read-redis/redis-check-dump.c
2010-03-13 15:57:00 +01:00

672 lines
18 KiB
C

#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <sys/mman.h>
#include <string.h>
#include <arpa/inet.h>
#include <stdint.h>
#include <limits.h>
#include "lzf.h"
/* Object types */
#define REDIS_STRING 0
#define REDIS_LIST 1
#define REDIS_SET 2
#define REDIS_ZSET 3
#define REDIS_HASH 4
/* Objects encoding. Some kind of objects like Strings and Hashes can be
* internally represented in multiple ways. The 'encoding' field of the object
* is set to one of this fields for this object. */
#define REDIS_ENCODING_RAW 0 /* Raw representation */
#define REDIS_ENCODING_INT 1 /* Encoded as integer */
#define REDIS_ENCODING_ZIPMAP 2 /* Encoded as zipmap */
#define REDIS_ENCODING_HT 3 /* Encoded as an hash table */
/* Object types only used for dumping to disk */
#define REDIS_EXPIRETIME 253
#define REDIS_SELECTDB 254
#define REDIS_EOF 255
/* Defines related to the dump file format. To store 32 bits lengths for short
* keys requires a lot of space, so we check the most significant 2 bits of
* the first byte to interpreter the length:
*
* 00|000000 => if the two MSB are 00 the len is the 6 bits of this byte
* 01|000000 00000000 => 01, the len is 14 byes, 6 bits + 8 bits of next byte
* 10|000000 [32 bit integer] => if it's 01, a full 32 bit len will follow
* 11|000000 this means: specially encoded object will follow. The six bits
* number specify the kind of object that follows.
* See the REDIS_RDB_ENC_* defines.
*
* Lenghts up to 63 are stored using a single byte, most DB keys, and may
* values, will fit inside. */
#define REDIS_RDB_6BITLEN 0
#define REDIS_RDB_14BITLEN 1
#define REDIS_RDB_32BITLEN 2
#define REDIS_RDB_ENCVAL 3
#define REDIS_RDB_LENERR UINT_MAX
/* When a length of a string object stored on disk has the first two bits
* set, the remaining two bits specify a special encoding for the object
* accordingly to the following defines: */
#define REDIS_RDB_ENC_INT8 0 /* 8 bit signed integer */
#define REDIS_RDB_ENC_INT16 1 /* 16 bit signed integer */
#define REDIS_RDB_ENC_INT32 2 /* 32 bit signed integer */
#define REDIS_RDB_ENC_LZF 3 /* string compressed with FASTLZ */
#define ERROR(...) { \
printf(__VA_ARGS__); \
exit(1); \
}
/* data type to hold offset in file and size */
typedef struct {
void *data;
unsigned long size;
unsigned long offset;
} pos;
static unsigned char level = 0;
static pos positions[16];
#define CURR_OFFSET (positions[level].offset)
/* Hold a stack of errors */
typedef struct {
char error[16][1024];
unsigned long offset[16];
unsigned int level;
} errors_t;
static errors_t errors;
#define SHIFT_ERROR(provided_offset, ...) { \
sprintf(errors.error[errors.level], __VA_ARGS__); \
errors.offset[errors.level] = provided_offset; \
errors.level++; \
}
/* Data type to hold opcode with optional key name an success status */
typedef struct {
char* key;
int type;
char success;
} entry;
/* Global vars that are actally used as constants. The following double
* values are used for double on-disk serialization, and are initialized
* at runtime to avoid strange compiler optimizations. */
static double R_Zero, R_PosInf, R_NegInf, R_Nan;
/* store string types for output */
static char types[256][16];
/* when number of bytes to read is negative, do a peek */
int readBytes(void *target, long num) {
char peek = (num < 0) ? 1 : 0;
num = (num < 0) ? -num : num;
pos p = positions[level];
if (p.offset + num > p.size) {
return 0;
} else {
memcpy(target, (void*)((unsigned long)p.data + p.offset), num);
if (!peek) positions[level].offset += num;
}
return 1;
}
int processHeader() {
char buf[10] = "_________";
int dump_version;
if (!readBytes(buf, 9)) {
ERROR("Cannot read header\n");
}
/* expect the first 5 bytes to equal REDIS */
