src/third_party/libwebp/src/dsp/lossless_enc_mips32.c - cobalt - Git at Google

 // Copyright 2015 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.
 // -----------------------------------------------------------------------------
 //
 // MIPS version of lossless functions
 //
 // Author(s):  Djordje Pesut    (djordje.pesut@imgtec.com)
 //             Jovan Zelincevic (jovan.zelincevic@imgtec.com)

 #include "src/dsp/dsp.h"
 #include "src/dsp/lossless.h"
 #include "src/dsp/lossless_common.h"

 #if defined(WEBP_USE_MIPS32)

 #if defined(STARBOARD)
 #include "starboard/client_porting/poem/assert_poem.h"
 #include "starboard/client_porting/poem/math_poem.h"
 #include "starboard/client_porting/poem/stdlib_poem.h"
 #include "starboard/client_porting/poem/string_poem.h"
 #else
 #include <assert.h>
 #include <math.h>
 #include <stdlib.h>
 #include <string.h>
 #endif

 static float FastSLog2Slow_MIPS32(uint32_t v) {
   assert(v >= LOG_LOOKUP_IDX_MAX);
   if (v < APPROX_LOG_WITH_CORRECTION_MAX) {
     uint32_t log_cnt, y, correction;
     const int c24 = 24;
     const float v_f = (float)v;
     uint32_t temp;

     // Xf = 256 = 2^8
     // log_cnt is index of leading one in upper 24 bits
     __asm__ volatile(
       "clz      %[log_cnt], %[v]                      \n\t"
       "addiu    %[y],       $zero,        1           \n\t"
       "subu     %[log_cnt], %[c24],       %[log_cnt]  \n\t"
       "sllv     %[y],       %[y],         %[log_cnt]  \n\t"
       "srlv     %[temp],    %[v],         %[log_cnt]  \n\t"
       : [log_cnt]"=&r"(log_cnt), [y]"=&r"(y),
         [temp]"=r"(temp)
       : [c24]"r"(c24), [v]"r"(v)
     );

     // vf = (2^log_cnt) * Xf; where y = 2^log_cnt and Xf < 256
     // Xf = floor(Xf) * (1 + (v % y) / v)
     // log2(Xf) = log2(floor(Xf)) + log2(1 + (v % y) / v)
     // The correction factor: log(1 + d) ~ d; for very small d values, so
     // log2(1 + (v % y) / v) ~ LOG_2_RECIPROCAL * (v % y)/v
     // LOG_2_RECIPROCAL ~ 23/16

     // (v % y) = (v % 2^log_cnt) = v & (2^log_cnt - 1)
     correction = (23 * (v & (y - 1))) >> 4;
     return v_f * (kLog2Table[temp] + log_cnt) + correction;
   } else {
     return (float)(LOG_2_RECIPROCAL * v * log((double)v));
   }
 }

 static float FastLog2Slow_MIPS32(uint32_t v) {
   assert(v >= LOG_LOOKUP_IDX_MAX);
   if (v < APPROX_LOG_WITH_CORRECTION_MAX) {
     uint32_t log_cnt, y;
     const int c24 = 24;
     double log_2;
     uint32_t temp;

     __asm__ volatile(
       "clz      %[log_cnt], %[v]                      \n\t"
       "addiu    %[y],       $zero,        1           \n\t"
       "subu     %[log_cnt], %[c24],       %[log_cnt]  \n\t"
       "sllv     %[y],       %[y],         %[log_cnt]  \n\t"
       "srlv     %[temp],    %[v],         %[log_cnt]  \n\t"
       : [log_cnt]"=&r"(log_cnt), [y]"=&r"(y),
         [temp]"=r"(temp)
       : [c24]"r"(c24), [v]"r"(v)
     );

     log_2 = kLog2Table[temp] + log_cnt;
     if (v >= APPROX_LOG_MAX) {
       // Since the division is still expensive, add this correction factor only
       // for large values of 'v'.

       const uint32_t correction = (23 * (v & (y - 1))) >> 4;
       log_2 += (double)correction / v;
     }
     return (float)log_2;
   } else {
     return (float)(LOG_2_RECIPROCAL * log((double)v));
   }
 }

 // C version of this function:
 //   int i = 0;
 //   int64_t cost = 0;
 //   const uint32_t* pop = &population[4];
 //   const uint32_t* LoopEnd = &population[length];
 //   while (pop != LoopEnd) {
 //     ++i;
 //     cost += i * *pop;
 //     cost += i * *(pop + 1);
 //     pop += 2;
 //   }
 //   return (double)cost;
 static double ExtraCost_MIPS32(const uint32_t* const population, int length) {
   int i, temp0, temp1;
   const uint32_t* pop = &population[4];
   const uint32_t* const LoopEnd = &population[length];

