/*- * Copyright (c) 2000 Poul-Henning Kamp and Dag-Erling Co•dan Sm¿rgrav * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer * in this position and unchanged. * 2. 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. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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 #ifdef KERNEL /* #include */ #include #include #include #include #include #include #include #else /* KERNEL */ #include #include #include #include #include #endif /* KERNEL */ #include #ifdef KERNEL /* MALLOC_DEFINE(M_SBUF, "sbuf", "string buffers"); */ #define SBMALLOC(size) _MALLOC(size, M_SBUF, M_WAITOK) #define SBFREE(buf) FREE(buf, M_SBUF) #else /* KERNEL */ #define KASSERT(e, m) #define SBMALLOC(size) malloc(size) #define SBFREE(buf) free(buf) #define min(x,y) MIN(x,y) #endif /* KERNEL */ /* * Predicates */ #define SBUF_ISDYNAMIC(s) ((s)->s_flags & SBUF_DYNAMIC) #define SBUF_ISDYNSTRUCT(s) ((s)->s_flags & SBUF_DYNSTRUCT) #define SBUF_ISFINISHED(s) ((s)->s_flags & SBUF_FINISHED) #define SBUF_HASOVERFLOWED(s) ((s)->s_flags & SBUF_OVERFLOWED) #define SBUF_HASROOM(s) ((s)->s_len < (s)->s_size - 1) #define SBUF_FREESPACE(s) ((s)->s_size - (s)->s_len - 1) #define SBUF_CANEXTEND(s) ((s)->s_flags & SBUF_AUTOEXTEND) /* * Set / clear flags */ #define SBUF_SETFLAG(s, f) do { (s)->s_flags |= (f); } while (0) #define SBUF_CLEARFLAG(s, f) do { (s)->s_flags &= ~(f); } while (0) #define SBUF_MINEXTENDSIZE 16 /* Should be power of 2. */ #define SBUF_MAXEXTENDSIZE PAGE_SIZE #define SBUF_MAXEXTENDINCR PAGE_SIZE /* * Debugging support */ #if defined(KERNEL) && defined(INVARIANTS) static void _assert_sbuf_integrity(const char *fun, struct sbuf *s) { KASSERT(s != NULL, ("%s called with a NULL sbuf pointer", fun)); KASSERT(s->s_buf != NULL, ("%s called with uninitialized or corrupt sbuf", fun)); KASSERT(s->s_len < s->s_size, ("wrote past end of sbuf (%d >= %d)", s->s_len, s->s_size)); } static void _assert_sbuf_state(const char *fun, struct sbuf *s, int state) { KASSERT((s->s_flags & SBUF_FINISHED) == state, ("%s called with %sfinished or corrupt sbuf", fun, (state ? "un" : ""))); } #define assert_sbuf_integrity(s) _assert_sbuf_integrity(__func__, (s)) #define assert_sbuf_state(s, i) _assert_sbuf_state(__func__, (s), (i)) #else /* KERNEL && INVARIANTS */ #define assert_sbuf_integrity(s) do { } while (0) #define assert_sbuf_state(s, i) do { } while (0) #endif /* KERNEL && INVARIANTS */ static int sbuf_extendsize(int size) { int newsize; newsize = SBUF_MINEXTENDSIZE; while (newsize < size) { if (newsize < (int)SBUF_MAXEXTENDSIZE) newsize *= 2; else newsize += SBUF_MAXEXTENDINCR; } return (newsize); } /* * Extend an sbuf. */ static int sbuf_extend(struct sbuf *s, int addlen) { char *newbuf; int newsize; if (!SBUF_CANEXTEND(s)) return (-1); newsize = sbuf_extendsize(s->s_size + addlen); newbuf = (char *)SBMALLOC(newsize); if (newbuf == NULL) return (-1); bcopy(s->s_buf, newbuf, s->s_size); if (SBUF_ISDYNAMIC(s)) SBFREE(s->s_buf); else SBUF_SETFLAG(s, SBUF_DYNAMIC); s->s_buf = newbuf; s->s_size = newsize; return (0); } /* * Initialize an sbuf. * If buf is non-NULL, it points to a static or already-allocated string * big enough to hold at least length characters. */ struct sbuf * sbuf_new(struct sbuf *s, char *buf, int length, int flags) { KASSERT(length >= 0, ("attempt to create an sbuf of negative length (%d)", length)); KASSERT((flags & ~SBUF_USRFLAGMSK) == 0, ("%s called with invalid flags", __func__)); flags &= SBUF_USRFLAGMSK; if (s == NULL) { s = (struct sbuf *)SBMALLOC(sizeof *s); if (s == NULL) return (NULL); bzero(s, sizeof *s); s->s_flags = flags; SBUF_SETFLAG(s, SBUF_DYNSTRUCT); } else { bzero(s, sizeof *s); s->s_flags = flags; } s->s_size = length; if (buf) { s->s_buf = buf; return (s); } if (flags & SBUF_AUTOEXTEND) s->s_size = sbuf_extendsize(s->s_size); s->s_buf = (char *)SBMALLOC(s->s_size); if (s->s_buf == NULL) { if (SBUF_ISDYNSTRUCT(s)) SBFREE(s); return (NULL); } SBUF_SETFLAG(s, SBUF_DYNAMIC); return (s); } #ifdef KERNEL /* * Create an sbuf with uio data */ struct sbuf * sbuf_uionew(struct sbuf *s, struct uio *uio, int *error) { KASSERT(uio != NULL, ("%s called with NULL uio pointer", __func__)); KASSERT(error != NULL, ("%s called with NULL error pointer", __func__)); s = sbuf_new(s, NULL, uio_resid(uio) + 1, 0); if (s == NULL) { *error = ENOMEM; return (NULL); } *error = uiomove(s->s_buf, uio_resid(uio), uio); if (*error != 0) { sbuf_delete(s); return (NULL); } s->s_len = s->s_size - 1; *error = 0; return (s); } #endif /* * Clear an sbuf and reset its position. */ void sbuf_clear(struct sbuf *s) { assert_sbuf_integrity(s); /* don't care if it's finished or not */ SBUF_CLEARFLAG(s, SBUF_FINISHED); SBUF_CLEARFLAG(s, SBUF_OVERFLOWED); s->s_len = 0; } /* * Set the sbuf's end position to an arbitrary value. * Effectively truncates the sbuf at the new position. */ int sbuf_setpos(struct sbuf *s, int pos) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); KASSERT(pos >= 0, ("attempt to seek to a negative position (%d)", pos)); KASSERT(pos < s->s_size, ("attempt to seek past end of sbuf (%d >= %d)", pos, s->s_size)); if (pos < 0 || pos > s->s_len) return (-1); s->s_len = pos; return (0); } /* * Append a byte string to an sbuf. */ int sbuf_bcat(struct sbuf *s, const void *buf, size_t len) { const char *str = buf; assert_sbuf_integrity(s); assert_sbuf_state(s, 0); if (SBUF_HASOVERFLOWED(s)) return (-1); for (; len; len--) { if (!SBUF_HASROOM(s) && sbuf_extend(s, len) < 0) break; s->s_buf[s->s_len++] = *str++; } if (len) { SBUF_SETFLAG(s, SBUF_OVERFLOWED); return (-1); } return (0); } #ifdef KERNEL /* * Copy a byte string from userland into an sbuf. */ int sbuf_bcopyin(struct sbuf *s, const void *uaddr, size_t len) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); if (SBUF_HASOVERFLOWED(s)) return (-1); if (len == 0) return (0); if (len > (unsigned) SBUF_FREESPACE(s)) { sbuf_extend(s, len - SBUF_FREESPACE(s)); len = min(len, SBUF_FREESPACE(s)); } if (copyin(CAST_USER_ADDR_T(uaddr), s->s_buf + s->s_len, len) != 0) return (-1); s->s_len += len; return (0); } #endif /* * Copy a byte string into an sbuf. */ int sbuf_bcpy(struct sbuf *s, const void *buf, size_t len) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); sbuf_clear(s); return (sbuf_bcat(s, buf, len)); } /* * Append a string to an sbuf. */ int sbuf_cat(struct sbuf *s, const char *str) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); if (SBUF_HASOVERFLOWED(s)) return (-1); while (*str) { if (!SBUF_HASROOM(s) && sbuf_extend(s, strlen(str)) < 0) break; s->s_buf[s->s_len++] = *str++; } if (*str) { SBUF_SETFLAG(s, SBUF_OVERFLOWED); return (-1); } return (0); } #ifdef KERNEL /* * Append a string from userland to an sbuf. */ int sbuf_copyin(struct sbuf *s, const void *uaddr, size_t len) { size_t done; assert_sbuf_integrity(s); assert_sbuf_state(s, 0); if (SBUF_HASOVERFLOWED(s)) return (-1); if (len == 0) len = SBUF_FREESPACE(s); /* XXX return 0? */ if (len > (unsigned) SBUF_FREESPACE(s)) { sbuf_extend(s, len); len = min(len, SBUF_FREESPACE(s)); } switch (copyinstr(CAST_USER_ADDR_T(uaddr), s->s_buf + s->s_len, len + 1, &done)) { case ENAMETOOLONG: SBUF_SETFLAG(s, SBUF_OVERFLOWED); /* fall through */ case 0: s->s_len += done - 1; break; default: return (-1); /* XXX */ } return (done); } #endif /* * Copy a string into an sbuf. */ int sbuf_cpy(struct sbuf *s, const char *str) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); sbuf_clear(s); return (sbuf_cat(s, str)); } /* * Format the given argument list and append the resulting string to an sbuf. */ int sbuf_vprintf(struct sbuf *s, const char *fmt, va_list ap) { __builtin_va_list ap_copy; /* XXX tduffy - blame on him */ int len; assert_sbuf_integrity(s); assert_sbuf_state(s, 0); KASSERT(fmt != NULL, ("%s called with a NULL format string", __func__)); if (SBUF_HASOVERFLOWED(s)) return (-1); do { va_copy(ap_copy, ap); len = vsnprintf(&s->s_buf[s->s_len], SBUF_FREESPACE(s) + 1, fmt, ap_copy); va_end(ap_copy); } while (len > SBUF_FREESPACE(s) && sbuf_extend(s, len - SBUF_FREESPACE(s)) == 0); /* * s->s_len is the length of the string, without the terminating nul. * When updating s->s_len, we must subtract 1 from the length that * we passed into vsnprintf() because that length includes the * terminating nul. * * vsnprintf() returns the amount that would have been copied, * given sufficient space, hence the min() calculation below. */ s->s_len += min(len, SBUF_FREESPACE(s)); if (!SBUF_HASROOM(s) && !SBUF_CANEXTEND(s)) SBUF_SETFLAG(s, SBUF_OVERFLOWED); KASSERT(s->s_len < s->s_size, ("wrote past end of sbuf (%d >= %d)", s->s_len, s->s_size)); if (SBUF_HASOVERFLOWED(s)) return (-1); return (0); } /* * Format the given arguments and append the resulting string to an sbuf. */ int sbuf_printf(struct sbuf *s, const char *fmt, ...) { va_list ap; int result; va_start(ap, fmt); result = sbuf_vprintf(s, fmt, ap); va_end(ap); return(result); } /* * Append a character to an sbuf. */ int sbuf_putc(struct sbuf *s, int c) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); if (SBUF_HASOVERFLOWED(s)) return (-1); if (!SBUF_HASROOM(s) && sbuf_extend(s, 1) < 0) { SBUF_SETFLAG(s, SBUF_OVERFLOWED); return (-1); } if (c != '\0') s->s_buf[s->s_len++] = c; return (0); } static inline int isspace(char ch) { return (ch == ' ' || ch == '\n' || ch == '\t'); } /* * Trim whitespace characters from end of an sbuf. */ int sbuf_trim(struct sbuf *s) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); if (SBUF_HASOVERFLOWED(s)) return (-1); while (s->s_len && isspace(s->s_buf[s->s_len-1])) --s->s_len; return (0); } /* * Check if an sbuf overflowed */ int sbuf_overflowed(struct sbuf *s) { return SBUF_HASOVERFLOWED(s); } /* * Finish off an sbuf. */ void sbuf_finish(struct sbuf *s) { assert_sbuf_integrity(s); assert_sbuf_state(s, 0); s->s_buf[s->s_len] = '\0'; SBUF_CLEARFLAG(s, SBUF_OVERFLOWED); SBUF_SETFLAG(s, SBUF_FINISHED); } /* * Return a pointer to the sbuf data. */ char * sbuf_data(struct sbuf *s) { assert_sbuf_integrity(s); assert_sbuf_state(s, SBUF_FINISHED); return s->s_buf; } /* * Return the length of the sbuf data. */ int sbuf_len(struct sbuf *s) { assert_sbuf_integrity(s); /* don't care if it's finished or not */ if (SBUF_HASOVERFLOWED(s)) return (-1); return s->s_len; } /* * Clear an sbuf, free its buffer if necessary. */ void sbuf_delete(struct sbuf *s) { int isdyn; assert_sbuf_integrity(s); /* don't care if it's finished or not */ if (SBUF_ISDYNAMIC(s)) SBFREE(s->s_buf); isdyn = SBUF_ISDYNSTRUCT(s); bzero(s, sizeof *s); if (isdyn) SBFREE(s); } /* * Check if an sbuf has been finished. */ int sbuf_done(struct sbuf *s) { return(SBUF_ISFINISHED(s)); }