if (memcmp(buf,"REDIS",5) != 0) {
ERROR("Wrong signature in header\n");
}
dump_version = (int)strtol(buf + 5, NULL, 10);
if (dump_version != 1) {
ERROR("Unknown RDB format version: %d\n", dump_version);
}
return 1;
}
int loadType(entry *e) {
uint32_t offset = CURR_OFFSET;
/* this byte needs to qualify as type */
unsigned char t;
if (readBytes(&t, 1)) {
if (t <= 4 || t >= 253) {
e->type = t;
return 1;
} else {
SHIFT_ERROR(offset, "Unknown type (0x%02x)", t);
}
} else {
SHIFT_ERROR(offset, "Could not read type");
}
/* failure */
return 0;
}
int peekType() {
unsigned char t;
if (readBytes(&t, -1) && (t <= 4 || t >= 253)) return t;
return -1;
}
/* discard time, just consume the bytes */
int processTime() {
uint32_t offset = CURR_OFFSET;
unsigned char t[4];
if (readBytes(t, 4)) {
return 1;
} else {
SHIFT_ERROR(offset, "Could not read time");
}
/* failure */
return 0;
}
uint32_t loadLength(int *isencoded) {
unsigned char buf[2];
uint32_t len;
int type;
if (isencoded) *isencoded = 0;
if (!readBytes(buf, 1)) return REDIS_RDB_LENERR;
type = (buf[0] & 0xC0) >> 6;
if (type == REDIS_RDB_6BITLEN) {
/* Read a 6 bit len */
return buf[0] & 0x3F;
} else if (type == REDIS_RDB_ENCVAL) {
/* Read a 6 bit len encoding type */
if (isencoded) *isencoded = 1;
return buf[0] & 0x3F;
} else if (type == REDIS_RDB_14BITLEN) {
/* Read a 14 bit len */
if (!readBytes(buf+1,1)) return REDIS_RDB_LENERR;
return ((buf[0] & 0x3F) << 8) | buf[1];
} else {
/* Read a 32 bit len */
if (!readBytes(&len, 4)) return REDIS_RDB_LENERR;
return (unsigned int)ntohl(len);
}
}
char *loadIntegerObject(int enctype) {
uint32_t offset = CURR_OFFSET;
unsigned char enc[4];
long long val;
if (enctype == REDIS_RDB_ENC_INT8) {
uint8_t v;
if (!readBytes(enc, 1)) return NULL;
v = enc[0];
val = (int8_t)v;
} else if (enctype == REDIS_RDB_ENC_INT16) {
uint16_t v;
if (!readBytes(enc, 2)) return NULL;
v = enc[0]|(enc[1]<<8);
val = (int16_t)v;
} else if (enctype == REDIS_RDB_ENC_INT32) {
uint32_t v;
if (!readBytes(enc, 4)) return NULL;
v = enc[0]|(enc[1]<<8)|(enc[2]<<16)|(enc[3]<<24);
val = (int32_t)v;
} else {
SHIFT_ERROR(offset, "Unknown integer encoding (0x%02x)", enctype);
return NULL;
}
/* convert val into string */
char *buf;
buf = malloc(sizeof(char) * 128);
sprintf(buf, "%lld", val);
return buf;
}
char* loadLzfStringObject() {
unsigned int slen, clen;
char *c, *s;
if ((clen = loadLength(NULL)) == REDIS_RDB_LENERR) return NULL;
if ((slen = loadLength(NULL)) == REDIS_RDB_LENERR) return NULL;
c = malloc(clen);
if (!readBytes(c, clen)) {
free(c);
return NULL;
}
s = malloc(slen+1);
if (lzf_decompress(c,clen,s,slen) == 0) {
free(c); free(s);
return NULL;
}
free(c);
return s;
}
/* returns NULL when not processable, char* when valid */
char* loadStringObject() {
uint32_t offset = CURR_OFFSET;
int isencoded;
uint32_t len;
len = loadLength(&isencoded);
if (isencoded) {
switch(len) {
case REDIS_RDB_ENC_INT8:
case REDIS_RDB_ENC_INT16:
case REDIS_RDB_ENC_INT32:
return loadIntegerObject(len);
case REDIS_RDB_ENC_LZF:
return loadLzfStringObject();
default:
/* unknown encoding */
SHIFT_ERROR(offset, "Unknown string encoding (0x%02x)", len);
return NULL;
}
}
if (len == REDIS_RDB_LENERR) return NULL;
char *buf = malloc(sizeof(char) * (len+1));
buf[len] = '\0';
if (!readBytes(buf, len)) {
free(buf);
return NULL;
}
return buf;
}
int processStringObject(char** store) {
unsigned long offset = CURR_OFFSET;
char *key = loadStringObject();
if (key == NULL) {
SHIFT_ERROR(offset, "Error reading string object");
free(key);
return 0;
}
if (store != NULL) {
*store = key;
} else {
free(key);
}
return 1;
}
double* loadDoubleValue() {
char buf[256];
unsigned char len;
double* val;
if (!readBytes(&len,1)) return NULL;
val = malloc(sizeof(double));
switch(len) {