   __asm__ volatile(
     "mult   $zero,    $zero                  \n\t"
     "xor    %[i],     %[i],       %[i]       \n\t"
     "beq    %[pop],   %[LoopEnd], 2f         \n\t"
   "1:                                        \n\t"
     "lw     %[temp0], 0(%[pop])              \n\t"
     "lw     %[temp1], 4(%[pop])              \n\t"
     "addiu  %[i],     %[i],       1          \n\t"
     "addiu  %[pop],   %[pop],     8          \n\t"
     "madd   %[i],     %[temp0]               \n\t"
     "madd   %[i],     %[temp1]               \n\t"
     "bne    %[pop],   %[LoopEnd], 1b         \n\t"
   "2:                                        \n\t"
     "mfhi   %[temp0]                         \n\t"
     "mflo   %[temp1]                         \n\t"
     : [temp0]"=&r"(temp0), [temp1]"=&r"(temp1),
       [i]"=&r"(i), [pop]"+r"(pop)
     : [LoopEnd]"r"(LoopEnd)
     : "memory", "hi", "lo"
   );

   return (double)((int64_t)temp0 << 32 | temp1);
 }

 // C version of this function:
 //   int i = 0;
 //   int64_t cost = 0;
 //   const uint32_t* pX = &X[4];
 //   const uint32_t* pY = &Y[4];
 //   const uint32_t* LoopEnd = &X[length];
 //   while (pX != LoopEnd) {
 //     const uint32_t xy0 = *pX + *pY;
 //     const uint32_t xy1 = *(pX + 1) + *(pY + 1);
 //     ++i;
 //     cost += i * xy0;
 //     cost += i * xy1;
 //     pX += 2;
 //     pY += 2;
 //   }
 //   return (double)cost;
 static double ExtraCostCombined_MIPS32(const uint32_t* const X,
                                        const uint32_t* const Y, int length) {
   int i, temp0, temp1, temp2, temp3;
   const uint32_t* pX = &X[4];
   const uint32_t* pY = &Y[4];
   const uint32_t* const LoopEnd = &X[length];

   __asm__ volatile(
     "mult   $zero,    $zero                  \n\t"
     "xor    %[i],     %[i],       %[i]       \n\t"
     "beq    %[pX],    %[LoopEnd], 2f         \n\t"
   "1:                                        \n\t"
     "lw     %[temp0], 0(%[pX])               \n\t"
     "lw     %[temp1], 0(%[pY])               \n\t"
     "lw     %[temp2], 4(%[pX])               \n\t"
     "lw     %[temp3], 4(%[pY])               \n\t"
     "addiu  %[i],     %[i],       1          \n\t"
     "addu   %[temp0], %[temp0],   %[temp1]   \n\t"
     "addu   %[temp2], %[temp2],   %[temp3]   \n\t"
     "addiu  %[pX],    %[pX],      8          \n\t"
     "addiu  %[pY],    %[pY],      8          \n\t"
     "madd   %[i],     %[temp0]               \n\t"
     "madd   %[i],     %[temp2]               \n\t"
     "bne    %[pX],    %[LoopEnd], 1b         \n\t"
   "2:                                        \n\t"
     "mfhi   %[temp0]                         \n\t"
     "mflo   %[temp1]                         \n\t"
     : [temp0]"=&r"(temp0), [temp1]"=&r"(temp1),
       [temp2]"=&r"(temp2), [temp3]"=&r"(temp3),
       [i]"=&r"(i), [pX]"+r"(pX), [pY]"+r"(pY)
     : [LoopEnd]"r"(LoopEnd)
     : "memory", "hi", "lo"
   );

   return (double)((int64_t)temp0 << 32 | temp1);
 }

 #define HUFFMAN_COST_PASS                                 \
   __asm__ volatile(                                       \
     "sll   %[temp1],  %[temp0],    3           \n\t"      \
     "addiu %[temp3],  %[streak],   -3          \n\t"      \
     "addu  %[temp2],  %[pstreaks], %[temp1]    \n\t"      \
     "blez  %[temp3],  1f                       \n\t"      \
     "srl   %[temp1],  %[temp1],    1           \n\t"      \
     "addu  %[temp3],  %[pcnts],    %[temp1]    \n\t"      \
     "lw    %[temp0],  4(%[temp2])              \n\t"      \
     "lw    %[temp1],  0(%[temp3])              \n\t"      \
     "addu  %[temp0],  %[temp0],    %[streak]   \n\t"      \
     "addiu %[temp1],  %[temp1],    1           \n\t"      \
     "sw    %[temp0],  4(%[temp2])              \n\t"      \
     "sw    %[temp1],  0(%[temp3])              \n\t"      \
     "b     2f                                  \n\t"      \
   "1:                                          \n\t"      \
     "lw    %[temp0],  0(%[temp2])              \n\t"      \
     "addu  %[temp0],  %[temp0],    %[streak]   \n\t"      \
     "sw    %[temp0],  0(%[temp2])              \n\t"      \
   "2:                                          \n\t"      \
     : [temp1]"=&r"(temp1), [temp2]"=&r"(temp2),           \
       [temp3]"=&r"(temp3), [temp0]"+r"(temp0)             \
     : [pstreaks]"r"(pstreaks), [pcnts]"r"(pcnts),         \
       [streak]"r"(streak)                                 \
     : "memory"                                            \
   );

