examples/blockStreaming_ringBuffer.c - platform/external/lz4 - Git at Google

 /* LZ4 streaming API example : ring buffer
  * Based on sample code from Takayuki Matsuoka */


 /**************************************
  * Compiler Options
  **************************************/
 #if defined(_MSC_VER) && (_MSC_VER <= 1800)  /* Visual Studio <= 2013 */
 #  define _CRT_SECURE_NO_WARNINGS
 #  define snprintf sprintf_s
 #endif


 /**************************************
  * Includes
  **************************************/
 #include <stdio.h>
 #include <stdint.h>
 #include <stdlib.h>
 #include <string.h>
 #include "lz4.h"


 enum {
     MESSAGE_MAX_BYTES   = 1024,
     RING_BUFFER_BYTES   = 1024 * 8 + MESSAGE_MAX_BYTES,
     DECODE_RING_BUFFER  = RING_BUFFER_BYTES + MESSAGE_MAX_BYTES   /* Intentionally larger, to test unsynchronized ring buffers */
 };


 size_t write_int32(FILE* fp, int32_t i) {
     return fwrite(&i, sizeof(i), 1, fp);
 }

 size_t write_bin(FILE* fp, const void* array, int arrayBytes) {
     return fwrite(array, 1, arrayBytes, fp);
 }

 size_t read_int32(FILE* fp, int32_t* i) {
     return fread(i, sizeof(*i), 1, fp);
 }

 size_t read_bin(FILE* fp, void* array, int arrayBytes) {
     return fread(array, 1, arrayBytes, fp);
 }


 void test_compress(FILE* outFp, FILE* inpFp)
 {
     LZ4_stream_t lz4Stream_body = { { 0 } };
     LZ4_stream_t* lz4Stream = &lz4Stream_body;

     static char inpBuf[RING_BUFFER_BYTES];
     int inpOffset = 0;

     for(;;) {
         // Read random length ([1,MESSAGE_MAX_BYTES]) data to the ring buffer.
         char* const inpPtr = &inpBuf[inpOffset];
         const int randomLength = (rand() % MESSAGE_MAX_BYTES) + 1;
         const int inpBytes = (int) read_bin(inpFp, inpPtr, randomLength);
         if (0 == inpBytes) break;

         {
 #define CMPBUFSIZE (LZ4_COMPRESSBOUND(MESSAGE_MAX_BYTES))
             char cmpBuf[CMPBUFSIZE];
             const int cmpBytes = LZ4_compress_fast_continue(lz4Stream, inpPtr, cmpBuf, inpBytes, CMPBUFSIZE, 0);
             if(cmpBytes <= 0) break;
             write_int32(outFp, cmpBytes);
             write_bin(outFp, cmpBuf, cmpBytes);

             inpOffset += inpBytes;

             // Wraparound the ringbuffer offset
             if(inpOffset >= RING_BUFFER_BYTES - MESSAGE_MAX_BYTES) inpOffset = 0;
         }
     }

     write_int32(outFp, 0);
 }


 void test_decompress(FILE* outFp, FILE* inpFp)
 {
     static char decBuf[DECODE_RING_BUFFER];
     int decOffset = 0;
     LZ4_streamDecode_t lz4StreamDecode_body = { { 0 } };
     LZ4_streamDecode_t* lz4StreamDecode = &lz4StreamDecode_body;

     for(;;) {
         int cmpBytes = 0;
         char cmpBuf[CMPBUFSIZE];

         {   const size_t r0 = read_int32(inpFp, &cmpBytes);
             if(r0 != 1 || cmpBytes <= 0) break;

             const size_t r1 = read_bin(inpFp, cmpBuf, cmpBytes);
             if(r1 != (size_t) cmpBytes) break;
         }

         {   char* const decPtr = &decBuf[decOffset];
             const int decBytes = LZ4_decompress_safe_continue(
                 lz4StreamDecode, cmpBuf, decPtr, cmpBytes, MESSAGE_MAX_BYTES);
             if(decBytes <= 0) break;
             decOffset += decBytes;
             write_bin(outFp, decPtr, decBytes);

