/* SDSLib 2.0 -- A C dynamic strings library * * Copyright (c) 2006-2015, Redis Ltd. * Copyright (c) 2015, Oran Agra * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Redis nor the names of its contributors may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include "serverassert.h" #include "sds.h" #include "sdsalloc.h" #include "util.h" const char *SDS_NOINIT = "SDS_NOINIT"; static inline int sdsHdrSize(char type) { switch (type & SDS_TYPE_MASK) { case SDS_TYPE_5: return sizeof(struct sdshdr5); case SDS_TYPE_8: return sizeof(struct sdshdr8); case SDS_TYPE_16: return sizeof(struct sdshdr16); case SDS_TYPE_32: return sizeof(struct sdshdr32); case SDS_TYPE_64: return sizeof(struct sdshdr64); } return 0; } static inline char sdsReqType(size_t string_size) { if (string_size < 1 << 5) return SDS_TYPE_5; if (string_size <= (1 << 8) - sizeof(struct sdshdr8) - 1) return SDS_TYPE_8; if (string_size <= (1 << 16) - sizeof(struct sdshdr16) - 1) return SDS_TYPE_16; #if (LONG_MAX == LLONG_MAX) if (string_size <= (1ll << 32) - sizeof(struct sdshdr32) - 1) return SDS_TYPE_32; return SDS_TYPE_64; #else return SDS_TYPE_32; #endif } static inline size_t sdsTypeMaxSize(char type) { if (type == SDS_TYPE_5) return (1 << 5) - 1; if (type == SDS_TYPE_8) return (1 << 8) - 1; if (type == SDS_TYPE_16) return (1 << 16) - 1; #if (LONG_MAX == LLONG_MAX) if (type == SDS_TYPE_32) return (1ll << 32) - 1; #endif return -1; /* this is equivalent to the max SDS_TYPE_64 or SDS_TYPE_32 */ } static inline int adjustTypeIfNeeded(char *type, int *hdrlen, size_t bufsize) { size_t usable = bufsize - *hdrlen - 1; if (*type != SDS_TYPE_5 && usable > sdsTypeMaxSize(*type)) { *type = sdsReqType(usable); *hdrlen = sdsHdrSize(*type); return 1; } return 0; } /* Create a new sds string with the content specified by the 'init' pointer * and 'initlen'. * If NULL is used for 'init' the string is initialized with zero bytes. * If SDS_NOINIT is used, the buffer is left uninitialized; * * The string is always null-terminated (all the sds strings are, always) so * even if you create an sds string with: * * mystring = sdsnewlen("abc",3); * * You can print the string with printf() as there is an implicit \0 at the * end of the string. However the string is binary safe and can contain * \0 characters in the middle, as the length is stored in the sds header. */ sds _sdsnewlen(const void *init, size_t initlen, int trymalloc) { void *sh; sds s; char type = sdsReqType(initlen); /* Empty strings are usually created in order to append. Use type 8 * since type 5 is not good at this. */ if (type == SDS_TYPE_5 && initlen == 0) type = SDS_TYPE_8; int hdrlen = sdsHdrSize(type); unsigned char *fp; /* flags pointer. */ size_t bufsize, usable; assert(initlen + hdrlen + 1 > initlen); /* Catch size_t overflow */ sh = trymalloc ? s_trymalloc_usable(hdrlen + initlen + 1, &bufsize) : s_malloc_usable(hdrlen + initlen + 1, &bufsize); if (sh == NULL) return NULL; if (init == SDS_NOINIT) init = NULL; else if (!init) memset(sh, 0, hdrlen + initlen + 1); adjustTypeIfNeeded(&type, &hdrlen, bufsize); usable = bufsize - hdrlen - 1; s = (char *)sh + hdrlen; fp = ((unsigned char *)s) - 1; switch (type) { case SDS_TYPE_5: { *fp = type | (initlen << SDS_TYPE_BITS); break; } case SDS_TYPE_8: { SDS_HDR_VAR(8, s); sh->len = initlen; assert(usable <= sdsTypeMaxSize(type)); sh->alloc = usable; *fp = type; break; } case SDS_TYPE_16: { SDS_HDR_VAR(16, s); sh->len = initlen; assert(usable <= sdsTypeMaxSize(type)); sh->alloc = usable; *fp = type; break; } case SDS_TYPE_32: { SDS_HDR_VAR(32, s); sh->len = initlen; assert(usable <= sdsTypeMaxSize(type)); sh->alloc = usable; *fp = type; break; } case SDS_TYPE_64: { SDS_HDR_VAR(64, s); sh->len = initlen; assert(usable <= sdsTypeMaxSize(type)); sh->alloc = usable; *fp = type; break; } } if (initlen && init) memcpy(s, init, initlen); s[initlen] = '\0'; return s; } sds sdsnewlen(const void *init, size_t initlen) { return _sdsnewlen(init, initlen, 0); } sds sdstrynewlen(const void *init, size_t initlen) { return _sdsnewlen(init, initlen, 1); } /* Create an empty (zero length) sds string. Even in this case the string * always has an implicit null term. */ sds sdsempty(void) { return sdsnewlen("", 0); } /* Create a new sds string starting from a null terminated C string. */ sds sdsnew(const char *init) { size_t initlen = (init == NULL) ? 