 // Returns the various RLE counts
 static WEBP_INLINE void GetEntropyUnrefinedHelper(
     uint32_t val, int i, uint32_t* const val_prev, int* const i_prev,
     VP8LBitEntropy* const bit_entropy, VP8LStreaks* const stats) {
   int* const pstreaks = &stats->streaks[0][0];
   int* const pcnts = &stats->counts[0];
   int temp0, temp1, temp2, temp3;
   const int streak = i - *i_prev;

   // Gather info for the bit entropy.
   if (*val_prev != 0) {
     bit_entropy->sum += (*val_prev) * streak;
     bit_entropy->nonzeros += streak;
     bit_entropy->nonzero_code = *i_prev;
     bit_entropy->entropy -= VP8LFastSLog2(*val_prev) * streak;
     if (bit_entropy->max_val < *val_prev) {
       bit_entropy->max_val = *val_prev;
     }
   }

   // Gather info for the Huffman cost.
   temp0 = (*val_prev != 0);
   HUFFMAN_COST_PASS

   *val_prev = val;
   *i_prev = i;
 }

 static void GetEntropyUnrefined_MIPS32(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];

   memset(stats, 0, sizeof(*stats));
   VP8LBitEntropyInit(bit_entropy);

   for (i = 1; i < length; ++i) {
     const uint32_t x = X[i];
     if (x != x_prev) {
       GetEntropyUnrefinedHelper(x, 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);
 }

 static void GetCombinedEntropyUnrefined_MIPS32(const uint32_t X[],
                                                const uint32_t Y[],
                                                int length,
                                                VP8LBitEntropy* const entropy,
                                                VP8LStreaks* const stats) {
   int i = 1;
   int i_prev = 0;
   uint32_t xy_prev = X[0] + Y[0];

   memset(stats, 0, sizeof(*stats));
   VP8LBitEntropyInit(entropy);

   for (i = 1; i < length; ++i) {
     const uint32_t xy = X[i] + Y[i];
     if (xy != xy_prev) {
       GetEntropyUnrefinedHelper(xy, i, &xy_prev, &i_prev, entropy, stats);
     }
   }
   GetEntropyUnrefinedHelper(0, i, &xy_prev, &i_prev, entropy, stats);

   entropy->entropy += VP8LFastSLog2(entropy->sum);
 }

 #define ASM_START                                       \
   __asm__ volatile(                                     \
     ".set   push                            \n\t"       \
     ".set   at                              \n\t"       \
     ".set   macro                           \n\t"       \
   "1:                                       \n\t"

 // P2 = P0 + P1
 // A..D - offsets
 // E - temp variable to tell macro
 //     if pointer should be incremented
 // literal_ and successive histograms could be unaligned
 // so we must use ulw and usw
 #define ADD_TO_OUT(A, B, C, D, E, P0, P1, P2)           \
     "ulw    %[temp0], " #A "(%[" #P0 "])    \n\t"       \
     "ulw    %[temp1], " #B "(%[" #P0 "])    \n\t"       \
     "ulw    %[temp2], " #C "(%[" #P0 "])    \n\t"       \
     "ulw    %[temp3], " #D "(%[" #P0 "])    \n\t"       \
     "ulw    %[temp4], " #A "(%[" #P1 "])    \n\t"       \
     "ulw    %[temp5], " #B "(%[" #P1 "])    \n\t"       \
     "ulw    %[temp6], " #C "(%[" #P1 "])    \n\t"       \
     "ulw    %[temp7], " #D "(%[" #P1 "])    \n\t"       \
     "addu   %[temp4], %[temp4],   %[temp0]  \n\t"       \
     "addu   %[temp5], %[temp5],   %[temp1]  \n\t"       \
     "addu   %[temp6], %[temp6],   %[temp2]  \n\t"       \
     "addu   %[temp7], %[temp7],   %[temp3]  \n\t"       \
     "addiu  %[" #P0 "],  %[" #P0 "],  16    \n\t"       \
   ".if " #E " == 1                          \n\t"       \
     "addiu  %[" #P1 "],  %[" #P1 "],  16    \n\t"       \
   ".endif                                   \n\t"       \
     "usw    %[temp4], " #A "(%[" #P2 "])    \n\t"       \
     "usw    %[temp5], " #B "(%[" #P2 "])    \n\t"       \
     "usw    %[temp6], " #C "(%[" #P2 "])    \n\t"       \
     "usw    %[temp7], " #D "(%[" #P2 "])    \n\t"       \
     "addiu  %[" #P2 "], %[" #P2 "],   16    \n\t"       \
     "bne    %[" #P0 "], %[LoopEnd], 1b      \n\t"       \
     ".set   pop                             \n\t"       \

