src/third_party/libwebp/utils/quant_levels.c - cobalt - Git at Google

 // Copyright 2011 Google Inc. All Rights Reserved.
 //
 // Use of this source code is governed by a BSD-style license
 // that can be found in the COPYING file in the root of the source
 // tree. An additional intellectual property rights grant can be found
 // in the file PATENTS. All contributing project authors may
 // be found in the AUTHORS file in the root of the source tree.
 // -----------------------------------------------------------------------------
 //
 // Quantize levels for specified number of quantization-levels ([2, 256]).
 // Min and max values are preserved (usual 0 and 255 for alpha plane).
 //
 // Author: Skal (pascal.massimino@gmail.com)

 #if defined(STARBOARD)
 #include "third_party/libwebp/starboard_private.h"
 #else
 #include <assert.h>
 #endif

 #include "./quant_levels.h"

 #if defined(__cplusplus) || defined(c_plusplus)
 extern "C" {
 #endif

 #define NUM_SYMBOLS     256

 #define MAX_ITER  6             // Maximum number of convergence steps.
 #define ERROR_THRESHOLD 1e-4    // MSE stopping criterion.

 // -----------------------------------------------------------------------------
 // Quantize levels.

 int QuantizeLevels(uint8_t* const data, int width, int height,
                    int num_levels, uint64_t* const sse) {
   int freq[NUM_SYMBOLS] = { 0 };
   int q_level[NUM_SYMBOLS] = { 0 };
   double inv_q_level[NUM_SYMBOLS] = { 0 };
   int min_s = 255, max_s = 0;
   const size_t data_size = height * width;
   int i, num_levels_in, iter;
   double last_err = 1.e38, err = 0.;
   const double err_threshold = ERROR_THRESHOLD * data_size;

   if (data == NULL) {
     return 0;
   }

   if (width <= 0 || height <= 0) {
     return 0;
   }

   if (num_levels < 2 || num_levels > 256) {
     return 0;
   }

   {
     size_t n;
     num_levels_in = 0;
     for (n = 0; n < data_size; ++n) {
       num_levels_in += (freq[data[n]] == 0);
       if (min_s > data[n]) min_s = data[n];
       if (max_s < data[n]) max_s = data[n];
       ++freq[data[n]];
     }
   }

   if (num_levels_in <= num_levels) goto End;  // nothing to do!

   // Start with uniformly spread centroids.
   for (i = 0; i < num_levels; ++i) {
     inv_q_level[i] = min_s + (double)(max_s - min_s) * i / (num_levels - 1);
   }

   // Fixed values. Won't be changed.
   q_level[min_s] = 0;
   q_level[max_s] = num_levels - 1;
   assert(inv_q_level[0] == min_s);
   assert(inv_q_level[num_levels - 1] == max_s);

   // k-Means iterations.
   for (iter = 0; iter < MAX_ITER; ++iter) {
     double q_sum[NUM_SYMBOLS] = { 0 };
     double q_count[NUM_SYMBOLS] = { 0 };
     int s, slot = 0;

     // Assign classes to representatives.
     for (s = min_s; s <= max_s; ++s) {
       // Keep track of the nearest neighbour 'slot'
       while (slot < num_levels - 1 &&
              2 * s > inv_q_level[slot] + inv_q_level[slot + 1]) {
         ++slot;
       }
       if (freq[s] > 0) {
         q_sum[slot] += s * freq[s];
         q_count[slot] += freq[s];
       }
       q_level[s] = slot;
     }

     // Assign new representatives to classes.
     if (num_levels > 2) {
       for (slot = 1; slot < num_levels - 1; ++slot) {
         const double count = q_count[slot];
         if (count > 0.) {
           inv_q_level[slot] = q_sum[slot] / count;
         }
       }
     }

     // Compute convergence error.
     err = 0.;
     for (s = min_s; s <= max_s; ++s) {
       const double error = s - inv_q_level[q_level[s]];
       err += freq[s] * error * error;
     }

     // Check for convergence: we stop as soon as the error is no
     // longer improving.
     if (last_err - err < err_threshold) break;
     last_err = err;
   }

   // Remap the alpha plane to quantized values.
   {
     // double->int rounding operation can be costly, so we do it
     // once for all before remapping. We also perform the data[] -> slot
     // mapping, while at it (avoid one indirection in the final loop).
     uint8_t map[NUM_SYMBOLS];
     int s;
     size_t n;
     for (s = min_s; s <= max_s; ++s) {
       const int slot = q_level[s];
       map[s] = (uint8_t)(inv_q_level[slot] + .5);
     }
     // Final pass.
     for (n = 0; n < data_size; ++n) {
       data[n] = map[data[n]];
     }
   }
  End:
   // Store sum of squared error if needed.
   if (sse != NULL) *sse = (uint64_t)err;

   return 1;
 }

 #if defined(__cplusplus) || defined(c_plusplus)
 }    // extern "C"
 #endif
	// Copyright 2011 Google Inc. All Rights Reserved.
	//
	// Use of this source code is governed by a BSD-style license
	// that can be found in the COPYING file in the root of the source
	// tree. An additional intellectual property rights grant can be found
	// in the file PATENTS. All contributing project authors may
	// be found in the AUTHORS file in the root of the source tree.
	// -----------------------------------------------------------------------------
	//
	// Quantize levels for specified number of quantization-levels ([2, 256]).
	// Min and max values are preserved (usual 0 and 255 for alpha plane).
	//
	// Author: Skal (pascal.massimino@gmail.com)