0 : strlen(init); return sdsnewlen(init, initlen); } /* Duplicate an sds string. */ sds sdsdup(const sds s) { return sdsnewlen(s, sdslen(s)); } /* * This method returns the minimum amount of bytes required to store the sds (header + data + NULL terminator). */ static inline size_t sdsminlen(sds s) { return sdslen(s) + sdsHdrSize(s[-1]) + 1; } /* This method copies the sds `s` into `buf` which is the target character buffer. */ size_t sdscopytobuffer(unsigned char *buf, size_t buf_len, sds s, uint8_t *hdr_size) { size_t required_keylen = sdsminlen(s); if (buf == NULL) { return required_keylen; } assert(buf_len >= required_keylen); memcpy(buf, sdsAllocPtr(s), required_keylen); *hdr_size = sdsHdrSize(s[-1]); return required_keylen; } /* Free an sds string. No operation is performed if 's' is NULL. */ void sdsfree(sds s) { if (s == NULL) return; s_free_with_size(sdsAllocPtr(s), sdsAllocSize(s)); } /* Set the sds string length to the length as obtained with strlen(), so * considering as content only up to the first null term character. * * This function is useful when the sds string is hacked manually in some * way, like in the following example: * * s = sdsnew("foobar"); * s[2] = '\0'; * sdsupdatelen(s); * printf("%d\n", sdslen(s)); * * The output will be "2", but if we comment out the call to sdsupdatelen() * the output will be "6" as the string was modified but the logical length * remains 6 bytes. */ void sdsupdatelen(sds s) { size_t reallen = strlen(s); sdssetlen(s, reallen); } /* Modify an sds string in-place to make it empty (zero length). * However all the existing buffer is not discarded but set as free space * so that next append operations will not require allocations up to the * number of bytes previously available. */ void sdsclear(sds s) { sdssetlen(s, 0); s[0] = '\0'; } /* Enlarge the free space at the end of the sds string so that the caller * is sure that after calling this function can overwrite up to addlen * bytes after the end of the string, plus one more byte for nul term. * If there's already sufficient free space, this function returns without any * action, if there isn't sufficient free space, it'll allocate what's missing, * and possibly more: * When greedy is 1, enlarge more than needed, to avoid need for future reallocs * on incremental growth. * When greedy is 0, enlarge just enough so that there's free space for 'addlen'. * * Note: this does not change the *length* of the sds string as returned * by sdslen(), but only the free buffer space we have. */ sds _sdsMakeRoomFor(sds s, size_t addlen, int greedy) { void *sh, *newsh; size_t avail = sdsavail(s); size_t len, newlen, reqlen; char type, oldtype = s[-1] & SDS_TYPE_MASK; int hdrlen; size_t bufsize, usable; int use_realloc; /* Return ASAP if there is enough space left. */ if (avail >= addlen) return s; len = sdslen(s); sh = (char *)s - sdsHdrSize(oldtype); reqlen = newlen = (len + addlen); assert(newlen > len); /* Catch size_t overflow */ if (greedy == 1) { if (newlen < SDS_MAX_PREALLOC) newlen *= 2; else newlen += SDS_MAX_PREALLOC; } type = sdsReqType(newlen); /* Don't use type 5: the user is appending to the string and type 5 is * not able to remember empty space, so sdsMakeRoomFor() must be called * at every appending operation. */ if (type == SDS_TYPE_5) type = SDS_TYPE_8; hdrlen = sdsHdrSize(type); assert(hdrlen + newlen + 1 > reqlen); /* Catch size_t overflow */ use_realloc = (oldtype == type); if (use_realloc) { newsh = s_realloc_usable(sh, hdrlen + newlen + 1, &bufsize); if (newsh == NULL) return NULL; s = (char *)newsh + hdrlen; if (adjustTypeIfNeeded(&type, &hdrlen, bufsize)) { memmove((char *)newsh + hdrlen, s, len + 1); s = (char *)newsh + hdrlen; s[-1] = type; sdssetlen(s, len); } } else { /* Since the header size changes, need to move the string forward, * and can't use realloc */ newsh = s_malloc_usable(hdrlen + newlen + 1, &bufsize); if (newsh == NULL) return NULL; adjustTypeIfNeeded(&type, &hdrlen, bufsize); memcpy((char *)newsh + hdrlen, s, len + 1); s_free(sh); s = (char *)newsh + hdrlen; s[-1] = type; sdssetlen(s, len); } usable = bufsize - hdrlen - 1; assert(type == SDS_TYPE_5 || usable <= sdsTypeMaxSize(type)); sdssetalloc(s, usable); return s; } /* Enlarge the free space at the end of the sds string more than needed, * This is useful to avoid repeated re-allocations when repeatedly appending to the sds. */ sds sdsMakeRoomFor(sds s, size_t addlen) { return _sdsMakeRoomFor(s, addlen, 1); } /* Unlike sdsMakeRoomFor(), this one just grows to the necessary size. */ sds sdsMakeRoomForNonGreedy(sds s, size_t addlen) { return _sdsMakeRoomFor(s, addlen, 0); } /* Reallocate the sds string so that it has no free space at the end. The * contained string remains not altered, but next concatenation operations * will require a reallocation. * * After the call, the passed sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. */ sds sdsRemoveFreeSpace(sds s, int would_regrow) { return sdsResize(s, sdslen(s), would_regrow); } /* Resize the allocation, this can make the allocation bigger or smaller, * if the size is smaller than currently used len, the data will be truncated. * * The when the would_regrow argument is set to 1, it prevents the use of * SDS_TYPE_5, which is desired when the sds is likely to be changed again. */ sds sdsResize(sds s, size_t size, int would_regrow) { void *sh, *newsh = NULL; char type, oldtype = s[-1] & SDS_TYPE_MASK; int hdrlen, oldhdrlen = sdsHdrSize(oldtype); size_t len = sdslen(s); sh = (char *)s - oldhdrlen; /* Return ASAP if the size is already good. */ if (sdsalloc(s) == size) return s; /* Truncate len if needed. */ if (size < len) len = size; /* Check what would be the minimum SDS header that is just good enough to * fit this string. */ type = sdsReqType(size); if (would_regrow) { /* Don't use type 5, it is not good for strings that are expected to grow back. */ if (type == SDS_TYPE_5) type = SDS_TYPE_8; } hdrlen = sdsHdrSize(type); /* If the type is the same, or can hold the size in it with low overhead * (larger than SDS_TYPE_8), we just realloc(), letting the allocator * to do the copy only if really needed. Otherwise if the change is * huge, we manually reallocate the string to use the different header * type. */ int use_realloc = (oldtype == type || (type < oldtype && type > SDS_TYPE_8)); size_t newlen = use_realloc ? oldhdrlen + size + 1 : hdrlen + size + 1; size_t bufsize = 0; size_t newsize; if (use_realloc) { int alloc_already_optimal = 0; #if defined(USE_JEMALLOC) /* je_nallocx returns the expected allocation size for the newlen. * We aim to avoid calling realloc() when using Jemalloc if there is no * change in the allocation size, as it incurs a cost even if the * allocation size stays the same. */ bufsize = sdsAllocSize(s); alloc_already_optimal = (je_nallocx(newlen, 0) == bufsize); #endif if (!alloc_already_optimal) { newsh = s_realloc_usable(sh, newlen, &bufsize); if (newsh == NULL) return NULL; s = (char *)newsh + oldhdrlen; if (adjustTypeIfNeeded(&oldtype, &oldhdrlen, bufsize)) { memmove((char *)newsh + oldhdrlen, s, len + 1); s = (char *)newsh + oldhdrlen; s[-1] = oldtype; sdssetlen(s, len); } } newsize = bufsize - oldhdrlen - 1; assert(oldtype == SDS_TYPE_5 || newsize <= sdsTypeMaxSize(oldtype)); } else { newsh = s_malloc_usable(newlen, &bufsize); if (newsh == NULL) return NULL; adjustTypeIfNeeded(&type, &hdrlen, bufsize); memcpy((char *)newsh + hdrlen, s, len + 1); s_free(sh); s = (char *)newsh + hdrlen; s[-1] = type; newsize = bufsize - hdrlen - 1; assert(type == SDS_TYPE_5 || newsize <= sdsTypeMaxSize(type)); } s[len] = '\0'; sdssetlen(s, len); sdssetalloc(s, newsize); return s; } /* Return the total size of the allocation of the specified sds string, * including: * 1) The sds header before the pointer. * 2) The string. * 3) The free buffer at the end if any. * 4) The implicit null term. */ size_t sdsAllocSize(sds s) { char type = s[-1] & SDS_TYPE_MASK; /* SDS_TYPE_5 header doesn't contain the size of the allocation */ if (type == SDS_TYPE_5) { return s_malloc_usable_size(sdsAllocPtr(s)); } else { return sdsHdrSize(type) + sdsalloc(s) + 1; } } /* Return the pointer of the actual SDS allocation (normally SDS strings * are referenced by the start of the string buffer). */ void *sdsAllocPtr(sds s) { return (void *)(s - sdsHdrSize(s[-1])); } /* Increment the sds length and decrements the left free space at the * end of the string according