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Current File : //compat/linux/proc/self/root/usr/src/usr.bin/csup/stream.c |
/*- * Copyright (c) 2003-2006, Maxime Henrion <mux@FreeBSD.org> * 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. * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 AUTHOR 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. * * $FreeBSD: release/9.1.0/usr.bin/csup/stream.c 204556 2010-03-02 07:26:07Z lulf $ */ #include <sys/types.h> #include <sys/stat.h> #include <assert.h> #include <zlib.h> #include <err.h> #include <errno.h> #include <fcntl.h> #include <stdarg.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <unistd.h> #include "misc.h" #include "stream.h" /* * Simple stream API to make my life easier. If the fgetln() and * funopen() functions were standard and if funopen() wasn't using * wrong types for the function pointers, I could have just used * stdio, but life sucks. * * For now, streams are always block-buffered. */ /* * Try to quiet warnings as much as possible with GCC while staying * compatible with other compilers. */ #ifndef __unused #if defined(__GNUC__) && (__GNUC__ > 2 || __GNUC__ == 2 && __GNUC_MINOR__ >= 7) #define __unused __attribute__((__unused__)) #else #define __unused #endif #endif /* * Flags passed to the flush methods. * * STREAM_FLUSH_CLOSING is passed during the last flush call before * closing a stream. This allows the zlib filter to emit the EOF * marker as appropriate. In all other cases, STREAM_FLUSH_NORMAL * should be passed. * * These flags are completely unused in the default flush method, * but they are very important for the flush method of the zlib * filter. */ typedef enum { STREAM_FLUSH_NORMAL, STREAM_FLUSH_CLOSING } stream_flush_t; /* * This is because buf_new() will always allocate size + 1 bytes, * so our buffer sizes will still be power of 2 values. */ #define STREAM_BUFSIZ 1023 struct buf { char *buf; size_t size; size_t in; size_t off; }; struct stream { void *cookie; int fd; int buf; struct buf *rdbuf; struct buf *wrbuf; stream_readfn_t *readfn; stream_writefn_t *writefn; stream_closefn_t *closefn; int eof; struct stream_filter *filter; void *fdata; }; typedef int stream_filter_initfn_t(struct stream *, void *); typedef void stream_filter_finifn_t(struct stream *); typedef int stream_filter_flushfn_t(struct stream *, struct buf *, stream_flush_t); typedef ssize_t stream_filter_fillfn_t(struct stream *, struct buf *); struct stream_filter { stream_filter_t id; stream_filter_initfn_t *initfn; stream_filter_finifn_t *finifn; stream_filter_fillfn_t *fillfn; stream_filter_flushfn_t *flushfn; }; /* Low-level buffer API. */ #define buf_avail(buf) ((buf)->size - (buf)->off - (buf)->in) #define buf_count(buf) ((buf)->in) #define buf_size(buf) ((buf)->size) static void buf_more(struct buf *, size_t); static void buf_less(struct buf *, size_t); static void buf_grow(struct buf *, size_t); /* Internal stream functions. */ static ssize_t stream_fill(struct stream *); static ssize_t stream_fill_default(struct stream *, struct buf *); static int stream_flush_int(struct stream *, stream_flush_t); static int stream_flush_default(struct stream *, struct buf *, stream_flush_t); /* Filters specific functions. */ static struct stream_filter *stream_filter_lookup(stream_filter_t); static int stream_filter_init(struct stream *, void *); static void stream_filter_fini(struct stream *); /* The zlib stream filter declarations. */ #define ZFILTER_EOF 1 /* Got Z_STREAM_END. */ struct zfilter { int flags; struct buf *rdbuf; struct buf *wrbuf; z_stream *rdstate; z_stream *wrstate; }; static int zfilter_init(struct stream *, void *); static void zfilter_fini(struct stream *); static ssize_t zfilter_fill(struct stream *, struct buf *); static int zfilter_flush(struct stream *, struct buf *, stream_flush_t); /* The