 #define ASM_END_COMMON_0                                \
     : [temp0]"=&r"(temp0), [temp1]"=&r"(temp1),         \
       [temp2]"=&r"(temp2), [temp3]"=&r"(temp3),         \
       [temp4]"=&r"(temp4), [temp5]"=&r"(temp5),         \
       [temp6]"=&r"(temp6), [temp7]"=&r"(temp7),         \
       [pa]"+r"(pa), [pout]"+r"(pout)

 #define ASM_END_COMMON_1                                \
     : [LoopEnd]"r"(LoopEnd)                             \
     : "memory", "at"                                    \
   );

 #define ASM_END_0                                       \
     ASM_END_COMMON_0                                    \
       , [pb]"+r"(pb)                                    \
     ASM_END_COMMON_1

 #define ASM_END_1                                       \
     ASM_END_COMMON_0                                    \
     ASM_END_COMMON_1

 #define ADD_VECTOR(A, B, OUT, SIZE, EXTRA_SIZE)  do {   \
   const uint32_t* pa = (const uint32_t*)(A);            \
   const uint32_t* pb = (const uint32_t*)(B);            \
   uint32_t* pout = (uint32_t*)(OUT);                    \
   const uint32_t* const LoopEnd = pa + (SIZE);          \
   assert((SIZE) % 4 == 0);                              \
   ASM_START                                             \
   ADD_TO_OUT(0, 4, 8, 12, 1, pa, pb, pout)              \
   ASM_END_0                                             \
   if ((EXTRA_SIZE) > 0) {                               \
     const int last = (EXTRA_SIZE);                      \
     int i;                                              \
     for (i = 0; i < last; ++i) pout[i] = pa[i] + pb[i]; \
   }                                                     \
 } while (0)

 #define ADD_VECTOR_EQ(A, OUT, SIZE, EXTRA_SIZE)  do {   \
   const uint32_t* pa = (const uint32_t*)(A);            \
   uint32_t* pout = (uint32_t*)(OUT);                    \
   const uint32_t* const LoopEnd = pa + (SIZE);          \
   assert((SIZE) % 4 == 0);                              \
   ASM_START                                             \
   ADD_TO_OUT(0, 4, 8, 12, 0, pa, pout, pout)            \
   ASM_END_1                                             \
   if ((EXTRA_SIZE) > 0) {                               \
     const int last = (EXTRA_SIZE);                      \
     int i;                                              \
     for (i = 0; i < last; ++i) pout[i] += pa[i];        \
   }                                                     \
 } while (0)

 static void HistogramAdd_MIPS32(const VP8LHistogram* const a,
                                 const VP8LHistogram* const b,
                                 VP8LHistogram* const out) {
   uint32_t temp0, temp1, temp2, temp3, temp4, temp5, temp6, temp7;
   const int extra_cache_size = VP8LHistogramNumCodes(a->palette_code_bits_)
                              - (NUM_LITERAL_CODES + NUM_LENGTH_CODES);
   assert(a->palette_code_bits_ == b->palette_code_bits_);

   if (b != out) {
     ADD_VECTOR(a->literal_, b->literal_, out->literal_,
                NUM_LITERAL_CODES + NUM_LENGTH_CODES, extra_cache_size);
     ADD_VECTOR(a->distance_, b->distance_, out->distance_,
                NUM_DISTANCE_CODES, 0);
     ADD_VECTOR(a->red_, b->red_, out->red_, NUM_LITERAL_CODES, 0);
     ADD_VECTOR(a->blue_, b->blue_, out->blue_, NUM_LITERAL_CODES, 0);
     ADD_VECTOR(a->alpha_, b->alpha_, out->alpha_, NUM_LITERAL_CODES, 0);
   } else {
     ADD_VECTOR_EQ(a->literal_, out->literal_,
                   NUM_LITERAL_CODES + NUM_LENGTH_CODES, extra_cache_size);
     ADD_VECTOR_EQ(a->distance_, out->distance_, NUM_DISTANCE_CODES, 0);
     ADD_VECTOR_EQ(a->red_, out->red_, NUM_LITERAL_CODES, 0);
     ADD_VECTOR_EQ(a->blue_, out->blue_, NUM_LITERAL_CODES, 0);
     ADD_VECTOR_EQ(a->alpha_, out->alpha_, NUM_LITERAL_CODES, 0);
   }
 }

 #undef ADD_VECTOR_EQ
 #undef ADD_VECTOR
 #undef ASM_END_1
 #undef ASM_END_0
 #undef ASM_END_COMMON_1
 #undef ASM_END_COMMON_0
 #undef ADD_TO_OUT
 #undef ASM_START

 //------------------------------------------------------------------------------
 // Entry point

 extern void VP8LEncDspInitMIPS32(void);