to 'incr'. Also set the null term * in the new end of the string. * * This function is used in order to fix the string length after the * user calls sdsMakeRoomFor(), writes something after the end of * the current string, and finally needs to set the new length. * * Note: it is possible to use a negative increment in order to * right-trim the string. * * Usage example: * * Using sdsIncrLen() and sdsMakeRoomFor() it is possible to mount the * following schema, to cat bytes coming from the kernel to the end of an * sds string without copying into an intermediate buffer: * * oldlen = sdslen(s); * s = sdsMakeRoomFor(s, BUFFER_SIZE); * nread = read(fd, s+oldlen, BUFFER_SIZE); * ... check for nread <= 0 and handle it ... * sdsIncrLen(s, nread); */ void sdsIncrLen(sds s, ssize_t incr) { unsigned char flags = s[-1]; size_t len; switch (flags & SDS_TYPE_MASK) { case SDS_TYPE_5: { unsigned char *fp = ((unsigned char *)s) - 1; unsigned char oldlen = SDS_TYPE_5_LEN(flags); assert((incr > 0 && oldlen + incr < 32) || (incr < 0 && oldlen >= (unsigned int)(-incr))); *fp = SDS_TYPE_5 | ((oldlen + incr) << SDS_TYPE_BITS); len = oldlen + incr; break; } case SDS_TYPE_8: { SDS_HDR_VAR(8, s); assert((incr >= 0 && sh->alloc - sh->len >= incr) || (incr < 0 && sh->len >= (unsigned int)(-incr))); len = (sh->len += incr); break; } case SDS_TYPE_16: { SDS_HDR_VAR(16, s); assert((incr >= 0 && sh->alloc - sh->len >= incr) || (incr < 0 && sh->len >= (unsigned int)(-incr))); len = (sh->len += incr); break; } case SDS_TYPE_32: { SDS_HDR_VAR(32, s); assert((incr >= 0 && sh->alloc - sh->len >= (unsigned int)incr) || (incr < 0 && sh->len >= (unsigned int)(-incr))); len = (sh->len += incr); break; } case SDS_TYPE_64: { SDS_HDR_VAR(64, s); assert((incr >= 0 && sh->alloc - sh->len >= (uint64_t)incr) || (incr < 0 && sh->len >= (uint64_t)(-incr))); len = (sh->len += incr); break; } default: len = 0; /* Just to avoid compilation warnings. */ } s[len] = '\0'; } /* Grow the sds to have the specified length. Bytes that were not part of * the original length of the sds will be set to zero. * * if the specified length is smaller than the current length, no operation * is performed. */ sds sdsgrowzero(sds s, size_t len) { size_t curlen = sdslen(s); if (len <= curlen) return s; s = sdsMakeRoomFor(s, len - curlen); if (s == NULL) return NULL; /* Make sure added region doesn't contain garbage */ memset(s + curlen, 0, (len - curlen + 1)); /* also set trailing \0 byte */ sdssetlen(s, len); return s; } /* Append the specified binary-safe string pointed by 't' of 'len' bytes to the * end of the specified sds string 's'. * * After the call, the passed sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. */ sds sdscatlen(sds s, const void *t, size_t len) { size_t curlen = sdslen(s); s = sdsMakeRoomFor(s, len); if (s == NULL) return NULL; memcpy(s + curlen, t, len); sdssetlen(s, curlen + len); s[curlen + len] = '\0'; return s; } /* Append the specified null terminated C string to the sds string 's'. * * After the call, the passed sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. */ sds sdscat(sds s, const char *t) { return sdscatlen(s, t, strlen(t)); } /* Append the specified sds 't' to the existing sds 's'. * * After the call, the modified sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. */ sds sdscatsds(sds s, const sds t) { return sdscatlen(s, t, sdslen(t)); } /* Destructively modify the sds string 's' to hold the specified binary * safe string pointed by 't' of length 'len' bytes. */ sds sdscpylen(sds s, const char *t, size_t len) { if (sdsalloc(s) < len) { s = sdsMakeRoomFor(s, len - sdslen(s)); if (s == NULL) return NULL; } memcpy(s, t, len); s[len] = '\0'; sdssetlen(s, len); return s; } /* Like sdscpylen() but 't' must be a null-terminated string so that the length * of the string is obtained with strlen(). */ sds sdscpy(sds s, const char *t) { return sdscpylen(s, t, strlen(t)); } /* Create an sds string from a long long value. It is much faster than: * * sdscatprintf(sdsempty(),"%lld\n", value); */ sds sdsfromlonglong(long long value) { char buf[LONG_STR_SIZE]; int len = ll2string(buf, sizeof(buf), value); return sdsnewlen(buf, len); } /* Like sdscatprintf() but gets va_list instead of being variadic. */ sds