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main_simd.cpp
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main_simd.cpp
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#include "platform.h"
#include <stdio.h>
#include <stdarg.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <assert.h>
#include "rans_word_sse41.h"
// This is just the sample program. All the meat is in rans_byte.h.
static void panic(const char *fmt, ...)
{
va_list arg;
va_start(arg, fmt);
fputs("Error: ", stderr);
vfprintf(stderr, fmt, arg);
va_end(arg);
fputs("\n", stderr);
exit(1);
}
static uint8_t* read_file(char const* filename, size_t* out_size)
{
FILE* f = fopen(filename, "rb");
if (!f)
panic("file not found: %s\n", filename);
fseek(f, 0, SEEK_END);
size_t size = ftell(f);
fseek(f, 0, SEEK_SET);
uint8_t* buf = new uint8_t[size];
if (fread(buf, size, 1, f) != 1)
panic("read failed\n");
fclose(f);
if (out_size)
*out_size = size;
return buf;
}
// ---- Stats
struct SymbolStats
{
uint32_t freqs[256];
uint32_t cum_freqs[257];
void count_freqs(uint8_t const* in, size_t nbytes);
void calc_cum_freqs();
void normalize_freqs(uint32_t target_total);
};
void SymbolStats::count_freqs(uint8_t const* in, size_t nbytes)
{
for (int i=0; i < 256; i++)
freqs[i] = 0;
for (size_t i=0; i < nbytes; i++)
freqs[in[i]]++;
}
void SymbolStats::calc_cum_freqs()
{
cum_freqs[0] = 0;
for (int i=0; i < 256; i++)
cum_freqs[i+1] = cum_freqs[i] + freqs[i];
}
void SymbolStats::normalize_freqs(uint32_t target_total)
{
assert(target_total >= 256);
calc_cum_freqs();
uint32_t cur_total = cum_freqs[256];
// resample distribution based on cumulative freqs
for (int i = 1; i <= 256; i++)
cum_freqs[i] = ((uint64_t)target_total * cum_freqs[i])/cur_total;
// if we nuked any non-0 frequency symbol to 0, we need to steal
// the range to make the frequency nonzero from elsewhere.
//
// this is not at all optimal, i'm just doing the first thing that comes to mind.
for (int i=0; i < 256; i++) {
if (freqs[i] && cum_freqs[i+1] == cum_freqs[i]) {
// symbol i was set to zero freq
// find best symbol to steal frequency from (try to steal from low-freq ones)
uint32_t best_freq = ~0u;
int best_steal = -1;
for (int j=0; j < 256; j++) {
uint32_t freq = cum_freqs[j+1] - cum_freqs[j];
if (freq > 1 && freq < best_freq) {
best_freq = freq;
best_steal = j;
}
}
assert(best_steal != -1);
// and steal from it!
if (best_steal < i) {
for (int j = best_steal + 1; j <= i; j++)
cum_freqs[j]--;
} else {
assert(best_steal > i);
for (int j = i + 1; j <= best_steal; j++)
cum_freqs[j]++;
}
}
}
// calculate updated freqs and make sure we didn't screw anything up
assert(cum_freqs[0] == 0 && cum_freqs[256] == target_total);
for (int i=0; i < 256; i++) {
if (freqs[i] == 0)
assert(cum_freqs[i+1] == cum_freqs[i]);
else
assert(cum_freqs[i+1] > cum_freqs[i]);
// calc updated freq
freqs[i] = cum_freqs[i+1] - cum_freqs[i];
}
}
int main()
{
size_t in_size;
uint8_t* in_bytes = read_file("book1", &in_size);
SymbolStats stats;
stats.count_freqs(in_bytes, in_size);
stats.normalize_freqs(RANS_WORD_M);
// init decoding tables
RansWordTables tab;
for (int s=0; s < 256; s++)
RansWordTablesInitSymbol(&tab, (uint8_t)s, stats.cum_freqs[s], stats.freqs[s]);
size_t out_max_size = in_size + (in_size >> 3) + 128;
uint8_t* out_buf = new uint8_t[out_max_size + 16]; // extra bytes at end
uint8_t* dec_bytes = new uint8_t[in_size];
// try rANS encode
uint16_t *rans_begin;
// ---- regular rANS encode/decode. Typical usage.
