINE void MultipliersClear(VP8LMultipliers* const m) { - m->green_to_red_ = 0; - m->green_to_blue_ = 0; - m->red_to_blue_ = 0; -} - -static WEBP_INLINE uint32_t ColorTransformDelta(int8_t color_pred, - int8_t color) { - return (uint32_t)((int)(color_pred) * color) >> 5; -} - -static WEBP_INLINE void ColorCodeToMultipliers(uint32_t color_code, - VP8LMultipliers* const m) { - m->green_to_red_ = (color_code >> 0) & 0xff; - m->green_to_blue_ = (color_code >> 8) & 0xff; - m->red_to_blue_ = (color_code >> 16) & 0xff; -} - -static WEBP_INLINE uint32_t MultipliersToColorCode( - const VP8LMultipliers* const m) { - return 0xff000000u | - ((uint32_t)(m->red_to_blue_) << 16) | - ((uint32_t)(m->green_to_blue_) << 8) | - m->green_to_red_; +static WEBP_INLINE int ColorTransformDelta(int8_t color_pred, int8_t color) { + return ((int)color_pred * color) >> 5; } void VP8LTransformColor_C(const VP8LMultipliers* const m, uint32_t* data, @@ -963,8 +520,8 @@ void VP8LTransformColor_C(const VP8LMultipliers* const m, uint32_t* data, const uint32_t argb = data[i]; const uint32_t green = argb >> 8; const uint32_t red = argb >> 16; - uint32_t new_red = red; - uint32_t new_blue = argb; + int new_red = red; + int new_blue = argb; new_red -= ColorTransformDelta(m->green_to_red_, green); new_red &= 0xff; new_blue -= ColorTransformDelta(m->green_to_blue_, green); @@ -977,7 +534,7 @@ void VP8LTransformColor_C(const VP8LMultipliers* const m, uint32_t* data, static WEBP_INLINE uint8_t TransformColorRed(uint8_t green_to_red, uint32_t argb) { const uint32_t green = argb >> 8; - uint32_t new_red = argb >> 16; + int new_red = argb >> 16; new_red -= ColorTransformDelta(green_to_red, green); return (new_red & 0xff); } @@ -993,15 +550,6 @@ static WEBP_INLINE uint8_t TransformColorBlue(uint8_t green_to_blue, return (new_blue & 0xff); } -static float PredictionCostCrossColor(const int accumulated[256], - const int counts[256]) { - // Favor low entropy, locally and globally. - // Favor small absolute values for PredictionCostSpatial - static const double kExpValue = 2.4; - return VP8LCombinedShannonEntropy(counts, accumulated) + - PredictionCostSpatial(counts, 3, kExpValue); -} - void VP8LCollectColorRedTransforms_C(const uint32_t* argb, int stride, int tile_width, int tile_height, int green_to_red, int histo[]) { @@ -1014,59 +562,6 @@ void VP8LCollectColorRedTransforms_C(const uint32_t* argb, int stride, } } -static float GetPredictionCostCrossColorRed( - const uint32_t* argb, int stride, int tile_width, int tile_height, - VP8LMultipliers prev_x, VP8LMultipliers prev_y, int green_to_red, - const int accumulated_red_histo[256]) { - int histo[256] = { 0 }; - float cur_diff; - - VP8LCollectColorRedTransforms(argb, stride, tile_width, tile_height, - green_to_red, histo); - - cur_diff = PredictionCostCrossColor(accumulated_red_histo, histo); - if ((uint8_t)green_to_red == prev_x.green_to_red_) { - cur_diff -= 3; // favor keeping the areas locally similar - } - if ((uint8_t)green_to_red == prev_y.green_to_red_) { - cur_diff -= 3; // favor keeping the areas locally similar - } - if (green_to_red == 0) { - cur_diff -= 3; - } - return cur_diff; -} - -static void GetBestGreenToRed( - const uint32_t* argb, int stride, int tile_width, int tile_height, - VP8LMultipliers prev_x, VP8LMultipliers prev_y, int quality, - const int accumulated_red_histo[256], VP8LMultipliers* const best_tx) { - const int kMaxIters = 4 + ((7 * quality) >> 8); // in range [4..6] - int