sdscatvprintf(sds s, const char *fmt, va_list ap) { va_list cpy; char staticbuf[1024], *buf = staticbuf, *t; size_t buflen = strlen(fmt) * 2; int bufstrlen; /* We try to start using a static buffer for speed. * If not possible we revert to heap allocation. */ if (buflen > sizeof(staticbuf)) { buf = s_malloc(buflen); if (buf == NULL) return NULL; } else { buflen = sizeof(staticbuf); } /* Alloc enough space for buffer and \0 after failing to * fit the string in the current buffer size. */ while (1) { va_copy(cpy, ap); bufstrlen = vsnprintf(buf, buflen, fmt, cpy); va_end(cpy); if (bufstrlen < 0) { if (buf != staticbuf) s_free(buf); return NULL; } if (((size_t)bufstrlen) >= buflen) { if (buf != staticbuf) s_free(buf); buflen = ((size_t)bufstrlen) + 1; buf = s_malloc(buflen); if (buf == NULL) return NULL; continue; } break; } /* Finally concat the obtained string to the SDS string and return it. */ t = sdscatlen(s, buf, bufstrlen); if (buf != staticbuf) s_free(buf); return t; } /* Append to the sds string 's' a string obtained using printf-alike format * specifier. * * After the call, the modified sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. * * Example: * * s = sdsnew("Sum is: "); * s = sdscatprintf(s,"%d+%d = %d",a,b,a+b). * * Often you need to create a string from scratch with the printf-alike * format. When this is the need, just use sdsempty() as the target string: * * s = sdscatprintf(sdsempty(), "... your format ...", args); */ sds sdscatprintf(sds s, const char *fmt, ...) { va_list ap; char *t; va_start(ap, fmt); t = sdscatvprintf(s, fmt, ap); va_end(ap); return t; } /* This function is similar to sdscatprintf, but much faster as it does * not rely on sprintf() family functions implemented by the libc that * are often very slow. Moreover directly handling the sds string as * new data is concatenated provides a performance improvement. * * However this function only handles an incompatible subset of printf-alike * format specifiers: * * %s - C String * %S - SDS string * %i - signed int * %I - 64 bit signed integer (long long, int64_t) * %u - unsigned int * %U - 64 bit unsigned integer (unsigned long long, uint64_t) * %% - Verbatim "%" character. */ sds sdscatfmt(sds s, char const *fmt, ...) { size_t initlen = sdslen(s); const char *f = fmt; long i; va_list ap; /* To avoid continuous reallocations, let's start with a buffer that * can hold at least two times the format string itself. It's not the * best heuristic but seems to work in practice. */ s = sdsMakeRoomFor(s, strlen(fmt) * 2); va_start(ap, fmt); f = fmt; /* Next format specifier byte to process. */ i = initlen; /* Position of the next byte to write to dest str. */ while (*f) { char next, *str; size_t l; long long num; unsigned long long unum; /* Make sure there is always space for at least 1 char. */ if (sdsavail(s) == 0) { s = sdsMakeRoomFor(s, 1); } switch (*f) { case '%': next = *(f + 1); if (next == '\0') break; f++; switch (next) { case 's': case 'S': str = va_arg(ap, char *); l = (next == 's') ? strlen(str) : sdslen(str); if (sdsavail(s) < l) { s = sdsMakeRoomFor(s, l); } memcpy(s + i, str, l); sdsinclen(s, l); i += l; break; case 'i': case 'I': if (next == 'i') num = va_arg(ap, int); else num = va_arg(ap, long long); { char buf[LONG_STR_SIZE]; l = ll2string(buf, sizeof(buf), num); if (sdsavail(s) < l) { s = sdsMakeRoomFor(s, l); } memcpy(s + i, buf, l); sdsinclen(s, l); i += l; } break; case 'u': case 'U': if (next == 'u') unum = va_arg(ap, unsigned int); else unum = va_arg(ap, unsigned long long); { char buf[LONG_STR_SIZE]; l = ull2string(buf, sizeof(buf), unum); if (sdsavail(s) < l) { s = sdsMakeRoomFor(s, l); } memcpy(s + i, buf, l); sdsinclen(s, l); i += l; } break; default: /* Handle %% and generally %. */ s[i++] = next; sdsinclen(s, 1); break; } break; default: s[i++] = *f; sdsinclen(s, 1); break; } f++; } va_end(ap); /* Add null-term */ s[i] = '\0'; return s; } /* Remove the part of the string from left and from right composed just of * contiguous characters found in 'cset', that is a null terminated C string. * * After the call, the modified sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. * * Example: * * s = sdsnew("AA...AA.a.aa.aHelloWorld :::"); * s = sdstrim(s,"Aa. :"); * printf("%s\n", s); * * Output