             // Wraparound the ringbuffer offset
             if(decOffset >= DECODE_RING_BUFFER - MESSAGE_MAX_BYTES) decOffset = 0;
         }
     }
 }


 int compare(FILE* f0, FILE* f1)
 {
     int result = 0;

     while (0 == result) {
         char b0[65536];
         char b1[65536];
         const size_t r0 = fread(b0, 1, sizeof(b0), f0);
         const size_t r1 = fread(b1, 1, sizeof(b1), f1);

         result = (int) r0 - (int) r1;

         if (0 == r0 || 0 == r1) break;

         if (0 == result) result = memcmp(b0, b1, r0);
     }

     return result;
 }


 int main(int argc, char** argv)
 {
     char inpFilename[256] = { 0 };
     char lz4Filename[256] = { 0 };
     char decFilename[256] = { 0 };

     if (argc < 2) {
         printf("Please specify input filename\n");
         return 0;
     }

     snprintf(inpFilename, 256, "%s", argv[1]);
     snprintf(lz4Filename, 256, "%s.lz4s-%d", argv[1], 0);
     snprintf(decFilename, 256, "%s.lz4s-%d.dec", argv[1], 0);

     printf("inp = [%s]\n", inpFilename);
     printf("lz4 = [%s]\n", lz4Filename);
     printf("dec = [%s]\n", decFilename);

     // compress
     {   FILE* const inpFp = fopen(inpFilename, "rb");
         FILE* const outFp = fopen(lz4Filename, "wb");

         test_compress(outFp, inpFp);

         fclose(outFp);
         fclose(inpFp);
     }

     // decompress
     {   FILE* const inpFp = fopen(lz4Filename, "rb");
         FILE* const outFp = fopen(decFilename, "wb");

         test_decompress(outFp, inpFp);

         fclose(outFp);
         fclose(inpFp);
     }

     // verify
     {   FILE* const inpFp = fopen(inpFilename, "rb");
         FILE* const decFp = fopen(decFilename, "rb");

         const int cmp = compare(inpFp, decFp);
         if (0 == cmp) {
             printf("Verify : OK\n");
         } else {
             printf("Verify : NG\n");
         }

         fclose(decFp);
         fclose(inpFp);
     }

     return 0;
 }
	/* LZ4 streaming API example : ring buffer
	* Based on sample code from Takayuki Matsuoka */


	/**************************************
	* Compiler Options
	**************************************/
	#if defined(_MSC_VER) && (_MSC_VER <= 1800) /* Visual Studio <= 2013 */
	# define _CRT_SECURE_NO_WARNINGS
	# define snprintf sprintf_s
	#endif


	/**************************************
	* Includes
	**************************************/
	#include <stdio.h>
	#include <stdint.h>
	#include <stdlib.h>
	#include <string.h>
	#include "lz4.h"


	enum {
	MESSAGE_MAX_BYTES = 1024,
	RING_BUFFER_BYTES = 1024 * 8 + MESSAGE_MAX_BYTES,
	DECODE_RING_BUFFER = RING_BUFFER_BYTES + MESSAGE_MAX_BYTES /* Intentionally larger, to test unsynchronized ring buffers */
	};


	size_t write_int32(FILE* fp, int32_t i) {
	return fwrite(&i, sizeof(i), 1, fp);
	}

	size_t write_bin(FILE* fp, const void* array, int arrayBytes) {
	return fwrite(array, 1, arrayBytes, fp);
	}

	size_t read_int32(FILE* fp, int32_t* i) {
	return fread(i, sizeof(*i), 1, fp);
	}

	size_t read_bin(FILE* fp, void* array, int arrayBytes) {
	return fread(array, 1, arrayBytes, fp);
	}


	void test_compress(FILE* outFp, FILE* inpFp)
	{
	LZ4_stream_t lz4Stream_body = { { 0 } };
	LZ4_stream_t* lz4Stream = &lz4Stream_body;

	static char inpBuf[RING_BUFFER_BYTES];
	int inpOffset = 0;

	for(;;) {
	// Read random length ([1,MESSAGE_MAX_BYTES]) data to the ring buffer.
	char* const inpPtr = &inpBuf[inpOffset];
	const int randomLength = (rand() % MESSAGE_MAX_BYTES) + 1;
	const int inpBytes = (int) read_bin(inpFp, inpPtr, randomLength);
	if (0 == inpBytes) break;