green_to_red_best = 0; - int iter, offset; - float best_diff = GetPredictionCostCrossColorRed( - argb, stride, tile_width, tile_height, prev_x, prev_y, - green_to_red_best, accumulated_red_histo); - for (iter = 0; iter < kMaxIters; ++iter) { - // ColorTransformDelta is a 3.5 bit fixed point, so 32 is equal to - // one in color computation. Having initial delta here as 1 is sufficient - // to explore the range of (-2, 2). - const int delta = 32 >> iter; - // Try a negative and a positive delta from the best known value. - for (offset = -delta; offset <= delta; offset += 2 * delta) { - const int green_to_red_cur = offset + green_to_red_best; - const float cur_diff = GetPredictionCostCrossColorRed( - argb, stride, tile_width, tile_height, prev_x, prev_y, - green_to_red_cur, accumulated_red_histo); - if (cur_diff < best_diff) { - best_diff = cur_diff; - green_to_red_best = green_to_red_cur; - } - } - } - best_tx->green_to_red_ = green_to_red_best; -} - void VP8LCollectColorBlueTransforms_C(const uint32_t* argb, int stride, int tile_width, int tile_height, int green_to_blue, int red_to_blue, @@ -1080,187 +575,6 @@ void VP8LCollectColorBlueTransforms_C(const uint32_t* argb, int stride, } } -static float GetPredictionCostCrossColorBlue( - const uint32_t* argb, int stride, int tile_width, int tile_height, - VP8LMultipliers prev_x, VP8LMultipliers prev_y, - int green_to_blue, int red_to_blue, const int accumulated_blue_histo[256]) { - int histo[256] = { 0 }; - float cur_diff; - - VP8LCollectColorBlueTransforms(argb, stride, tile_width, tile_height, - green_to_blue, red_to_blue, histo); - - cur_diff = PredictionCostCrossColor(accumulated_blue_histo, histo); - if ((uint8_t)green_to_blue == prev_x.green_to_blue_) { - cur_diff -= 3; // favor keeping the areas locally similar - } - if ((uint8_t)green_to_blue == prev_y.green_to_blue_) { - cur_diff -= 3; // favor keeping the areas locally similar - } - if ((uint8_t)red_to_blue == prev_x.red_to_blue_) { - cur_diff -= 3; // favor keeping the areas locally similar - } - if ((uint8_t)red_to_blue == prev_y.red_to_blue_) { - cur_diff -= 3; // favor keeping the areas locally similar - } - if (green_to_blue == 0) { - cur_diff -= 3; - } - if (red_to_blue == 0) { - cur_diff -= 3; - } - return cur_diff; -} - -#define kGreenRedToBlueNumAxis 8 -#define kGreenRedToBlueMaxIters 7 -static void GetBestGreenRedToBlue( - const uint32_t* argb, int stride, int tile_width, int tile_height, - VP8LMultipliers prev_x, VP8LMultipliers prev_y, int quality, - const int accumulated_blue_histo[256], - VP8LMultipliers* const best_tx) { - const int8_t offset[kGreenRedToBlueNumAxis][2] = - {{0, -1}, {0, 1}, {-1, 0}, {1, 0}, {-1, -1}, {-1, 1}, {1, -1}, {1, 1}}; - const int8_t delta_lut[kGreenRedToBlueMaxIters] = { 16, 16, 8, 4, 2, 2, 2 }; - const int iters = - (quality < 25) ? 1 : (quality > 50) ? kGreenRedToBlueMaxIters : 4; - int green_to_blue_best = 0; - int red_to_blue_best = 0; - int iter; - // Initial value at origin: - float best_diff = GetPredictionCostCrossColorBlue( - argb, stride, tile_width, tile_height, prev_x, prev_y, - green_to_blue_best, red_to_blue_best, accumulated_blue_histo); - for (iter = 0; iter < iters; ++iter) { - const int delta = delta_lut[iter]; - int axis; - for (axis = 0; axis < kGreenRedToBlueNumAxis; ++axis) { - const int green_to_blue_cur = - offset[axis][0] * delta + green_to_blue_best; - const int red_to_blue_cur = offset[axis][1] * delta + red_to_blue_best; - const