MD5 stream filter. */ struct md5filter { MD5_CTX ctx; char *md5; char lastc; #define PRINT 1 #define WS 2 #define STRING 3 #define SEEN 4 int state; }; static int md5filter_init(struct stream *, void *); static void md5filter_fini(struct stream *); static ssize_t md5filter_fill(struct stream *, struct buf *); static int md5filter_flush(struct stream *, struct buf *, stream_flush_t); static int md5rcsfilter_flush(struct stream *, struct buf *, stream_flush_t); /* The available stream filters. */ struct stream_filter stream_filters[] = { { STREAM_FILTER_NULL, NULL, NULL, stream_fill_default, stream_flush_default }, { STREAM_FILTER_ZLIB, zfilter_init, zfilter_fini, zfilter_fill, zfilter_flush }, { STREAM_FILTER_MD5, md5filter_init, md5filter_fini, md5filter_fill, md5filter_flush }, { STREAM_FILTER_MD5RCS, md5filter_init, md5filter_fini, md5filter_fill, md5rcsfilter_flush } }; /* Create a new buffer. */ struct buf * buf_new(size_t size) { struct buf *buf; buf = xmalloc(sizeof(struct buf)); /* * We keep one spare byte so that stream_getln() can put a '\0' * there in case the stream doesn't have an ending newline. */ buf->buf = xmalloc(size + 1); memset(buf->buf, 0, size + 1); buf->size = size; buf->in = 0; buf->off = 0; return (buf); } /* * Grow the size of the buffer. If "need" is 0, bump its size to the * next power of 2 value. Otherwise, bump it to the next power of 2 * value bigger than "need". */ static void buf_grow(struct buf *buf, size_t need) { if (need == 0) buf->size = buf->size * 2 + 1; /* Account for the spare byte. */ else { assert(need > buf->size); while (buf->size < need) buf->size = buf->size * 2 + 1; } buf->buf = xrealloc(buf->buf, buf->size + 1); } /* Make more room in the buffer if needed. */ static void buf_prewrite(struct buf *buf) { if (buf_count(buf) == buf_size(buf)) buf_grow(buf, 0); if (buf_count(buf) > 0 && buf_avail(buf) == 0) { memmove(buf->buf, buf->buf + buf->off, buf_count(buf)); buf->off = 0; } } /* Account for "n" bytes being added in the buffer. */ static void buf_more(struct buf *buf, size_t n) { assert(n <= buf_avail(buf)); buf->in += n; } /* Account for "n" bytes having been read in the buffer. */ static void buf_less(struct buf *buf, size_t n) { assert(n <= buf_count(buf)); buf->in -= n; if (buf->in == 0) buf->off = 0; else buf->off += n; } /* Free a buffer. */ void buf_free(struct buf *buf) { free(buf->buf); free(buf); } static struct stream * stream_new(stream_readfn_t *readfn, stream_writefn_t *writefn, stream_closefn_t *closefn) { struct stream *stream; stream = xmalloc(sizeof(struct stream)); if (readfn == NULL && writefn == NULL) { errno = EINVAL; return (NULL); } if (readfn != NULL) stream->rdbuf = buf_new(STREAM_BUFSIZ); else stream->rdbuf = NULL; if (writefn != NULL) stream->wrbuf = buf_new(STREAM_BUFSIZ); else stream->wrbuf = NULL; stream->cookie = NULL; stream->fd = -1; stream->buf = 0; stream->readfn = readfn; stream->writefn = writefn; stream->closefn = closefn; stream->filter = stream_filter_lookup(STREAM_FILTER_NULL); stream->fdata = NULL; stream->eof = 0; return (stream); } /* Create a new stream associated with a void *. */ struct stream * stream_open(void *cookie, stream_readfn_t *readfn, stream_writefn_t *writefn, stream_closefn_t *closefn) { struct stream *stream; stream = stream_new(readfn, writefn, closefn); stream->cookie = cookie; return (stream); } /* Associate a file descriptor with a stream. */ struct stream * stream_open_fd(int fd, stream_readfn_t *readfn, stream_writefn_t *writefn, stream_closefn_t *closefn) { struct stream *stream; stream = stream_new(readfn, writefn, closefn); stream->cookie = &stream->fd; stream->fd = fd; return (stream); } /* Associate a buf with a stream. */ struct stream * stream_open_buf(struct buf *b) { struct stream *stream; stream = stream_new(stream_read_buf, stream_append_buf, stream_close_buf); stream->cookie = b; stream->buf = 1; b->in = 0; return (stream); } /* * Truncate a buffer, just decrease offset pointer. * XXX: this can be dangerous if not used correctly. */ void stream_truncate_buf(struct buf *b, off_t off) { b->off += off; } /* Like open() but returns a stream. */ struct stream * stream_open_file(const char *path, int flags, ...) { struct stream *stream; stream_readfn_t *readfn; stream_writefn_t *writefn; va_list ap; mode_t mode; int fd; va_start(ap, flags); if (flags & O_CREAT) { /* * GCC says I should not be using mode_t here since it's * promoted to an int when passed through `...'. */ mode = va_arg(ap, int); fd = open(path, flags, mode); } else fd = open(path, flags); va_end(ap); if (fd == -1) return (NULL); flags &= O_ACCMODE; if (flags == O_RDONLY) { readfn = stream_read_fd; writefn = NULL; } else if (flags == O_WRONLY) { readfn = NULL; writefn = stream_write_fd; } else if (flags == O_RDWR) { assert(flags == O_RDWR); readfn = stream_read_fd; writefn = stream_write_fd; } else { errno = EINVAL; close(fd); return (NULL); } stream = stream_open_fd(fd, readfn, writefn, stream_close_fd); if (stream == NULL) close(fd); return (stream); } /* Return the file descriptor associated with this stream, or -1. */ int stream_fileno(struct stream *stream) { return (stream->fd); } /* Convenience read function for character buffers. */ ssize_t stream_read_buf(void *cookie, void *buf, size_t size) { struct buf *b; size_t avail; /* Use in to be read offset. */ b = (struct buf *)cookie; /* Just return what we have if the request is to large. */ avail = b->off - b->in; if (avail < size) { memcpy(buf, (b->buf + b->in), avail); b->in += avail; return (avail); } memcpy(buf, (b->buf + b->in), size); b->in += size; return (size); } /* Convenience write function for appending character buffers. */ ssize_t stream_append_buf(void *cookie, const void *buf, size_t size) { struct buf *b; size_t avail; /* Use off to be write offset. */ b = (struct buf *)cookie; avail = b->size - b->off; if (size > avail) buf_grow(b, b->size + size); memcpy((b->buf + b->off), buf, size); b->off += size; b->buf[b->off] = '\0'; return (size); } /* Convenience close function for freeing character buffers. */ int stream_close_buf(void *cookie) { void *data; data = cookie; /* Basically a NOP. */ return (0); } /* Convenience read function for file descriptors. */ ssize_t stream_read_fd(void *cookie, void *buf, size_t size) { ssize_t nbytes; int fd; fd = *(int *)cookie; nbytes = read(fd, buf, size); return (nbytes); } /* Convenience write function for file descriptors. */ ssize_t stream_write_fd(void *cookie, const void *buf, size_t size) { ssize_t nbytes; int fd; fd = *(int *)cookie; nbytes = write(fd, buf, size); return (nbytes); } /* Convenience close function for file descriptors. */ int stream_close_fd(void *cookie) { int fd, ret; fd = *(int *)cookie; ret = close(fd); return (ret); } /* Read some bytes from the stream. */ ssize_t stream_read(struct stream *stream, void *buf, size_t size) { struct buf *rdbuf; ssize_t ret; size_t n; rdbuf = stream->rdbuf; if (buf_count(rdbuf) == 0) { ret = stream_fill(stream); if (ret <= 0) return (-1); } n = min(size, buf_count(rdbuf)); memcpy(buf, rdbuf->buf + rdbuf->off, n); buf_less(rdbuf, n); return (n); } /* A blocking stream_read call. */ ssize_t stream_read_blocking(struct stream *stream, void *buf, size_t size) { struct buf *rdbuf; ssize_t ret; size_t n; rdbuf = stream->rdbuf; while (buf_count(rdbuf) <= size) { ret = stream_fill(stream); if (ret <= 0) return (-1); } /* XXX: Should be at least size bytes in the buffer, right? */ /* Just do this to make sure. */ n = min(size, buf_count(rdbuf)); memcpy(buf, rdbuf->buf + rdbuf->off, n); buf_less(rdbuf, n); return (n); } /* * Read a line from the stream and return a