 WEBP_TSAN_IGNORE_FUNCTION void VP8LEncDspInitMIPS32(void) {
   VP8LFastSLog2Slow = FastSLog2Slow_MIPS32;
   VP8LFastLog2Slow = FastLog2Slow_MIPS32;
   VP8LExtraCost = ExtraCost_MIPS32;
   VP8LExtraCostCombined = ExtraCostCombined_MIPS32;
   VP8LGetEntropyUnrefined = GetEntropyUnrefined_MIPS32;
   VP8LGetCombinedEntropyUnrefined = GetCombinedEntropyUnrefined_MIPS32;
   VP8LHistogramAdd = HistogramAdd_MIPS32;
 }

 #else  // !WEBP_USE_MIPS32

 WEBP_DSP_INIT_STUB(VP8LEncDspInitMIPS32)

 #endif  // WEBP_USE_MIPS32
	// Copyright 2015 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.
	// -----------------------------------------------------------------------------
	//
	// MIPS version of lossless functions
	//
	// Author(s): Djordje Pesut (djordje.pesut@imgtec.com)
	// Jovan Zelincevic (jovan.zelincevic@imgtec.com)

	#include "src/dsp/dsp.h"
	#include "src/dsp/lossless.h"
	#include "src/dsp/lossless_common.h"

	#if defined(WEBP_USE_MIPS32)

	#if defined(STARBOARD)
	#include "starboard/client_porting/poem/assert_poem.h"
	#include "starboard/client_porting/poem/math_poem.h"
	#include "starboard/client_porting/poem/stdlib_poem.h"
	#include "starboard/client_porting/poem/string_poem.h"
	#else
	#include <assert.h>
	#include <math.h>
	#include <stdlib.h>
	#include <string.h>
	#endif

	static float FastSLog2Slow_MIPS32(uint32_t v) {
	assert(v >= LOG_LOOKUP_IDX_MAX);
	if (v < APPROX_LOG_WITH_CORRECTION_MAX) {
	uint32_t log_cnt, y, correction;
	const int c24 = 24;
	const float v_f = (float)v;
	uint32_t temp;

	// Xf = 256 = 2^8
	// log_cnt is index of leading one in upper 24 bits
	__asm__ volatile(
	"clz %[log_cnt], %[v] \n\t"
	"addiu %[y], $zero, 1 \n\t"
	"subu %[log_cnt], %[c24], %[log_cnt] \n\t"
	"sllv %[y], %[y], %[log_cnt] \n\t"
	"srlv %[temp], %[v], %[log_cnt] \n\t"
	: [log_cnt]"=&r"(log_cnt), [y]"=&r"(y),
	[temp]"=r"(temp)
	: [c24]"r"(c24), [v]"r"(v)
	);

	// vf = (2^log_cnt) * Xf; where y = 2^log_cnt and Xf < 256
	// Xf = floor(Xf) * (1 + (v % y) / v)
	// log2(Xf) = log2(floor(Xf)) + log2(1 + (v % y) / v)
	// The correction factor: log(1 + d) ~ d; for very small d values, so
	// log2(1 + (v % y) / v) ~ LOG_2_RECIPROCAL * (v % y)/v
	// LOG_2_RECIPROCAL ~ 23/16

	// (v % y) = (v % 2^log_cnt) = v & (2^log_cnt - 1)
	correction = (23 * (v & (y - 1))) >> 4;
	return v_f * (kLog2Table[temp] + log_cnt) + correction;
	} else {
	return (float)(LOG_2_RECIPROCAL * v * log((double)v));
	}
	}

	static float FastLog2Slow_MIPS32(uint32_t v) {
	assert(v >= LOG_LOOKUP_IDX_MAX);
	if (v < APPROX_LOG_WITH_CORRECTION_MAX) {
	uint32_t log_cnt, y;
	const int c24 = 24;
	double log_2;
	uint32_t temp;

	__asm__ volatile(
	"clz %[log_cnt], %[v] \n\t"
	"addiu %[y], $zero, 1 \n\t"
	"subu %[log_cnt], %[c24], %[log_cnt] \n\t"
	"sllv %[y], %[y], %[log_cnt] \n\t"
	"srlv %[temp], %[v], %[log_cnt] \n\t"
	: [log_cnt]"=&r"(log_cnt), [y]"=&r"(y),
	[temp]"=r"(temp)
	: [c24]"r"(c24), [v]"r"(v)
	);

	log_2 = kLog2Table[temp] + log_cnt;
	if (v >= APPROX_LOG_MAX) {
	// Since the division is still expensive, add this correction factor only
	// for large values of 'v'.

	const uint32_t correction = (23 * (v & (y - 1))) >> 4;
	log_2 += (double)correction / v;
	}
	return (float)log_2;
	} else {
	return (float)(LOG_2_RECIPROCAL * log((double)v));
	}
	}

	// C version of this function:
	// int i = 0;
	// int64_t cost = 0;
	// const uint32_t* pop = &population[4];
	// const uint32_t* LoopEnd = &population[length];
	// while (pop != LoopEnd) {
	// ++i;
	// cost += i * *pop;
	// cost += i * *(pop + 1);
	// pop += 2;
	// }
	// return (double)cost;
	static double ExtraCost_MIPS32(const uint32_t* const population, int length) {
	int i, temp0, temp1;
	const uint32_t* pop = &population[4];
	const uint32_t* const LoopEnd = &population[length];