float cur_diff = GetPredictionCostCrossColorBlue( - argb, stride, tile_width, tile_height, prev_x, prev_y, - green_to_blue_cur, red_to_blue_cur, accumulated_blue_histo); - if (cur_diff < best_diff) { - best_diff = cur_diff; - green_to_blue_best = green_to_blue_cur; - red_to_blue_best = red_to_blue_cur; - } - if (quality < 25 && iter == 4) { - // Only axis aligned diffs for lower quality. - break; // next iter. - } - } - if (delta == 2 && green_to_blue_best == 0 && red_to_blue_best == 0) { - // Further iterations would not help. - break; // out of iter-loop. - } - } - best_tx->green_to_blue_ = green_to_blue_best; - best_tx->red_to_blue_ = red_to_blue_best; -} -#undef kGreenRedToBlueMaxIters -#undef kGreenRedToBlueNumAxis - -static VP8LMultipliers GetBestColorTransformForTile( - int tile_x, int tile_y, int bits, - VP8LMultipliers prev_x, - VP8LMultipliers prev_y, - int quality, int xsize, int ysize, - const int accumulated_red_histo[256], - const int accumulated_blue_histo[256], - const uint32_t* const argb) { - const int max_tile_size = 1 << bits; - const int tile_y_offset = tile_y * max_tile_size; - const int tile_x_offset = tile_x * max_tile_size; - const int all_x_max = GetMin(tile_x_offset + max_tile_size, xsize); - const int all_y_max = GetMin(tile_y_offset + max_tile_size, ysize); - const int tile_width = all_x_max - tile_x_offset; - const int tile_height = all_y_max - tile_y_offset; - const uint32_t* const tile_argb = argb + tile_y_offset * xsize - + tile_x_offset; - VP8LMultipliers best_tx; - MultipliersClear(&best_tx); - - GetBestGreenToRed(tile_argb, xsize, tile_width, tile_height, - prev_x, prev_y, quality, accumulated_red_histo, &best_tx); - GetBestGreenRedToBlue(tile_argb, xsize, tile_width, tile_height, - prev_x, prev_y, quality, accumulated_blue_histo, - &best_tx); - return best_tx; -} - -static void CopyTileWithColorTransform(int xsize, int ysize, - int tile_x, int tile_y, - int max_tile_size, - VP8LMultipliers color_transform, - uint32_t* argb) { - const int xscan = GetMin(max_tile_size, xsize - tile_x); - int yscan = GetMin(max_tile_size, ysize - tile_y); - argb += tile_y * xsize + tile_x; - while (yscan-- > 0) { - VP8LTransformColor(&color_transform, argb, xscan); - argb += xsize; - } -} - -void VP8LColorSpaceTransform(int width, int height, int bits, int quality, - uint32_t* const argb, uint32_t* image) { - const int max_tile_size = 1 << bits; - const int tile_xsize = VP8LSubSampleSize(width, bits); - const int tile_ysize = VP8LSubSampleSize(height, bits); - int accumulated_red_histo[256] = { 0 }; - int accumulated_blue_histo[256] = { 0 }; - int tile_x, tile_y; - VP8LMultipliers prev_x, prev_y; - MultipliersClear(&prev_y); - MultipliersClear(&prev_x); - for (tile_y = 0; tile_y < tile_ysize; ++tile_y) { - for (tile_x = 0; tile_x < tile_xsize; ++tile_x) { - int y; - const int tile_x_offset = tile_x * max_tile_size; - const int tile_y_offset = tile_y * max_tile_size; - const int all_x_max = GetMin(tile_x_offset + max_tile_size, width); - const int all_y_max = GetMin(tile_y_offset + max_tile_size, height); - const int offset = tile_y * tile_xsize + tile_x; - if (tile_y != 0) { - ColorCodeToMultipliers(image[offset - tile_xsize], &prev_y); - } - prev_x = GetBestColorTransformForTile(tile_x, tile_y, bits, - prev_x, prev_y, - quality, width, height, - accumulated_red_histo, - accumulated_blue_histo, - argb); - image[offset] = MultipliersToColorCode(&prev_x); - CopyTileWithColorTransform(width, height, tile_x_offset, tile_y_offset, - max_tile_size, prev_x, argb); - - // Gather