will be just "HelloWorld". */ sds sdstrim(sds s, const char *cset) { char *end, *sp, *ep; size_t len; sp = s; ep = end = s + sdslen(s) - 1; while (sp <= end && strchr(cset, *sp)) sp++; while (ep > sp && strchr(cset, *ep)) ep--; len = (ep - sp) + 1; if (s != sp) memmove(s, sp, len); s[len] = '\0'; sdssetlen(s, len); return s; } /* Changes the input string to be a subset of the original. * It does not release the free space in the string, so a call to * sdsRemoveFreeSpace may be wise after. */ void sdssubstr(sds s, size_t start, size_t len) { /* Clamp out of range input */ size_t oldlen = sdslen(s); if (start >= oldlen) start = len = 0; if (len > oldlen - start) len = oldlen - start; /* Move the data */ if (len) memmove(s, s + start, len); s[len] = 0; sdssetlen(s, len); } /* Turn the string into a smaller (or equal) string containing only the * substring specified by the 'start' and 'end' indexes. * * start and end can be negative, where -1 means the last character of the * string, -2 the penultimate character, and so forth. * * The interval is inclusive, so the start and end characters will be part * of the resulting string. * * The string is modified in-place. * * NOTE: this function can be misleading and can have unexpected behaviour, * specifically when you want the length of the new string to be 0. * Having start==end will result in a string with one character. * please consider using sdssubstr instead. * * Example: * * s = sdsnew("Hello World"); * sdsrange(s,1,-1); => "ello World" */ void sdsrange(sds s, ssize_t start, ssize_t end) { size_t newlen, len = sdslen(s); if (len == 0) return; if (start < 0) start = len + start; if (end < 0) end = len + end; newlen = (start > end) ? 0 : (end - start) + 1; sdssubstr(s, start, newlen); } /* Apply tolower() to every character of the sds string 's'. */ void sdstolower(sds s) { size_t len = sdslen(s), j; for (j = 0; j < len; j++) s[j] = tolower(s[j]); } /* Apply toupper() to every character of the sds string 's'. */ void sdstoupper(sds s) { size_t len = sdslen(s), j; for (j = 0; j < len; j++) s[j] = toupper(s[j]); } /* Compare two sds strings s1 and s2 with memcmp(). * * Return value: * * positive if s1 > s2. * negative if s1 < s2. * 0 if s1 and s2 are exactly the same binary string. * * If two strings share exactly the same prefix, but one of the two has * additional characters, the longer string is considered to be greater than * the smaller one. */ int sdscmp(const sds s1, const sds s2) { size_t l1, l2, minlen; int cmp; l1 = sdslen(s1); l2 = sdslen(s2); minlen = (l1 < l2) ? l1 : l2; cmp = memcmp(s1, s2, minlen); if (cmp == 0) return l1 > l2 ? 1 : (l1 < l2 ? -1 : 0); return cmp; } /* Split 's' with separator in 'sep'. An array * of sds strings is returned. *count will be set * by reference to the number of tokens returned. * * On out of memory, zero length string, zero length * separator, NULL is returned. * * Note that 'sep' is able to split a string using * a multi-character separator. For example * sdssplit("foo_-_bar","_-_"); will return two * elements "foo" and "bar". * * This version of the function is binary-safe but * requires length arguments. sdssplit() is just the * same function but for zero-terminated strings. */ sds *sdssplitlen(const char *s, ssize_t len, const char *sep, int seplen, int *count) { int elements = 0, slots = 5; long start = 0, j; sds *tokens; if (seplen < 1 || len <= 0) { *count = 0; return NULL; } tokens = s_malloc(sizeof(sds) * slots); if (tokens == NULL) return NULL; for (j = 0; j < (len - (seplen - 1)); j++) { /* make sure there is room for the next element and the final one */ if (slots < elements + 2) { sds *newtokens; slots *= 2; newtokens = s_realloc(tokens, sizeof(sds) * slots); if (newtokens == NULL) goto cleanup; tokens = newtokens; } /* search the separator */ if ((seplen == 1 && *(s + j) == sep[0]) || (memcmp(s + j, sep, seplen) == 0)) { tokens[elements] = sdsnewlen(s + start, j - start); if (tokens[elements] == NULL) goto cleanup; elements++; start = j + seplen; j = j + seplen - 1; /* skip the separator */ } } /* Add the final element. We are sure there is room in the tokens array. */ tokens[elements] = sdsnewlen(s + start, len - start); if (tokens[elements] == NULL) goto cleanup; elements++; *count = elements; return tokens; cleanup: { int i; for (i = 0; i < elements; i++) sdsfree(tokens[i]); s_free(tokens); *count = 0; return NULL; } } /* Free the result returned by sdssplitlen(), or do nothing if 'tokens' is NULL. */ void sdsfreesplitres(sds *tokens, int count) { if (!tokens) return; while (count--) sdsfree(tokens[count]); s_free(tokens); } /* Append to the sds string "s" an escaped string representation where * all the non-printable characters (tested with isprint()) are turned into * escapes in the form "\n\r\a...." or "\x". * * After the call, the modified sds string is no longer valid and all the * references must be substituted with the new pointer returned by the call. */ sds sdscatrepr(sds s, const char *p, size_t len) { s = sdsMakeRoomFor(s, len + 2); s = sdscatlen(s, "\"", 1); while (len--) { switch (*p) { case '\\': case '"': s = sdscatprintf(s, "\\%c", *p); break; case '\n': s = sdscatlen(s, "\\n", 2); break; case '\r': s = sdscatlen(s, "\\r", 2); break; case '\t': s = sdscatlen(s, "\\t", 2); break; case '\a': s = sdscatlen(s, "\\a", 2); break; case '\b': s = sdscatlen(s, "\\b", 2); break; default: if (isprint(*p)) s = sdscatlen(s, p, 1); else s = sdscatprintf(s, "\\x%02x", (unsigned char)*p); break; } p++; } return sdscatlen(s, "\"", 1); } /* Returns one if the string contains characters to be escaped * by sdscatrepr(), zero otherwise. * * Typically, this should be used to help protect aggregated strings in a way * that is compatible with sdssplitargs(). For this reason, also spaces will be * treated as needing an escape. */ int sdsneedsrepr(const sds s) { size_t len = sdslen(s); const char *p = s; while (len--) { if (*p == '\\' || *p == '"' || *p == '\n' || *p == '\r' || *p == '\t' || *p == '\a' || *p == '\b' || !isprint(*p) || isspace(*p)) return 1; p++; } return 0; } /* Helper function for sdssplitargs() that returns non zero if 'c' * is a valid hex digit. */ int is_hex_digit(char c) { return (c >= '0' && c <= '9') || (c >= 'a' && c <= 'f') || (c >= 'A' && c <= 'F'); } /* Helper function for sdssplitargs() that converts a hex digit into an * integer from 0 to 15 */ int hex_digit_to_int(char c) { switch (c) { case '0': return 0; case '1': return 1; case '2': return 2; case '3': return 3; case '4': return 4; case '5': return 5; case '6': return 6; case '7': return 7; case '8': return 8; case '9': return 9; case 'a': case 'A': return 10; case 'b': case 'B': return 11; case 'c': case 'C': return 12; case 'd': case 'D': return 13; case 'e': case 'E': return 14; case 'f': case 'F': return 15; default: return 0; } } /* Split a line into arguments, where every argument can be in the * following programming-language REPL-alike form: * * foo bar "newline are supported\n" and "\xff\x00otherstuff" * * The number of arguments is stored into *argc, and an array * of sds is returned. * * The caller should free the resulting array of sds strings with * sdsfreesplitres(). * * Note that sdscatrepr() is able to convert back a string into * a quoted string in the same format sdssplitargs() is able to parse. * * The function returns the allocated tokens on success, even when the * input string is empty, or NULL if the input contains unbalanced * quotes or closed quotes followed by non space characters * as in: "foo"bar or "foo' */ sds *sdssplitargs(const char *line, int *argc) { const char *p = line; char *current = NULL; char **vector = NULL; *argc = 0; while (1) { /* skip blanks */ while (*p && isspace(*p)) p++; if (*p) { /* get a token */ int inq = 0; /* set to 1 if we are in "quotes" */ int insq = 0; /* set to 1 if we are in 'single quotes' */ int done = 0; if (current == NULL) current = sdsempty(); while (!done) { if (inq) { if (*p == '\\' && *(p + 1) == 'x' && is_hex_digit(*(p + 2)) && is_hex_digit(*(p + 3))) { unsigned char byte; byte = (hex_digit_to_int(*(p + 2)) * 16) + hex_digit_to_int(*(p + 3)); current = sdscatlen(current, (char *)&byte, 1); p += 3; } else if (*p == '\\' && *(p + 1)) { char c; p++; switch (*p) { case 'n': c = '\n'; break; case 'r': c = '\r'; break; case 't': c = '\t'; break; case 'b': c = '\b'; break; case 'a': c = '\a'; break; default: c = *p; break; } current = sdscatlen(current, &c, 1); } else if (*p == '"') { /* closing quote must be followed by a space or * nothing at all. */ if (*(p + 1) && !isspace(*(p + 1))) goto err; done = 1; } else if (!