	#if defined(STARBOARD)
	#include "third_party/libwebp/starboard_private.h"
	#else
	#include <assert.h>
	#endif

	#include "./quant_levels.h"

	#if defined(__cplusplus) \|\| defined(c_plusplus)
	extern "C" {
	#endif

	#define NUM_SYMBOLS 256

	#define MAX_ITER 6 // Maximum number of convergence steps.
	#define ERROR_THRESHOLD 1e-4 // MSE stopping criterion.

	// -----------------------------------------------------------------------------
	// Quantize levels.

	int QuantizeLevels(uint8_t* const data, int width, int height,
	int num_levels, uint64_t* const sse) {
	int freq[NUM_SYMBOLS] = { 0 };
	int q_level[NUM_SYMBOLS] = { 0 };
	double inv_q_level[NUM_SYMBOLS] = { 0 };
	int min_s = 255, max_s = 0;
	const size_t data_size = height * width;
	int i, num_levels_in, iter;
	double last_err = 1.e38, err = 0.;
	const double err_threshold = ERROR_THRESHOLD * data_size;

	if (data == NULL) {
	return 0;
	}

	if (width <= 0 \|\| height <= 0) {
	return 0;
	}

	if (num_levels < 2 \|\| num_levels > 256) {
	return 0;
	}

	{
	size_t n;
	num_levels_in = 0;
	for (n = 0; n < data_size; ++n) {
	num_levels_in += (freq[data[n]] == 0);
	if (min_s > data[n]) min_s = data[n];
	if (max_s < data[n]) max_s = data[n];
	++freq[data[n]];
	}
	}

	if (num_levels_in <= num_levels) goto End; // nothing to do!

	// Start with uniformly spread centroids.
	for (i = 0; i < num_levels; ++i) {
	inv_q_level[i] = min_s + (double)(max_s - min_s) * i / (num_levels - 1);
	}

	// Fixed values. Won't be changed.
	q_level[min_s] = 0;
	q_level[max_s] = num_levels - 1;
	assert(inv_q_level[0] == min_s);
	assert(inv_q_level[num_levels - 1] == max_s);

	// k-Means iterations.
	for (iter = 0; iter < MAX_ITER; ++iter) {
	double q_sum[NUM_SYMBOLS] = { 0 };
	double q_count[NUM_SYMBOLS] = { 0 };
	int s, slot = 0;

	// Assign classes to representatives.
	for (s = min_s; s <= max_s; ++s) {
	// Keep track of the nearest neighbour 'slot'
	while (slot < num_levels - 1 &&
	2 * s > inv_q_level[slot] + inv_q_level[slot + 1]) {
	++slot;
	}
	if (freq[s] > 0) {
	q_sum[slot] += s * freq[s];
	q_count[slot] += freq[s];
	}
	q_level[s] = slot;
	}

	// Assign new representatives to classes.
	if (num_levels > 2) {
	for (slot = 1; slot < num_levels - 1; ++slot) {
	const double count = q_count[slot];
	if (count > 0.) {
	inv_q_level[slot] = q_sum[slot] / count;
	}
	}
	}

	// Compute convergence error.
	err = 0.;
	for (s = min_s; s <= max_s; ++s) {
	const double error = s - inv_q_level[q_level[s]];
	err += freq[s] * error * error;
	}

	// Check for convergence: we stop as soon as the error is no
	// longer improving.
	if (last_err - err < err_threshold) break;
	last_err = err;
	}

	// Remap the alpha plane to quantized values.
	{
	// double->int rounding operation can be costly, so we do it
	// once for all before remapping. We also perform the data[] -> slot
	// mapping, while at it (avoid one indirection in the final loop).
	uint8_t map[NUM_SYMBOLS];
	int s;
	size_t n;
	for (s = min_s; s <= max_s; ++s) {
	const int slot = q_level[s];
	map[s] = (uint8_t)(inv_q_level[slot] + .5);
	}
	// Final pass.
	for (n = 0; n < data_size; ++n) {
	data[n] = map[data[n]];
	}
	}
	End:
	// Store sum of squared error if needed.
	if (sse != NULL) *sse = (uint64_t)err;

	return 1;
	}

	#if defined(__cplusplus) \|\| defined(c_plusplus)
	} // extern "C"
	#endif