pointer to it. * * If "len" is non-NULL, the length of the string will be put into it. * The pointer is only valid until the next stream API call. The line * can be modified by the caller, provided he doesn't write before or * after it. * * This is somewhat similar to the BSD fgetln() function, except that * "len" can be NULL here. In that case the string is terminated by * overwriting the '\n' character with a NUL character. If it's the * last line in the stream and it has no ending newline, we can still * add '\0' after it, because we keep one spare byte in the buffers. * * However, be warned that one can't handle binary lines properly * without knowing the size of the string since those can contain * NUL characters. */ char * stream_getln(struct stream *stream, size_t *len) { struct buf *buf; char *cp, *line; ssize_t n; size_t done, size; buf = stream->rdbuf; if (buf_count(buf) == 0) { n = stream_fill(stream); if (n <= 0) return (NULL); } cp = memchr(buf->buf + buf->off, '\n', buf_count(buf)); for (done = buf_count(buf); cp == NULL; done += n) { n = stream_fill(stream); if (n < 0) return (NULL); if (n == 0) /* Last line of the stream. */ cp = buf->buf + buf->off + buf->in - 1; else cp = memchr(buf->buf + buf->off + done, '\n', buf_count(buf) - done); } line = buf->buf + buf->off; assert(cp >= line); size = cp - line + 1; buf_less(buf, size); if (len != NULL) { *len = size; } else { /* Terminate the string when len == NULL. */ if (line[size - 1] == '\n') line[size - 1] = '\0'; else line[size] = '\0'; } return (line); } /* Write some bytes to a stream. */ ssize_t stream_write(struct stream *stream, const void *src, size_t nbytes) { struct buf *buf; int error; buf = stream->wrbuf; if (nbytes > buf_size(buf)) buf_grow(buf, nbytes); if (nbytes > buf_avail(buf)) { error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); if (error) return (-1); } memcpy(buf->buf + buf->off + buf->in, src, nbytes); buf_more(buf, nbytes); return (nbytes); } /* Formatted output to a stream. */ int stream_printf(struct stream *stream, const char *fmt, ...) { struct buf *buf; va_list ap; int error, ret; buf = stream->wrbuf; again: va_start(ap, fmt); ret = vsnprintf(buf->buf + buf->off + buf->in, buf_avail(buf), fmt, ap); va_end(ap); if (ret < 0) return (ret); if ((unsigned)ret >= buf_avail(buf)) { if ((unsigned)ret >= buf_size(buf)) buf_grow(buf, ret + 1); if ((unsigned)ret >= buf_avail(buf)) { error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); if (error) return (-1); } goto again; } buf_more(buf, ret); return (ret); } /* Flush the entire write buffer of the stream. */ int stream_flush(struct stream *stream) { int error; error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); return (error); } /* Internal flush API. */ static int stream_flush_int(struct stream *stream, stream_flush_t how) { struct buf *buf; int error; buf = stream->wrbuf; error = (*stream->filter->flushfn)(stream, buf, how); assert(buf_count(buf) == 0); return (error); } /* The default flush method. */ static int stream_flush_default(struct stream *stream, struct buf *buf, stream_flush_t __unused how) { ssize_t n; while (buf_count(buf) > 0) { do { n = (*stream->writefn)(stream->cookie, buf->buf + buf->off, buf_count(buf)); } while (n == -1 && errno == EINTR); if (n <= 0) return (-1); buf_less(buf, n); } return (0); } /* Flush the write buffer and call fsync() on the file descriptor. */ int stream_sync(struct stream *stream) { int error; if (stream->fd == -1) { errno = EINVAL; return (-1); } error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); if (error) return (-1); error = fsync(stream->fd); return (error); } /* Like truncate() but on a stream. */ int stream_truncate(struct stream *stream, off_t size) { int error; if (stream->fd == -1) { errno = EINVAL; return (-1); } error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); if (error) return (-1); error = ftruncate(stream->fd, size); return (error); } /* Like stream_truncate() except the off_t parameter is an offset. */ int stream_truncate_rel(struct stream *stream, off_t off) { struct stat sb; int error; if (stream->buf) { stream_truncate_buf(stream->cookie, off); return (0); } if (stream->fd == -1) { errno = EINVAL; return (-1); } error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); if (error) return (-1); error = fstat(stream->fd, &sb); if (error) return (-1); error = stream_truncate(stream, sb.st_size + off); return (error); } /* Rewind the stream. */ int stream_rewind(struct stream *stream) { int error; if (stream->fd == -1) { errno = EINVAL; return (-1); } if (stream->rdbuf != NULL) buf_less(stream->rdbuf, buf_count(stream->rdbuf)); if (stream->wrbuf != NULL) { error = stream_flush_int(stream, STREAM_FLUSH_NORMAL); if (error) return (error); } error = lseek(stream->fd, 0, SEEK_SET); return (error); } /* Return EOF status. */ int stream_eof(struct stream *stream) { return (stream->eof); } /* Close a stream and free any resources held by it. */ int stream_close(struct stream *stream) { int error; if (stream == NULL) return (0); error = 0; if (stream->wrbuf != NULL) error = stream_flush_int(stream, STREAM_FLUSH_CLOSING); stream_filter_fini(stream); if (stream->closefn != NULL) /* * We might overwrite a previous error from stream_flush(), * but we have no choice, because wether it had worked or * not, we need to close the file descriptor. */ error = (*stream->closefn)(stream->cookie); if (stream->rdbuf != NULL) buf_free(stream->rdbuf); if (stream->wrbuf != NULL) buf_free(stream->wrbuf); free(stream); return (error); } /* The default fill method. */ static ssize_t stream_fill_default(struct stream *stream, struct buf *buf) { ssize_t n; if (stream->eof) return (0); assert(buf_avail(buf) > 0); n = (*stream->readfn)(stream->cookie, buf->buf + buf->off + buf->in, buf_avail(buf)); if (n < 0) return (-1); if (n == 0) { stream->eof = 1; return (0); } buf_more(buf, n); return (n); } /* * Refill the read buffer. This function is not permitted to return * without having made more bytes available, unless there was an error. * Moreover, stream_fill() returns the number of bytes added. */ static ssize_t stream_fill(struct stream *stream) { struct stream_filter *filter; struct buf *buf; #ifndef NDEBUG size_t oldcount; #endif ssize_t n; filter = stream->filter; buf = stream->rdbuf; buf_prewrite(buf); #ifndef NDEBUG oldcount = buf_count(buf); #endif n = (*filter->fillfn)(stream, buf); assert((n > 0 && n == (signed)(buf_count(buf) - oldcount)) || (n <= 0 && buf_count(buf) == oldcount)); return (n); } /* * Lookup a stream filter. * * We are not supposed to get passed an invalid filter id, since * filter ids are an enum type and we don't have invalid filter * ids in the enum :-). Thus, we are not checking for out of * bounds access here. If it happens, it's the caller's fault * anyway. */ static struct stream_filter * stream_filter_lookup(stream_filter_t id) { struct stream_filter *filter; filter = stream_filters; while (filter->id != id) filter++; return (filter); } static int stream_filter_init(struct stream *stream, void *data) { struct stream_filter *filter; int error; filter = stream->filter; if (filter->initfn == NULL) return (0); error = (*filter->initfn)(stream, data); return (error); } static void stream_filter_fini(struct stream *stream) { struct stream_filter *filter; filter = stream->filter; if (filter->finifn != NULL) (*filter->finifn)(stream); } /* * Start a filter on a stream. */ int stream_filter_start(struct stream *stream, stream_filter_t id, void *data) { struct stream_filter *filter; int error; filter = stream->filter; if (id == filter->id) return (0); stream_filter_fini(stream); stream->filter = stream_filter_lookup(id); stream->fdata = NULL; error = stream_filter_init(stream, data); return (error); } /* Stop a filter, this is equivalent to setting the null filter. */ void stream_filter_stop(struct stream *stream) { stream_filter_start(stream, STREAM_FILTER_NULL, NULL); } /* The zlib stream filter implementation. */ /* Take no chances with zlib... */ static void * zfilter_alloc(void __unused *opaque, unsigned int items, unsigned int size) { return (xmalloc(items * size)); } static void zfilter_free(void __unused *opaque, void *ptr) { free(ptr); } static int zfilter_init(struct stream *stream, void __unused *data) { struct zfilter *zf; struct buf *buf; z_stream *state; int rv; zf = xmalloc(sizeof(struct zfilter)); memset(zf, 0, sizeof(struct zfilter)); if (stream->rdbuf != NULL) { state = xmalloc(sizeof(z_stream)); state->zalloc = zfilter_alloc; state->zfree = zfilter_free; state->opaque = Z_NULL; rv = inflateInit(state); if (rv != Z_OK) errx(1, "inflateInit: %s", state->msg); buf = buf_new(buf_size(stream->rdbuf)); zf->rdbuf = stream->rdbuf; stream->rdbuf = buf; zf->rdstate = state; } if (stream->wrbuf != NULL) { state = xmalloc(sizeof(z_stream)); state->zalloc = zfilter_alloc; state->zfree = zfilter_free; state->opaque = Z_NULL; rv = deflateInit(state, Z_DEFAULT_COMPRESSION); if (rv != Z_OK) errx(1, "deflateInit: %s", state->msg); buf = buf_new(buf_size(stream->wrbuf)); zf->wrbuf = stream->wrbuf; stream->wrbuf = buf; zf->wrstate = state; } stream->fdata = zf; return (0); } static void zfilter_fini(struct stream *stream) { struct zfilter *zf; struct buf *zbuf; z_stream *state; ssize_t n; zf = stream->fdata; if (zf->rdbuf != NULL) { state = zf->rdstate; zbuf = zf->rdbuf; /* * Even if it has produced all the bytes, zlib sometimes * hasn't seen the EOF marker, so we need to call inflate() * again to make sure we have eaten all the zlib'ed bytes. */ if ((zf->flags & ZFILTER_EOF) == 0) { n = zfilter_fill(stream, stream->rdbuf); assert(n == 0 && zf->flags & ZFILTER_EOF); } inflateEnd(state); free(state); buf_free(stream->rdbuf); stream->rdbuf = zbuf; } if (zf->wrbuf != NULL) { state = zf->wrstate; zbuf = zf->wrbuf; /* * Compress the remaining bytes in the buffer, if any, * and emit an EOF marker as appropriate. We ignore * the error because we can't do anything about it at * this point, and it can happen if we're getting * disconnected. */ (void)zfilter_flush(stream, stream->wrbuf, STREAM_FLUSH_CLOSING); deflateEnd(state); free(state); buf_free(stream->wrbuf); stream->wrbuf = zbuf; } free(zf); } static int zfilter_flush(struct stream *stream, struct buf *buf, stream_flush_t how) { struct zfilter *zf; struct buf *zbuf; z_stream *state; size_t lastin, lastout, ate, prod; int done, error, flags, rv; zf = stream->fdata; state = zf->wrstate; zbuf = zf->wrbuf; if (how == STREAM_FLUSH_NORMAL) flags = Z_SYNC_FLUSH; else flags = Z_FINISH; done = 0; rv = Z_OK; again: /* * According to zlib.h, we should have at least 6 bytes * available when using deflate() with Z_SYNC_FLUSH. */ if ((buf_avail(zbuf) < 6 && flags == Z_SYNC_FLUSH) || rv == Z_BUF_ERROR || buf_avail(buf) == 0) { error = stream_flush_default(stream, zbuf, how); if (error) return (error); } state->next_in = (Bytef *)(buf->buf + buf->off); state->avail_in = buf_count(buf); state->next_out = (Bytef *)(zbuf->buf + zbuf->off + zbuf->in); state->avail_out = buf_avail(zbuf); lastin = state->avail_in; lastout = state->avail_out; rv = deflate(state, flags); if (rv != Z_BUF_ERROR && rv != Z_OK && rv != Z_STREAM_END) errx(1, "deflate: %s", state->msg); ate = lastin - state->avail_in; prod = lastout - state->avail_out; buf_less(buf, ate); buf_more(zbuf, prod); if ((flags == Z_SYNC_FLUSH && buf_count(buf) > 0) || (flags == Z_FINISH && rv != Z_STREAM_END) || (rv == Z_BUF_ERROR)) goto again; assert(rv == Z_OK || (rv == Z_STREAM_END && flags == Z_FINISH)); error = stream_flush_default(stream, zbuf, how); return (error); } static ssize_t zfilter_fill(struct stream *stream, struct buf *buf) { struct zfilter *zf; struct buf *zbuf; z_stream *state; size_t lastin, lastout, new; ssize_t n; int rv; zf = stream->fdata; state = zf->rdstate; zbuf = zf->rdbuf; assert(buf_avail(buf) > 0); if (buf_count(zbuf) == 0) { n = stream_fill_default(stream, zbuf); if (n <= 0) return (n); } again: assert(buf_count(zbuf) > 0); state->next_in = (Bytef *)(zbuf->buf + zbuf->off); state->avail_in = buf_count(zbuf); state->next_out = (Bytef *)(buf->buf + buf->off + buf->in); state->avail_out = buf_avail(buf); lastin = state->avail_in; lastout = state->avail_out; rv = inflate(state, Z_SYNC_FLUSH); buf_less(zbuf, lastin - state->avail_in); new = lastout - state->avail_out; if (new == 0 && rv != Z_STREAM_END) { n = stream_fill_default(stream, zbuf); if (n == -1) return (-1); if (n == 0) return (0); goto again; } if (rv != Z_STREAM_END && rv != Z_OK) errx(1, "inflate: %s", state->msg); if (rv == Z_STREAM_END) zf->flags |= ZFILTER_EOF; buf_more(buf, new); return (new); } /* The MD5 stream filter implementation. */ static int md5filter_init(struct stream *stream, void *data) { struct md5filter *mf; mf = xmalloc(sizeof(struct md5filter)); MD5_Init(&mf->ctx); mf->md5 = data; mf->lastc = ';'; mf->state = PRINT; stream->fdata = mf; return (0); } static void md5filter_fini(struct stream *stream) { struct md5filter *mf; mf = stream->fdata; MD5_End(mf->md5, &mf->ctx); free(stream->fdata); } static ssize_t md5filter_fill(struct stream *stream, struct buf *buf) { ssize_t n; assert(buf_avail(buf) > 0); n = stream_fill_default(stream, buf); return (n); } static int md5filter_flush(struct stream *stream, struct buf *buf, stream_flush_t how) { struct md5filter *mf; int error; mf = stream->fdata; MD5_Update(&mf->ctx, buf->buf + buf->off, buf->in); error = stream_flush_default(stream, buf, how); return (error); } /* MD5 flush for RCS, where whitespaces are omitted. */ static int md5rcsfilter_flush(struct stream *stream, struct buf *buf, stream_flush_t how) { struct md5filter *mf; char *ptr, *end; char *start; char space[2]; int error; mf = stream->fdata; space[0] = ' '; space[1] = '\0'; ptr = buf->buf + buf->off; end = buf->buf + buf->off + buf->in; #define IS_WS(var) ((var) == ' ' || (var) == '\n' || (var) == '\t' || \ (var) == '\010' || (var) == '\013' || (var) == '\f' || \ (var) == '\r') #define IS_SPECIAL(var) ((var) == '$' || (var) == ',' || (var) == ':' || \ (var) == ';' || (var) == '@') #define IS_PRINT(var) (!IS_WS(var) && (var) != '@') /* XXX: We can do better than this state machine. */ while (ptr < end) { switch (mf->state) { /* Outside RCS statements. */ case PRINT: start = ptr; while (ptr < end && IS_PRINT(*ptr)) { mf->lastc = *ptr; ptr++; } MD5_Update(&mf->ctx, start, (ptr - start)); if (ptr < end) { if (*ptr == '@') { MD5_Update(&mf->ctx, ptr, 1); ptr++; mf->state = STRING; } else { mf->state = WS; } } break; case WS: while (ptr < end && IS_WS(*ptr)) { ptr++; } if (ptr < end) { if (*ptr == '@') { if (mf->lastc == '@') { MD5_Update(&mf->ctx, space, 1); } MD5_Update(&mf->ctx, ptr, 1); ptr++; mf->state = STRING; } else { if (!IS_SPECIAL(*ptr) && !IS_SPECIAL(mf->lastc)) { MD5_Update(&mf->ctx, space, 1); } mf->state = PRINT; } } break; case STRING: start = ptr; while (ptr < end && *ptr != '@') { ptr++; } MD5_Update(&mf->ctx, start, (ptr - start)); if (ptr < end) { MD5_Update(&mf->ctx, ptr, 1); ptr++; mf->state = SEEN; } break; case SEEN: if (*ptr == '@') { MD5_Update(&mf->ctx, ptr, 1); ptr++; mf->state = STRING; } else if(IS_WS(*ptr)) { mf->lastc = '@'; mf->state = WS; } else { mf->state = PRINT; } break; default: err(1, "Invalid state"); break; } } error = stream_flush_default(stream, buf, how); return (error); }