*p) { /* unterminated quotes */ goto err; } else { current = sdscatlen(current, p, 1); } } else if (insq) { if (*p == '\\' && *(p + 1) == '\'') { p++; current = sdscatlen(current, "'", 1); } else if (*p == '\'') { /* closing quote must be followed by a space or * nothing at all. */ if (*(p + 1) && !isspace(*(p + 1))) goto err; done = 1; } else if (!*p) { /* unterminated quotes */ goto err; } else { current = sdscatlen(current, p, 1); } } else { switch (*p) { case ' ': case '\n': case '\r': case '\t': case '\0': done = 1; break; case '"': inq = 1; break; case '\'': insq = 1; break; default: current = sdscatlen(current, p, 1); break; } } if (*p) p++; } /* add the token to the vector */ vector = s_realloc(vector, ((*argc) + 1) * sizeof(char *)); vector[*argc] = current; (*argc)++; current = NULL; } else { /* Even on empty input string return something not NULL. */ if (vector == NULL) vector = s_malloc(sizeof(void *)); return vector; } } err: while ((*argc)--) sdsfree(vector[*argc]); s_free(vector); if (current) sdsfree(current); *argc = 0; return NULL; } /* Modify the string substituting all the occurrences of the set of * characters specified in the 'from' string to the corresponding character * in the 'to' array. * * For instance: sdsmapchars(mystring, "ho", "01", 2) * will have the effect of turning the string "hello" into "0ell1". * * The function returns the sds string pointer, that is always the same * as the input pointer since no resize is needed. */ sds sdsmapchars(sds s, const char *from, const char *to, size_t setlen) { size_t j, i, l = sdslen(s); for (j = 0; j < l; j++) { for (i = 0; i < setlen; i++) { if (s[j] == from[i]) { s[j] = to[i]; break; } } } return s; } /* Join an array of C strings using the specified separator (also a C string). * Returns the result as an sds string. */ sds sdsjoin(char **argv, int argc, char *sep) { sds join = sdsempty(); int j; for (j = 0; j < argc; j++) { join = sdscat(join, argv[j]); if (j != argc - 1) join = sdscat(join, sep); } return join; } /* Like sdsjoin, but joins an array of SDS strings. */ sds sdsjoinsds(sds *argv, int argc, const char *sep, size_t seplen) { sds join = sdsempty(); int j; for (j = 0; j < argc; j++) { join = sdscatsds(join, argv[j]); if (j != argc - 1) join = sdscatlen(join, sep, seplen); } return join; } /* Wrappers to the allocators used by SDS. Note that SDS will actually * just use the macros defined into sdsalloc.h in order to avoid to pay * the overhead of function calls. Here we define these wrappers only for * the programs SDS is linked to, if they want to touch the SDS internals * even if they use a different allocator. */ void *sds_malloc(size_t size) { return s_malloc(size); } void *sds_realloc(void *ptr, size_t size) { return s_realloc(ptr, size); } void sds_free(void *ptr) { s_free(ptr); } /* Perform expansion of a template string and return the result as a newly * allocated sds. * * Template variables are specified using curly brackets, e.g. {variable}. * An opening bracket can be quoted by repeating it twice. */ sds sdstemplate(const char *template, sdstemplate_callback_t cb_func, void *cb_arg) { sds res = sdsempty(); const char *p = template; while (*p) { /* Find next variable, copy everything until there */ const char *sv = strchr(p, '{'); if (!sv) { /* Not found: copy till rest of template and stop */ res = sdscat(res, p); break; } else if (sv > p) { /* Found: copy anything up to the beginning of the variable */ res = sdscatlen(res, p, sv - p); } /* Skip into variable name, handle premature end or quoting */ sv++; if (!*sv) goto error; /* Premature end of template */ if (*sv == '{') { /* Quoted '{' */ p = sv + 1; res = sdscat(res, "{"); continue; } /* Find end of variable name, handle premature end of template */ const char *ev = strchr(sv, '}'); if (!ev) goto error; /* Pass variable name to callback and obtain value. If callback failed, * abort. */ sds varname = sdsnewlen(sv, ev - sv); sds value = cb_func(varname, cb_arg); sdsfree(varname); if (!value) goto error; /* Append value to result and continue */ res = sdscat(res, value); sdsfree(value); p = ev + 1; } return res; error: sdsfree(res); return NULL; }