	__asm__ volatile(
	"mult $zero, $zero \n\t"
	"xor %[i], %[i], %[i] \n\t"
	"beq %[pop], %[LoopEnd], 2f \n\t"
	"1: \n\t"
	"lw %[temp0], 0(%[pop]) \n\t"
	"lw %[temp1], 4(%[pop]) \n\t"
	"addiu %[i], %[i], 1 \n\t"
	"addiu %[pop], %[pop], 8 \n\t"
	"madd %[i], %[temp0] \n\t"
	"madd %[i], %[temp1] \n\t"
	"bne %[pop], %[LoopEnd], 1b \n\t"
	"2: \n\t"
	"mfhi %[temp0] \n\t"
	"mflo %[temp1] \n\t"
	: [temp0]"=&r"(temp0), [temp1]"=&r"(temp1),
	[i]"=&r"(i), [pop]"+r"(pop)
	: [LoopEnd]"r"(LoopEnd)
	: "memory", "hi", "lo"
	);

	return (double)((int64_t)temp0 << 32 \| temp1);
	}

	// C version of this function:
	// int i = 0;
	// int64_t cost = 0;
	// const uint32_t* pX = &X[4];
	// const uint32_t* pY = &Y[4];
	// const uint32_t* LoopEnd = &X[length];
	// while (pX != LoopEnd) {
	// const uint32_t xy0 = pX + pY;
	// const uint32_t xy1 = (pX + 1) + (pY + 1);
	// ++i;
	// cost += i * xy0;
	// cost += i * xy1;
	// pX += 2;
	// pY += 2;
	// }
	// return (double)cost;
	static double ExtraCostCombined_MIPS32(const uint32_t* const X,
	const uint32_t* const Y, int length) {
	int i, temp0, temp1, temp2, temp3;
	const uint32_t* pX = &X[4];
	const uint32_t* pY = &Y[4];
	const uint32_t* const LoopEnd = &X[length];

	__asm__ volatile(
	"mult $zero, $zero \n\t"
	"xor %[i], %[i], %[i] \n\t"
	"beq %[pX], %[LoopEnd], 2f \n\t"
	"1: \n\t"
	"lw %[temp0], 0(%[pX]) \n\t"
	"lw %[temp1], 0(%[pY]) \n\t"
	"lw %[temp2], 4(%[pX]) \n\t"
	"lw %[temp3], 4(%[pY]) \n\t"
	"addiu %[i], %[i], 1 \n\t"
	"addu %[temp0], %[temp0], %[temp1] \n\t"
	"addu %[temp2], %[temp2], %[temp3] \n\t"
	"addiu %[pX], %[pX], 8 \n\t"
	"addiu %[pY], %[pY], 8 \n\t"
	"madd %[i], %[temp0] \n\t"
	"madd %[i], %[temp2] \n\t"
	"bne %[pX], %[LoopEnd], 1b \n\t"
	"2: \n\t"
	"mfhi %[temp0] \n\t"
	"mflo %[temp1] \n\t"
	: [temp0]"=&r"(temp0), [temp1]"=&r"(temp1),
	[temp2]"=&r"(temp2), [temp3]"=&r"(temp3),
	[i]"=&r"(i), [pX]"+r"(pX), [pY]"+r"(pY)
	: [LoopEnd]"r"(LoopEnd)
	: "memory", "hi", "lo"
	);

	return (double)((int64_t)temp0 << 32 \| temp1);
	}

	#define HUFFMAN_COST_PASS \
	__asm__ volatile( \
	"sll %[temp1], %[temp0], 3 \n\t" \
	"addiu %[temp3], %[streak], -3 \n\t" \
	"addu %[temp2], %[pstreaks], %[temp1] \n\t" \
	"blez %[temp3], 1f \n\t" \
	"srl %[temp1], %[temp1], 1 \n\t" \
	"addu %[temp3], %[pcnts], %[temp1] \n\t" \
	"lw %[temp0], 4(%[temp2]) \n\t" \
	"lw %[temp1], 0(%[temp3]) \n\t" \
	"addu %[temp0], %[temp0], %[streak] \n\t" \
	"addiu %[temp1], %[temp1], 1 \n\t" \
	"sw %[temp0], 4(%[temp2]) \n\t" \
	"sw %[temp1], 0(%[temp3]) \n\t" \
	"b 2f \n\t" \
	"1: \n\t" \
	"lw %[temp0], 0(%[temp2]) \n\t" \
	"addu %[temp0], %[temp0], %[streak] \n\t" \
	"sw %[temp0], 0(%[temp2]) \n\t" \
	"2: \n\t" \
	: [temp1]"=&r"(temp1), [temp2]"=&r"(temp2), \
	[temp3]"=&r"(temp3), [temp0]"+r"(temp0) \
	: [pstreaks]"r"(pstreaks), [pcnts]"r"(pcnts), \
	[streak]"r"(streak) \
	: "memory" \
	);