case 255: *val = R_NegInf; return val;
case 254: *val = R_PosInf; return val;
case 253: *val = R_Nan; return val;
default:
if (!readBytes(buf, len)) {
free(val);
return NULL;
}
buf[len] = '\0';
sscanf(buf, "%lg", val);
return val;
}
}
int processDoubleValue(double** store) {
unsigned long offset = CURR_OFFSET;
double *val = loadDoubleValue();
if (val == NULL) {
SHIFT_ERROR(offset, "Error reading double value");
free(val);
return 0;
}
if (store != NULL) {
*store = val;
} else {
free(val);
}
return 1;
}
int loadPair(entry *e) {
uint32_t offset = CURR_OFFSET;
uint32_t i;
/* read key first */
char *key;
if (processStringObject(&key)) {
e->key = key;
} else {
SHIFT_ERROR(offset, "Error reading entry key");
return 0;
}
uint32_t length = 0;
if (e->type == REDIS_LIST ||
e->type == REDIS_SET ||
e->type == REDIS_ZSET ||
e->type == REDIS_HASH) {
if ((length = loadLength(NULL)) == REDIS_RDB_LENERR) {
SHIFT_ERROR(offset, "Error reading %s length", types[e->type]);
return 0;
}
}
switch(e->type) {
case REDIS_STRING:
if (!processStringObject(NULL)) {
SHIFT_ERROR(offset, "Error reading entry value");
return 0;
}
break;
case REDIS_LIST:
case REDIS_SET:
for (i = 0; i < length; i++) {
offset = CURR_OFFSET;
if (!processStringObject(NULL)) {
SHIFT_ERROR(offset, "Error reading element at index %d (length: %d)", i, length);
return 0;
}
}
break;
case REDIS_ZSET:
for (i = 0; i < length; i++) {
offset = CURR_OFFSET;
if (!processStringObject(NULL)) {
SHIFT_ERROR(offset, "Error reading element key at index %d (length: %d)", i, length);
return 0;
}
offset = CURR_OFFSET;
if (!processDoubleValue(NULL)) {
SHIFT_ERROR(offset, "Error reading element value at index %d (length: %d)", i, length);
return 0;
}
}
break;
case REDIS_HASH:
for (i = 0; i < length; i++) {
offset = CURR_OFFSET;
if (!processStringObject(NULL)) {
SHIFT_ERROR(offset, "Error reading element key at index %d (length: %d)", i, length);
return 0;
}
offset = CURR_OFFSET;
if (!processStringObject(NULL)) {
SHIFT_ERROR(offset, "Error reading element value at index %d (length: %d)", i, length);
return 0;
}
}
break;
default:
SHIFT_ERROR(offset, "Type not implemented");
return 0;
}
/* because we're done, we assume success */
e->success = 1;
return 1;
}
entry loadEntry() {
entry e = { NULL, -1, 0 };
uint32_t length, offset[4];
/* reset error container */
errors.level = 0;
offset[0] = CURR_OFFSET;
if (!loadType(&e)) {
return e;
}
offset[1] = CURR_OFFSET;
if (e.type == REDIS_SELECTDB) {
if ((length = loadLength(NULL)) == REDIS_RDB_LENERR) {
SHIFT_ERROR(offset[1], "Error reading database number");
return e;
}
if (length > 63) {
SHIFT_ERROR(offset[1], "Database number out of range (%d)", length);
return e;
}
} else if (e.type == REDIS_EOF) {
if (positions[level].offset < positions[level].size) {
SHIFT_ERROR(offset[0], "Unexpected EOF");
} else {
e.success = 1;
}
return e;
} else {
/* optionally consume expire */
if (e.type == REDIS_EXPIRETIME) {
if (!processTime()) return e;
if (!loadType(&e)) return e;
}
offset[1] = CURR_OFFSET;
if (!loadPair(&e)) {
SHIFT_ERROR(offset[1], "Error for type %s", types[e.type]);
return e;
}
}
/* all entries are followed by a valid type:
* e.g. a new entry, SELECTDB, EXPIRE, EOF */
offset[2] = CURR_OFFSET;
if (peekType() == -1) {
SHIFT_ERROR(offset[2], "Followed by invalid type");
SHIFT_ERROR(offset[0], "Error for type %s", types[e.type]);
e.success = 0;
} else {
e.success = 1;
}
return e;
}
void printCentered(int indent, int width, char* body) {
char head[256], tail[256];
memset(head, '\0', 256);
memset(tail, '\0', 256);
memset(head, '=', indent);
memset(tail, '=', width - 2 - indent - strlen(body));
printf("%s %s %s\n", head, body, tail);
}
void printValid(int ops, int bytes) {
char body[80];
sprintf(body, "Processed %d valid opcodes (in %d bytes)", ops, bytes);