memset(dec_bytes, 0xcc, in_size);
printf("rANS encode:\n");
for (int run=0; run < 5; run++) {
double start_time = timer();
uint64_t enc_start_time = __rdtsc();
RansWordEnc rans = RansWordEncInit();
uint16_t* ptr = (uint16_t *) (out_buf + out_max_size); // *end* of output buffer
for (size_t i=in_size; i > 0; i--) { // NB: working in reverse!
int s = in_bytes[i-1];
RansWordEncPut(&rans, &ptr, stats.cum_freqs[s], stats.freqs[s]);
}
RansWordEncFlush(&rans, &ptr);
rans_begin = ptr;
uint64_t enc_clocks = __rdtsc() - enc_start_time;
double enc_time = timer() - start_time;
printf("%"PRIu64" clocks, %.1f clocks/symbol (%5.1fMiB/s)\n", enc_clocks, 1.0 * enc_clocks / in_size, 1.0 * in_size / (enc_time * 1048576.0));
}
printf("rANS: %d bytes\n", (int) (out_buf + out_max_size - (uint8_t *)rans_begin));
// try rANS decode
for (int run=0; run < 5; run++) {
double start_time = timer();
uint64_t dec_start_time = __rdtsc();
RansWordDec rans;
uint16_t* ptr = rans_begin;
RansWordDecInit(&rans, &ptr);
for (size_t i=0; i < in_size; i++) {
uint8_t s = RansWordDecSym(&rans, &tab);
dec_bytes[i] = (uint8_t) s;
RansWordDecRenorm(&rans, &ptr);
}
uint64_t dec_clocks = __rdtsc() - dec_start_time;
double dec_time = timer() - start_time;
printf("%"PRIu64" clocks, %.1f clocks/symbol (%5.1fMiB/s)\n", dec_clocks, 1.0 * dec_clocks / in_size, 1.0 * in_size / (dec_time * 1048576.0));
}
// check decode results
if (memcmp(in_bytes, dec_bytes, in_size) == 0)
printf("decode ok!\n");
else
printf("ERROR: bad decoder!\n");
// ---- interleaved rANS encode/decode. This is the kind of thing you might do to optimize critical paths.
memset(dec_bytes, 0xcc, in_size);
// try interleaved rANS encode
printf("\ninterleaved rANS encode:\n");
for (int run=0; run < 5; run++) {
double start_time = timer();
uint64_t enc_start_time = __rdtsc();
RansWordEnc rans0 = RansWordEncInit();
RansWordEnc rans1 = RansWordEncInit();
uint16_t* ptr = (uint16_t *)(out_buf + out_max_size); // *end* of output buffer
// odd number of bytes?
if (in_size & 1) {
int s = in_bytes[in_size - 1];
RansWordEncPut(&rans0, &ptr, stats.cum_freqs[s], stats.freqs[s]);
}
for (size_t i=(in_size & ~1); i > 0; i -= 2) { // NB: working in reverse!
int s1 = in_bytes[i-1];
int s0 = in_bytes[i-2];
RansWordEncPut(&rans1, &ptr, stats.cum_freqs[s1], stats.freqs[s1]);
RansWordEncPut(&rans0, &ptr, stats.cum_freqs[s0], stats.freqs[s0]);
}
RansWordEncFlush(&rans1, &ptr);
RansWordEncFlush(&rans0, &ptr);
rans_begin = ptr;
uint64_t enc_clocks = __rdtsc() - enc_start_time;
double enc_time = timer() - start_time;
printf("%"PRIu64" clocks, %.1f clocks/symbol (%5.1fMiB/s)\n", enc_clocks, 1.0 * enc_clocks / in_size, 1.0 * in_size / (enc_time * 1048576.0));
}
printf("interleaved rANS: %d bytes\n", (int) (out_buf + out_max_size - (uint8_t*)rans_begin));
// try interleaved rANS decode
for (int run=0; run < 5; run++) {
double start_time = timer();
uint64_t dec_start_time = __rdtsc();
RansWordDec rans0, rans1;
uint16_t* ptr = rans_begin;
RansWordDecInit(&rans0, &ptr);
RansWordDecInit(&rans1, &ptr);
for (size_t i=0; i < (in_size & ~1); i += 2) {
uint8_t s0 = RansWordDecSym(&rans0, &tab);
uint8_t s1 = RansWordDecSym(&rans1, &tab);
dec_bytes[i+0] = (uint8_t) s0;
dec_bytes[i+1] = (uint8_t) s1;
RansWordDecRenorm(&rans0, &ptr);
RansWordDecRenorm(&rans1, &ptr);
}
// last byte, if number of bytes was odd
if (in_size & 1) {
uint8_t s0 = RansWordDecSym(&rans0, &tab);
dec_bytes[in_size - 1] = (uint8_t) s0;
}
uint64_t dec_clocks = __rdtsc() - dec_start_time;
double dec_time = timer() - start_time;
printf("%"PRIu64" clocks, %.1f clocks/symbol (%5.1fMB/s)\n", dec_clocks, 1.0 * dec_clocks / in_size, 1.0 * in_size / (dec_time * 1048576.0));
}
// check decode results
if (memcmp(in_bytes, dec_bytes, in_size) == 0)
printf("decode ok!\n");
else
printf("ERROR: bad decoder!\n");
// ---- SIMD interleaved rANS encode/decode.