	// Returns the various RLE counts
	static WEBP_INLINE void GetEntropyUnrefinedHelper(
	uint32_t val, int i, uint32_t* const val_prev, int* const i_prev,
	VP8LBitEntropy* const bit_entropy, VP8LStreaks* const stats) {
	int* const pstreaks = &stats->streaks[0][0];
	int* const pcnts = &stats->counts[0];
	int temp0, temp1, temp2, temp3;
	const int streak = i - *i_prev;

	// Gather info for the bit entropy.
	if (*val_prev != 0) {
	bit_entropy->sum += (val_prev) streak;
	bit_entropy->nonzeros += streak;
	bit_entropy->nonzero_code = *i_prev;
	bit_entropy->entropy -= VP8LFastSLog2(val_prev) streak;
	if (bit_entropy->max_val < *val_prev) {
	bit_entropy->max_val = *val_prev;
	}
	}

	// Gather info for the Huffman cost.
	temp0 = (*val_prev != 0);
	HUFFMAN_COST_PASS

	*val_prev = val;
	*i_prev = i;
	}

	static void GetEntropyUnrefined_MIPS32(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];

	memset(stats, 0, sizeof(*stats));
	VP8LBitEntropyInit(bit_entropy);

	for (i = 1; i < length; ++i) {
	const uint32_t x = X[i];
	if (x != x_prev) {
	GetEntropyUnrefinedHelper(x, 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);
	}

	static void GetCombinedEntropyUnrefined_MIPS32(const uint32_t X[],
	const uint32_t Y[],
	int length,
	VP8LBitEntropy* const entropy,
	VP8LStreaks* const stats) {
	int i = 1;
	int i_prev = 0;
	uint32_t xy_prev = X[0] + Y[0];

	memset(stats, 0, sizeof(*stats));
	VP8LBitEntropyInit(entropy);

	for (i = 1; i < length; ++i) {
	const uint32_t xy = X[i] + Y[i];
	if (xy != xy_prev) {
	GetEntropyUnrefinedHelper(xy, i, &xy_prev, &i_prev, entropy, stats);
	}
	}
	GetEntropyUnrefinedHelper(0, i, &xy_prev, &i_prev, entropy, stats);

	entropy->entropy += VP8LFastSLog2(entropy->sum);
	}

	#define ASM_START \
	__asm__ volatile( \
	".set push \n\t" \
	".set at \n\t" \
	".set macro \n\t" \
	"1: \n\t"

	// P2 = P0 + P1
	// A..D - offsets
	// E - temp variable to tell macro
	// if pointer should be incremented
	// literal_ and successive histograms could be unaligned
	// so we must use ulw and usw
	#define ADD_TO_OUT(A, B, C, D, E, P0, P1, P2) \
	"ulw %[temp0], " #A "(%[" #P0 "]) \n\t" \
	"ulw %[temp1], " #B "(%[" #P0 "]) \n\t" \
	"ulw %[temp2], " #C "(%[" #P0 "]) \n\t" \
	"ulw %[temp3], " #D "(%[" #P0 "]) \n\t" \
	"ulw %[temp4], " #A "(%[" #P1 "]) \n\t" \
	"ulw %[temp5], " #B "(%[" #P1 "]) \n\t" \
	"ulw %[temp6], " #C "(%[" #P1 "]) \n\t" \
	"ulw %[temp7], " #D "(%[" #P1 "]) \n\t" \
	"addu %[temp4], %[temp4], %[temp0] \n\t" \
	"addu %[temp5], %[temp5], %[temp1] \n\t" \
	"addu %[temp6], %[temp6], %[temp2] \n\t" \
	"addu %[temp7], %[temp7], %[temp3] \n\t" \
	"addiu %[" #P0 "], %[" #P0 "], 16 \n\t" \
	".if " #E " == 1 \n\t" \
	"addiu %[" #P1 "], %[" #P1 "], 16 \n\t" \
	".endif \n\t" \
	"usw %[temp4], " #A "(%[" #P2 "]) \n\t" \
	"usw %[temp5], " #B "(%[" #P2 "]) \n\t" \
	"usw %[temp6], " #C "(%[" #P2 "]) \n\t" \
	"usw %[temp7], " #D "(%[" #P2 "]) \n\t" \
	"addiu %[" #P2 "], %[" #P2 "], 16 \n\t" \
	"bne %[" #P0 "], %[LoopEnd], 1b \n\t" \
	".set pop \n\t" \

	#define ASM_END_COMMON_0 \
	: [temp0]"=&r"(temp0), [temp1]"=&r"(temp1), \
	[temp2]"=&r"(temp2), [temp3]"=&r"(temp3), \
	[temp4]"=&r"(temp4), [temp5]"=&r"(temp5), \
	[temp6]"=&r"(temp6), [temp7]"=&r"(temp7), \
	[pa]"+r"(pa), [pout]"+r"(pout)

