#include "less.h" #include "xbuf.h" /* * Initialize an expandable text buffer. */ public void xbuf_init(struct xbuffer *xbuf) { xbuf->data = NULL; xbuf->size = xbuf->end = 0; } public void xbuf_deinit(struct xbuffer *xbuf) { if (xbuf->data != NULL) free(xbuf->data); xbuf_init(xbuf); } public void xbuf_reset(struct xbuffer *xbuf) { xbuf->end = 0; } /* * Add a byte to an expandable text buffer. */ public void xbuf_add_byte(struct xbuffer *xbuf, unsigned char b) { if (xbuf->end >= xbuf->size) { unsigned char *data; if (ckd_add(&xbuf->size, xbuf->size, xbuf->size ? xbuf->size : 16)) out_of_memory(); data = (unsigned char *) ecalloc(xbuf->size, sizeof(unsigned char)); if (xbuf->data != NULL) { memcpy(data, xbuf->data, xbuf->end); free(xbuf->data); } xbuf->data = data; } xbuf->data[xbuf->end++] = (unsigned char) b; } public void xbuf_add_data(struct xbuffer *xbuf, unsigned char *data, int len) { int i; for (i = 0; i < len; i++) xbuf_add_byte(xbuf, data[i]); } public int xbuf_pop(struct xbuffer *buf) { if (buf->end == 0) return -1; return (int) buf->data[--(buf->end)]; } public void xbuf_set(struct xbuffer *dst, struct xbuffer *src) { xbuf_reset(dst); xbuf_add_data(dst, src->data, src->end); } public char * xbuf_char_data(struct xbuffer *xbuf) { return (char *)(xbuf->data); } /* * Helper functions for the ckd_add and ckd_mul macro substitutes. * These helper functions do not set *R on overflow, and assume that * arguments are nonnegative, that INTMAX_MAX <= UINTMAX_MAX, and that * sizeof is a reliable way to distinguish integer representations. * Despite these limitations they are good enough for 'less' on all * known practical platforms. For more-complicated substitutes * without most of these limitations, see Gnulib's stdckdint module. */ #if !HAVE_STDCKDINT_H /* * If the integer *R can represent VAL, store the value and return FALSE. * Otherwise, possibly set *R to an indeterminate value and return TRUE. * R has size RSIZE, and is signed if and only if RSIGNED is nonzero. */ static int help_fixup(void *r, uintmax val, int rsize, int rsigned) { if (rsigned) { if (rsize == sizeof (int)) { int *pr = r; if (INT_MAX < val) return TRUE; *pr = (int) val; #ifdef LLONG_MAX } else if (rsize == sizeof (long long)) { long long *pr = r; if (LLONG_MAX < val) return TRUE; *pr = val; #endif #ifdef INTMAX_MAX } else if (rsize == sizeof (intmax_t)) { intmax_t *pr = r; if (INTMAX_MAX < val) return TRUE; *pr = val; #endif } else /* rsize == sizeof (long) */ { long *pr = r; if (LONG_MAX < val) return TRUE; *pr = (long) val; } } else { if (rsize == sizeof (unsigned)) { unsigned *pr = r; if (UINT_MAX < val) return TRUE; *pr = (unsigned) val; } else if (rsize == sizeof (unsigned long)) { unsigned long *pr = r; if (ULONG_MAX < val) return TRUE; *pr = (unsigned long) val; #ifdef ULLONG_MAX } else if (rsize == sizeof (unsigned long long)) { long long *pr = r; if (ULLONG_MAX < val) return TRUE; *pr = val; #endif } else /* rsize == sizeof (uintmax) */ { uintmax *pr = r; *pr = val; } } return FALSE; } /* * If *R can represent the mathematical sum of A and B, store the sum * and return FALSE. Otherwise, possibly set *R to an indeterminate * value and return TRUE. R has size RSIZE, and is signed if and only * if RSIGNED is nonzero. */ public int help_ckd_add(void *r, uintmax a, uintmax b, int rsize, int rsigned) { uintmax sum = a + b; return sum < a || help_fixup(r, sum, rsize, rsigned); } /* Likewise, but for the product of A and B. */ public int help_ckd_mul(void *r, uintmax a, uintmax b, int rsize, int rsigned) { uintmax product = a * b; return ((b != 0 && a != product / b) || help_fixup(r, product, rsize, rsigned)); } #endif