	{
	#define CMPBUFSIZE (LZ4_COMPRESSBOUND(MESSAGE_MAX_BYTES))
	char cmpBuf[CMPBUFSIZE];
	const int cmpBytes = LZ4_compress_fast_continue(lz4Stream, inpPtr, cmpBuf, inpBytes, CMPBUFSIZE, 0);
	if(cmpBytes <= 0) break;
	write_int32(outFp, cmpBytes);
	write_bin(outFp, cmpBuf, cmpBytes);

	inpOffset += inpBytes;

	// Wraparound the ringbuffer offset
	if(inpOffset >= RING_BUFFER_BYTES - MESSAGE_MAX_BYTES) inpOffset = 0;
	}
	}

	write_int32(outFp, 0);
	}


	void test_decompress(FILE* outFp, FILE* inpFp)
	{
	static char decBuf[DECODE_RING_BUFFER];
	int decOffset = 0;
	LZ4_streamDecode_t lz4StreamDecode_body = { { 0 } };
	LZ4_streamDecode_t* lz4StreamDecode = &lz4StreamDecode_body;

	for(;;) {
	int cmpBytes = 0;
	char cmpBuf[CMPBUFSIZE];

	{ const size_t r0 = read_int32(inpFp, &cmpBytes);
	if(r0 != 1 \|\| cmpBytes <= 0) break;

	const size_t r1 = read_bin(inpFp, cmpBuf, cmpBytes);
	if(r1 != (size_t) cmpBytes) break;
	}

	{ char* const decPtr = &decBuf[decOffset];
	const int decBytes = LZ4_decompress_safe_continue(
	lz4StreamDecode, cmpBuf, decPtr, cmpBytes, MESSAGE_MAX_BYTES);
	if(decBytes <= 0) break;
	decOffset += decBytes;
	write_bin(outFp, decPtr, decBytes);

	// Wraparound the ringbuffer offset
	if(decOffset >= DECODE_RING_BUFFER - MESSAGE_MAX_BYTES) decOffset = 0;
	}
	}
	}


	int compare(FILE* f0, FILE* f1)
	{
	int result = 0;

	while (0 == result) {
	char b0[65536];
	char b1[65536];
	const size_t r0 = fread(b0, 1, sizeof(b0), f0);
	const size_t r1 = fread(b1, 1, sizeof(b1), f1);

	result = (int) r0 - (int) r1;

	if (0 == r0 \|\| 0 == r1) break;

	if (0 == result) result = memcmp(b0, b1, r0);
	}

	return result;
	}


	int main(int argc, char** argv)
	{
	char inpFilename[256] = { 0 };
	char lz4Filename[256] = { 0 };
	char decFilename[256] = { 0 };

	if (argc < 2) {
	printf("Please specify input filename\n");
	return 0;
	}

	snprintf(inpFilename, 256, "%s", argv[1]);
	snprintf(lz4Filename, 256, "%s.lz4s-%d", argv[1], 0);
	snprintf(decFilename, 256, "%s.lz4s-%d.dec", argv[1], 0);

	printf("inp = [%s]\n", inpFilename);
	printf("lz4 = [%s]\n", lz4Filename);
	printf("dec = [%s]\n", decFilename);

	// compress
	{ FILE* const inpFp = fopen(inpFilename, "rb");
	FILE* const outFp = fopen(lz4Filename, "wb");

	test_compress(outFp, inpFp);

	fclose(outFp);
	fclose(inpFp);
	}

	// decompress
	{ FILE* const inpFp = fopen(lz4Filename, "rb");
	FILE* const outFp = fopen(decFilename, "wb");

	test_decompress(outFp, inpFp);

	fclose(outFp);
	fclose(inpFp);
	}

	// verify
	{ FILE* const inpFp = fopen(inpFilename, "rb");
	FILE* const decFp = fopen(decFilename, "rb");

	const int cmp = compare(inpFp, decFp);
	if (0 == cmp) {
	printf("Verify : OK\n");
	} else {
	printf("Verify : NG\n");
	}

	fclose(decFp);
	fclose(inpFp);
	}

	return 0;
	}