	#define ASM_END_COMMON_1 \
	: [LoopEnd]"r"(LoopEnd) \
	: "memory", "at" \
	);

	#define ASM_END_0 \
	ASM_END_COMMON_0 \
	, [pb]"+r"(pb) \
	ASM_END_COMMON_1

	#define ASM_END_1 \
	ASM_END_COMMON_0 \
	ASM_END_COMMON_1

	#define ADD_VECTOR(A, B, OUT, SIZE, EXTRA_SIZE) do { \
	const uint32_t* pa = (const uint32_t*)(A); \
	const uint32_t* pb = (const uint32_t*)(B); \
	uint32_t* pout = (uint32_t*)(OUT); \
	const uint32_t* const LoopEnd = pa + (SIZE); \
	assert((SIZE) % 4 == 0); \
	ASM_START \
	ADD_TO_OUT(0, 4, 8, 12, 1, pa, pb, pout) \
	ASM_END_0 \
	if ((EXTRA_SIZE) > 0) { \
	const int last = (EXTRA_SIZE); \
	int i; \
	for (i = 0; i < last; ++i) pout[i] = pa[i] + pb[i]; \
	} \
	} while (0)

	#define ADD_VECTOR_EQ(A, OUT, SIZE, EXTRA_SIZE) do { \
	const uint32_t* pa = (const uint32_t*)(A); \
	uint32_t* pout = (uint32_t*)(OUT); \
	const uint32_t* const LoopEnd = pa + (SIZE); \
	assert((SIZE) % 4 == 0); \
	ASM_START \
	ADD_TO_OUT(0, 4, 8, 12, 0, pa, pout, pout) \
	ASM_END_1 \
	if ((EXTRA_SIZE) > 0) { \
	const int last = (EXTRA_SIZE); \
	int i; \
	for (i = 0; i < last; ++i) pout[i] += pa[i]; \
	} \
	} while (0)

	static void HistogramAdd_MIPS32(const VP8LHistogram* const a,
	const VP8LHistogram* const b,
	VP8LHistogram* const out) {
	uint32_t temp0, temp1, temp2, temp3, temp4, temp5, temp6, temp7;
	const int extra_cache_size = VP8LHistogramNumCodes(a->palette_code_bits_)
	- (NUM_LITERAL_CODES + NUM_LENGTH_CODES);
	assert(a->palette_code_bits_ == b->palette_code_bits_);

	if (b != out) {
	ADD_VECTOR(a->literal_, b->literal_, out->literal_,
	NUM_LITERAL_CODES + NUM_LENGTH_CODES, extra_cache_size);
	ADD_VECTOR(a->distance_, b->distance_, out->distance_,
	NUM_DISTANCE_CODES, 0);
	ADD_VECTOR(a->red_, b->red_, out->red_, NUM_LITERAL_CODES, 0);
	ADD_VECTOR(a->blue_, b->blue_, out->blue_, NUM_LITERAL_CODES, 0);
	ADD_VECTOR(a->alpha_, b->alpha_, out->alpha_, NUM_LITERAL_CODES, 0);
	} else {
	ADD_VECTOR_EQ(a->literal_, out->literal_,
	NUM_LITERAL_CODES + NUM_LENGTH_CODES, extra_cache_size);
	ADD_VECTOR_EQ(a->distance_, out->distance_, NUM_DISTANCE_CODES, 0);
	ADD_VECTOR_EQ(a->red_, out->red_, NUM_LITERAL_CODES, 0);
	ADD_VECTOR_EQ(a->blue_, out->blue_, NUM_LITERAL_CODES, 0);
	ADD_VECTOR_EQ(a->alpha_, out->alpha_, NUM_LITERAL_CODES, 0);
	}
	}

	#undef ADD_VECTOR_EQ
	#undef ADD_VECTOR
	#undef ASM_END_1
	#undef ASM_END_0
	#undef ASM_END_COMMON_1
	#undef ASM_END_COMMON_0
	#undef ADD_TO_OUT
	#undef ASM_START

	//------------------------------------------------------------------------------
	// Entry point

	extern void VP8LEncDspInitMIPS32(void);

	WEBP_TSAN_IGNORE_FUNCTION void VP8LEncDspInitMIPS32(void) {
	VP8LFastSLog2Slow = FastSLog2Slow_MIPS32;
	VP8LFastLog2Slow = FastLog2Slow_MIPS32;
	VP8LExtraCost = ExtraCost_MIPS32;
	VP8LExtraCostCombined = ExtraCostCombined_MIPS32;
	VP8LGetEntropyUnrefined = GetEntropyUnrefined_MIPS32;
	VP8LGetCombinedEntropyUnrefined = GetCombinedEntropyUnrefined_MIPS32;
	VP8LHistogramAdd = HistogramAdd_MIPS32;
	}

	#else // !WEBP_USE_MIPS32

	WEBP_DSP_INIT_STUB(VP8LEncDspInitMIPS32)

	#endif // WEBP_USE_MIPS32