accumulated histogram data. - for (y = tile_y_offset; y < all_y_max; ++y) { - int ix = y * width + tile_x_offset; - const int ix_end = ix + all_x_max - tile_x_offset; - for (; ix < ix_end; ++ix) { - const uint32_t pix = argb[ix]; - if (ix >= 2 && - pix == argb[ix - 2] && - pix == argb[ix - 1]) { - continue; // repeated pixels are handled by backward references - } - if (ix >= width + 2 && - argb[ix - 2] == argb[ix - width - 2] && - argb[ix - 1] == argb[ix - width - 1] && - pix == argb[ix - width]) { - continue; // repeated pixels are handled by backward references - } - ++accumulated_red_histo[(pix >> 16) & 0xff]; - ++accumulated_blue_histo[(pix >> 0) & 0xff]; - } - } - } - } -} - //------------------------------------------------------------------------------ static int VectorMismatch(const uint32_t* const array1, @@ -1274,8 +588,8 @@ static int VectorMismatch(const uint32_t* const array1, } // Bundles multiple (1, 2, 4 or 8) pixels into a single pixel. -void VP8LBundleColorMap(const uint8_t* const row, int width, - int xbits, uint32_t* const dst) { +void VP8LBundleColorMap_C(const uint8_t* const row, int width, int xbits, + uint32_t* dst) { int x; if (xbits > 0) { const int bit_depth = 1 << (3 - xbits); @@ -1350,8 +664,172 @@ static void HistogramAdd(const VP8LHistogram* const a, } //------------------------------------------------------------------------------ +// Image transforms. -VP8LProcessBlueAndRedFunc VP8LSubtractGreenFromBlueAndRed; +static WEBP_INLINE uint32_t Average2(uint32_t a0, uint32_t a1) { + return (((a0 ^ a1) & 0xfefefefeu) >> 1) + (a0 & a1); +} + +static WEBP_INLINE uint32_t Average3(uint32_t a0, uint32_t a1, uint32_t a2) { + return Average2(Average2(a0, a2), a1); +} + +static WEBP_INLINE uint32_t Average4(uint32_t a0, uint32_t a1, + uint32_t a2, uint32_t a3) { + return Average2(Average2(a0, a1), Average2(a2, a3)); +} + +static WEBP_INLINE uint32_t Clip255(uint32_t a) { + if (a < 256) { + return a; + } + // return 0, when a is a negative integer. + // return 255, when a is positive. + return ~a >> 24; +} + +static WEBP_INLINE int AddSubtractComponentFull(int a, int b, int c) { + return Clip255(a + b - c); +} + +static WEBP_INLINE uint32_t ClampedAddSubtractFull(uint32_t c0, uint32_t c1, + uint32_t c2) { + const int a = AddSubtractComponentFull(c0 >> 24, c1 >> 24, c2 >> 24); + const int r = AddSubtractComponentFull((c0 >> 16) & 0xff, + (c1 >> 16) & 0xff, + (c2 >> 16) & 0xff); + const int g = AddSubtractComponentFull((c0 >> 8) & 0xff, + (c1 >> 8) & 0xff, + (c2 >> 8) & 0xff); + const int b = AddSubtractComponentFull(c0 & 0xff, c1 & 0xff, c2 & 0xff); + return ((uint32_t)a << 24) | (r << 16) | (g << 8) | b; +} + +static WEBP_INLINE int AddSubtractComponentHalf(int a, int b) { + return Clip255(a + (a - b) / 2); +} + +static WEBP_INLINE uint32_t ClampedAddSubtractHalf(uint32_t c0, uint32_t c1, + uint32_t c2) { + const uint32_t ave = Average2(c0, c1); + const int a = AddSubtractComponentHalf(ave >> 24, c2 >> 24); + const int r = AddSubtractComponentHalf((ave >> 16) & 0xff, (c2 >> 16) & 0xff); + const int g = AddSubtractComponentHalf((ave >> 8) & 0xff, (c2 >> 8) & 0xff); + const int b = AddSubtractComponentHalf((ave >> 0) & 0xff, (c2 >> 0) & 0xff); + return ((uint32_t)a << 24) | (r << 16) | (g << 8) | b; +} + +// gcc-4.9 on ARM generates incorrect code in Select() when Sub3() is inlined. +#if