radare2/libr/util/debruijn.c

143 lines
3.9 KiB
C

/* radare - LGPL - Copyright 2014-2016 - crowell, pancake */
#include <r_util.h>
// The following two (commented out) lines are the character set used in peda.
// You may use this charset instead of the A-Za-z0-9 charset normally used.
// char* peda_charset =
// "A%sB$nC-(D;)Ea0Fb1Gc2Hd3Ie4Jf5Kg6Lh7Mi8Nj9OkPlQmRnSoTpUqVrWsXtYuZvwxyz";
//TODO(crowell): Make charset configurable, to allow banning characters.
static const char* debruijn_charset = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz1234567890";
// Generate a De Bruijn sequence.
static void de_bruijn_seq(int prenecklace_len_t, int lyndon_prefix_len_p, int order,
int maxlen, int size, int* prenecklace_a, char* sequence, const char* charset) {
int j;
if (!charset || !sequence || strlen (sequence) == maxlen) {
return;
}
if (prenecklace_len_t > order) {
if (order % lyndon_prefix_len_p == 0) {
for (j = 1; j <= lyndon_prefix_len_p; j++) {
sequence[strlen(sequence)] = charset[prenecklace_a[j]];
if (strlen (sequence) == maxlen) {
return;
}
}
}
} else {
prenecklace_a[prenecklace_len_t] =
prenecklace_a[prenecklace_len_t - lyndon_prefix_len_p];
de_bruijn_seq(prenecklace_len_t + 1, lyndon_prefix_len_p, order, maxlen,
size, prenecklace_a, sequence, charset);
for (j = prenecklace_a[prenecklace_len_t - lyndon_prefix_len_p] + 1;
j < size; j++) {
prenecklace_a[prenecklace_len_t] = j;
de_bruijn_seq (prenecklace_len_t + 1, prenecklace_len_t, order, maxlen,
size, prenecklace_a, sequence, charset);
}
}
}
// Generate a De Bruijn sequence.
// The returned string is malloced, and it is the responsibility of the caller
// to free the memory.
static char* de_bruijn(const char* charset, int order, int maxlen) {
if (!charset) {
return NULL;
}
int size = strlen (charset);
int* prenecklace_a = calloc (size * order, sizeof (int));
if (!prenecklace_a) {
return NULL;
}
char* sequence = calloc (maxlen + 1, sizeof (char));
if (!sequence) {
free (prenecklace_a);
return NULL;
}
de_bruijn_seq (1, 1, order, maxlen, size, prenecklace_a, sequence, charset);
free (prenecklace_a);
return sequence;
}
// Generate a cyclic pattern of desired size, and charset, return with starting
// offset of start.
// The returned string is malloced, and it is the responsibility of the caller
// to free the memory.
R_API char* r_debruijn_pattern(int size, int start, const char* charset) {
char *pat, *pat2;
ut64 len;
if (!charset) {
charset = debruijn_charset;
}
if (start >= size) {
return (char*)NULL;
}
pat = de_bruijn (charset, 3 /*subsequence length*/, size);
if (!pat) {
return NULL;
}
if (start == 0) {
len = strlen (pat);
if (size != len) {
eprintf ("warning: requested pattern of length %d, "
"generated length %"PFMT64d"\n", size, len);
}
return pat;
}
pat2 = calloc ((size - start) + 1, sizeof(char));
if (!pat2) {
free (pat);
return NULL;
}
strncpy (pat2, pat + start, size - start);
pat2[size-start] = 0;
free (pat);
len = strlen (pat2);
if (size != len) {
eprintf ("warning: requested pattern of length %d, "
"generated length %"PFMT64d"\n",
size, len);
}
return pat2;
}
// Finds the offset of a given value in a cyclic pattern of an integer.
R_API int r_debruijn_offset(ut64 value, bool is_big_endian) {
char* needle, *pattern, buf[9];
int retval = -1;
char* pch;
// 0x10000 should be long enough. This is how peda works, and nobody complains
// ... but is slow. Optimize for common case.
int lens[2] = {0x1000, 0x10000};
int j;
if (value == 0) {
return -1;
}
for (j = 0; j < 2 && retval == -1; j++) {
pattern = r_debruijn_pattern (lens[j], 0, debruijn_charset);
buf[8] = '\0';
if (is_big_endian) {
r_write_be64 (buf, value);
} else {
r_write_le64 (buf, value);
}
for (needle = buf; !*needle; needle++) {
/* do nothing here */
}
pch = strstr (pattern, needle);
if (pch) {
retval = (int)(size_t)(pch - pattern);
}
free (pattern);
}
return retval;
}