printCentered(4, 80, body);
}
void printSkipped(int bytes, int offset) {
char body[80];
sprintf(body, "Skipped %d bytes (resuming at 0x%08x)", bytes, offset);
printCentered(4, 80, body);
}
void printErrorStack(entry *e) {
unsigned int i;
char body[64];
if (e->type == -1) {
sprintf(body, "Error trace");
} else if (e->type >= 253) {
sprintf(body, "Error trace (%s)", types[e->type]);
} else if (!e->key) {
sprintf(body, "Error trace (%s: (unknown))", types[e->type]);
} else {
char tmp[41];
strncpy(tmp, e->key, 40);
/* display truncation at the last 3 chars */
if (strlen(e->key) > 40) {
memset(&tmp[37], '.', 3);
}
/* display unprintable characters as ? */
for (i = 0; i < strlen(tmp); i++) {
if (tmp[i] <= 32) tmp[i] = '?';
}
sprintf(body, "Error trace (%s: %s)", types[e->type], tmp);
}
printCentered(4, 80, body);
/* display error stack */
for (i = 0; i < errors.level; i++) {
printf("0x%08lx - %s\n", errors.offset[i], errors.error[i]);
}
}
void process() {
int i, num_errors = 0, num_valid_ops = 0, num_valid_bytes = 0;
entry entry;
processHeader();
level = 1;
while(positions[0].offset < positions[0].size) {
positions[1] = positions[0];
entry = loadEntry();
if (!entry.success) {
printValid(num_valid_ops, num_valid_bytes);
printErrorStack(&entry);
num_errors++;
num_valid_ops = 0;
num_valid_bytes = 0;
/* search for next valid entry */
unsigned long offset = positions[0].offset + 1;
while (!entry.success && offset < positions[0].size) {
positions[1].offset = offset;
/* find 3 consecutive valid entries */
for (i = 0; i < 3; i++) {
entry = loadEntry();
if (!entry.success) break;
}
/* check if we found 3 consecutive valid entries */
if (i < 3) {
offset++;
}
}
/* print how many bytes we have skipped to find a new valid opcode */
if (offset < positions[0].size) {
printSkipped(offset - positions[0].offset, offset);
}
positions[0].offset = offset;
} else {
num_valid_ops++;
num_valid_bytes += positions[1].offset - positions[0].offset;
/* advance position */
positions[0] = positions[1];
}
}
/* because there is another potential error,
* print how many valid ops we have processed */
printValid(num_valid_ops, num_valid_bytes);
/* expect an eof */
if (entry.type != REDIS_EOF) {
/* last byte should be EOF, add error */
errors.level = 0;
SHIFT_ERROR(positions[0].offset, "Expected EOF, got %s", types[entry.type]);
/* this is an EOF error so reset type */
entry.type = -1;
printErrorStack(&entry);
num_errors++;
}
/* print summary on errors */
if (num_errors > 0) {
printf("\n");
printf("Total unprocessable opcodes: %d\n", num_errors);
}
}
int main(int argc, char **argv) {
/* expect the first argument to be the dump file */
if (argc <= 1) {
printf("Usage: %s <dump.rdb>\n", argv[0]);
exit(0);
}
int fd;
unsigned long size;
struct stat stat;
void *data;
fd = open(argv[1], O_RDONLY);
if (fd < 1) {
ERROR("Cannot open file: %s\n", argv[1]);
}
if (fstat(fd, &stat) == -1) {
ERROR("Cannot stat: %s\n", argv[1]);
} else {
size = stat.st_size;
}
data = mmap(NULL, size, PROT_READ, MAP_SHARED, fd, 0);
if (data == MAP_FAILED) {
ERROR("Cannot mmap: %s\n", argv[1]);
}
/* Initialize static vars */
positions[0].data = data;
positions[0].size = size;
positions[0].offset = 0;
errors.level = 0;
/* Object types */
sprintf(types[REDIS_STRING], "STRING");
sprintf(types[REDIS_LIST], "LIST");
sprintf(types[REDIS_SET], "SET");
sprintf(types[REDIS_ZSET], "ZSET");
sprintf(types[REDIS_HASH], "HASH");
/* Object types only used for dumping to disk */
sprintf(types[REDIS_EXPIRETIME], "EXPIRETIME");
sprintf(types[REDIS_SELECTDB], "SELECTDB");
sprintf(types[REDIS_EOF], "EOF");
/* Double constants initialization */
R_Zero = 0.0;
R_PosInf = 1.0/R_Zero;
R_NegInf = -1.0/R_Zero;
R_Nan = R_Zero/R_Zero;
process();
munmap(data, size);
close(fd);
return 0;
}