defined(__arm__) && \ + (LOCAL_GCC_VERSION == 0x409 || LOCAL_GCC_VERSION == 0x408) +# define LOCAL_INLINE __attribute__ ((noinline)) +#else +# define LOCAL_INLINE WEBP_INLINE +#endif + +static LOCAL_INLINE int Sub3(int a, int b, int c) { + const int pb = b - c; + const int pa = a - c; + return abs(pb) - abs(pa); +} + +#undef LOCAL_INLINE + +static WEBP_INLINE uint32_t Select(uint32_t a, uint32_t b, uint32_t c) { + const int pa_minus_pb = + Sub3((a >> 24) , (b >> 24) , (c >> 24) ) + + Sub3((a >> 16) & 0xff, (b >> 16) & 0xff, (c >> 16) & 0xff) + + Sub3((a >> 8) & 0xff, (b >> 8) & 0xff, (c >> 8) & 0xff) + + Sub3((a ) & 0xff, (b ) & 0xff, (c ) & 0xff); + return (pa_minus_pb <= 0) ? a : b; +} + +//------------------------------------------------------------------------------ +// Predictors + +static uint32_t Predictor2(uint32_t left, const uint32_t* const top) { + (void)left; + return top[0]; +} +static uint32_t Predictor3(uint32_t left, const uint32_t* const top) { + (void)left; + return top[1]; +} +static uint32_t Predictor4(uint32_t left, const uint32_t* const top) { + (void)left; + return top[-1]; +} +static uint32_t Predictor5(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Average3(left, top[0], top[1]); + return pred; +} +static uint32_t Predictor6(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Average2(left, top[-1]); + return pred; +} +static uint32_t Predictor7(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Average2(left, top[0]); + return pred; +} +static uint32_t Predictor8(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Average2(top[-1], top[0]); + (void)left; + return pred; +} +static uint32_t Predictor9(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Average2(top[0], top[1]); + (void)left; + return pred; +} +static uint32_t Predictor10(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Average4(left, top[-1], top[0], top[1]); + return pred; +} +static uint32_t Predictor11(uint32_t left, const uint32_t* const top) { + const uint32_t pred = Select(top[0], left, top[-1]); + return pred; +} +static uint32_t Predictor12(uint32_t left, const uint32_t* const top) { + const uint32_t pred = ClampedAddSubtractFull(left, top[0], top[-1]); + return pred; +} +static uint32_t Predictor13(uint32_t left, const uint32_t* const top) { + const uint32_t pred = ClampedAddSubtractHalf(left, top[0], top[-1]); + return pred; +} + +//------------------------------------------------------------------------------ + +static void PredictorSub0_C(const uint32_t* in, const uint32_t* upper, + int num_pixels, uint32_t* out) { + int i; + for (i = 0; i < num_pixels; ++i) out[i] = VP8LSubPixels(in[i], ARGB_BLACK); + (void)upper; +} + +static void PredictorSub1_C(const uint32_t* in, const uint32_t* upper, + int num_pixels, uint32_t* out) { + int i; + for (i = 0; i < num_pixels; ++i) out[i] = VP8LSubPixels(in[i], in[i - 1]); + (void)upper; +} + +GENERATE_PREDICTOR_SUB(Predictor2, PredictorSub2_C) +GENERATE_PREDICTOR_SUB(Predictor3, PredictorSub3_C) +GENERATE_PREDICTOR_SUB(Predictor4, PredictorSub4_C) +GENERATE_PREDICTOR_SUB(Predictor5, PredictorSub5_C) +GENERATE_PREDICTOR_SUB(Predictor6, PredictorSub6_C) +GENERATE_PREDICTOR_SUB(Predictor7, PredictorSub7_C) +GENERATE_PREDICTOR_SUB(Predictor8, PredictorSub8_C) +GENERATE_PREDICTOR_SUB(Predictor9, PredictorSub9_C) +GENERATE_PREDICTOR_SUB(Predictor10, PredictorSub10_C) +GENERATE_PREDICTOR_SUB(Predictor11, PredictorSub11_C) +GENERATE_PREDICTOR_SUB(Predictor12, PredictorSub12_C) +GENERATE_PREDICTOR_SUB(Predictor13, PredictorSub13_C) + +//------------------------------------------------------------------------------ + +VP8LProcessEncBlueAndRedFunc VP8LSubtractGreenFromBlueAndRed; VP8LTransformColorFunc VP8LTransformColor; @@ -1365,17 +843,23 @@ VP8LCostFunc VP8LExtraCost; VP8LCostCombinedFunc VP8LExtraCostCombined; VP8LCombinedShannonEntropyFunc VP8LCombinedShannonEntropy; -GetEntropyUnrefinedHelperFunc VP8LGetEntropyUnrefinedHelper; +VP8LGetEntropyUnrefinedFunc VP8LGetEntropyUnrefined; +VP8LGetCombinedEntropyUnrefinedFunc VP8LGetCombinedEntropyUnrefined; VP8LHistogramAddFunc VP8LHistogramAdd; VP8LVectorMismatchFunc VP8LVectorMismatch; +VP8LBundleColorMapFunc VP8LBundleColorMap; + +VP8LPredictorAddSubFunc VP8LPredictorsSub[16]; +VP8LPredictorAddSubFunc VP8LPredictorsSub_C[16]; extern void VP8LEncDspInitSSE2(void); extern void VP8LEncDspInitSSE41(void); extern void VP8LEncDspInitNEON(void); extern void VP8LEncDspInitMIPS32(void); extern void VP8LEncDspInitMIPSdspR2(void); +extern void VP8LEncDspInitMSA(void); static volatile VP8CPUInfo lossless_enc_last_cpuinfo_used = (VP8CPUInfo)&lossless_enc_last_cpuinfo_used; @@ -1399,11 +883,47 @@ WEBP_TSAN_IGNORE_FUNCTION void VP8LEncDspInit(void) { VP8LExtraCostCombined = ExtraCostCombined; VP8LCombinedShannonEntropy = CombinedShannonEntropy; - VP8LGetEntropyUnrefinedHelper = GetEntropyUnrefinedHelper; + VP8LGetEntropyUnrefined = GetEntropyUnrefined; + VP8LGetCombinedEntropyUnrefined = GetCombinedEntropyUnrefined; VP8LHistogramAdd = HistogramAdd; VP8LVectorMismatch = VectorMismatch; + VP8LBundleColorMap = VP8LBundleColorMap_C; + + VP8LPredictorsSub[0] = PredictorSub0_C; + VP8LPredictorsSub[1] = PredictorSub1_C; + VP8LPredictorsSub[2] = PredictorSub2_C; + VP8LPredictorsSub[3] = PredictorSub3_C; + VP8LPredictorsSub[4] = PredictorSub4_C; + VP8LPredictorsSub[5] = PredictorSub5_C; + VP8LPredictorsSub[6] = PredictorSub6_C; + VP8LPredictorsSub[7] = PredictorSub7_C; + VP8LPredictorsSub[8] = PredictorSub8_C; + VP8LPredictorsSub[9] = PredictorSub9_C; + VP8LPredictorsSub[10] = PredictorSub10_C; + VP8LPredictorsSub[11] = PredictorSub11_C; + VP8LPredictorsSub[12] = PredictorSub12_C; + VP8LPredictorsSub[13] = PredictorSub13_C; + VP8LPredictorsSub[14] = PredictorSub0_C; // <- padding security sentinels + VP8LPredictorsSub[15] = PredictorSub0_C; + + VP8LPredictorsSub_C[0] = PredictorSub0_C; + VP8LPredictorsSub_C[1] = PredictorSub1_C; + VP8LPredictorsSub_C[2] = PredictorSub2_C; + VP8LPredictorsSub_C[3] = PredictorSub3_C; + VP8LPredictorsSub_C[4] = PredictorSub4_C; + VP8LPredictorsSub_C[5] = PredictorSub5_C; + VP8LPredictorsSub_C[6] = PredictorSub6_C; + VP8LPredictorsSub_C[7] = PredictorSub7_C; + VP8LPredictorsSub_C[8] = PredictorSub8_C; + VP8LPredictorsSub_C[9] = PredictorSub9_C; + VP8LPredictorsSub_C[10] = PredictorSub10_C; + VP8LPredictorsSub_C[11] = PredictorSub11_C; + VP8LPredictorsSub_C[12] = PredictorSub12_C; + VP8LPredictorsSub_C[13] = PredictorSub13_C; + VP8LPredictorsSub_C[14] = PredictorSub0_C; // <- padding security sentinels + VP8LPredictorsSub_C[15] = PredictorSub0_C; // If defined, use CPUInfo() to overwrite some pointers with faster versions. if (VP8GetCPUInfo != NULL) { @@ -1432,6 +952,11 @@ WEBP_TSAN_IGNORE_FUNCTION void VP8LEncDspInit(void) { VP8LEncDspInitMIPSdspR2(); } #endif +#if defined(WEBP_USE_MSA) + if (VP8GetCPUInfo(kMSA)) { + VP8LEncDspInitMSA(); + } +#endif } lossless_enc_last_cpuinfo_used = VP8GetCPUInfo; } |