memset(dec_bytes, 0xcc, in_size);
// try SIMD rANS encode
// this is written for clarity not speed.
printf("\ninterleaved SIMD rANS encode: (encode itself isn't SIMD)\n");
for (int run=0; run < 5; run++) {
double start_time = timer();
uint64_t enc_start_time = __rdtsc();
RansWordEnc rans[8];
for (int i=0; i < 8; i++)
rans[i] = RansWordEncInit();
uint16_t* ptr = (uint16_t *)(out_buf + out_max_size); // *end* of output buffer
// last few bytes
for (size_t i=in_size; i > 0; i--) { // NB: working in reverse
int s = in_bytes[i - 1];
RansWordEncPut(&rans[(i - 1) & 7], &ptr, stats.cum_freqs[s], stats.freqs[s]);
}
for (int i=8; i > 0; i--)
RansWordEncFlush(&rans[i - 1], &ptr);
rans_begin = ptr;
uint64_t enc_clocks = __rdtsc() - enc_start_time;
double enc_time = timer() - start_time;
printf("%"PRIu64" clocks, %.1f clocks/symbol (%5.1fMiB/s)\n", enc_clocks, 1.0 * enc_clocks / in_size, 1.0 * in_size / (enc_time * 1048576.0));
}
printf("SIMD rANS: %d bytes\n", (int) (out_buf + out_max_size - (uint8_t*)rans_begin));
// try SIMD rANS decode
for (int run=0; run < 5; run++) {
double start_time = timer();
uint64_t dec_start_time = __rdtsc();
RansSimdDec rans0, rans1;
uint16_t* ptr = rans_begin;
RansSimdDecInit(&rans0, &ptr);
RansSimdDecInit(&rans1, &ptr);
for (size_t i=0; i < (in_size & ~7); i += 8) {
uint32_t s03 = RansSimdDecSym(&rans0, &tab);
uint32_t s47 = RansSimdDecSym(&rans1, &tab);
*(uint32_t *)(dec_bytes + i) = s03;
*(uint32_t *)(dec_bytes + i + 4) = s47;
RansSimdDecRenorm(&rans0, &ptr);
RansSimdDecRenorm(&rans1, &ptr);
}
// last few bytes
for (size_t i=(in_size & ~7); i < in_size; i++) {
RansSimdDec* which = (i & 4) != 0 ? &rans1 : &rans0;
uint8_t s = RansWordDecSym(&which->lane[i & 3], &tab);
dec_bytes[i] = s;
}
uint64_t dec_clocks = __rdtsc() - dec_start_time;
double dec_time = timer() - start_time;
printf("%"PRIu64" clocks, %.1f clocks/symbol (%5.1fMB/s)\n", dec_clocks, 1.0 * dec_clocks / in_size, 1.0 * in_size / (dec_time * 1048576.0));
}
// check decode results
if (memcmp(in_bytes, dec_bytes, in_size) == 0)
printf("decode ok!\n");
else
printf("ERROR: bad decoder!\n");
delete[] out_buf;
delete[] dec_bytes;
delete[] in_bytes;
return 0;
}