/*************************************************************************** * _ _ ____ _ * Project ___| | | | _ \| | * / __| | | | |_) | | * | (__| |_| | _ <| |___ * \___|\___/|_| \_\_____| * * Copyright (C) Daniel Stenberg, , et al. * * This software is licensed as described in the file COPYING, which * you should have received as part of this distribution. The terms * are also available at https://curl.se/docs/copyright.html. * * You may opt to use, copy, modify, merge, publish, distribute and/or sell * copies of the Software, and permit persons to whom the Software is * furnished to do so, under the terms of the COPYING file. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * * SPDX-License-Identifier: curl * ***************************************************************************/ #include "curl_setup.h" #include "bufq.h" /* The last 3 #include files should be in this order */ #include "curl_printf.h" #include "curl_memory.h" #include "memdebug.h" static bool chunk_is_empty(const struct buf_chunk *chunk) { return chunk->r_offset >= chunk->w_offset; } static bool chunk_is_full(const struct buf_chunk *chunk) { return chunk->w_offset >= chunk->dlen; } static size_t chunk_len(const struct buf_chunk *chunk) { return chunk->w_offset - chunk->r_offset; } static size_t chunk_space(const struct buf_chunk *chunk) { return chunk->dlen - chunk->w_offset; } static void chunk_reset(struct buf_chunk *chunk) { chunk->next = NULL; chunk->r_offset = chunk->w_offset = 0; } static size_t chunk_append(struct buf_chunk *chunk, const unsigned char *buf, size_t len) { unsigned char *p = &chunk->x.data[chunk->w_offset]; size_t n = chunk->dlen - chunk->w_offset; DEBUGASSERT(chunk->dlen >= chunk->w_offset); if(n) { n = CURLMIN(n, len); memcpy(p, buf, n); chunk->w_offset += n; } return n; } static size_t chunk_read(struct buf_chunk *chunk, unsigned char *buf, size_t len) { unsigned char *p = &chunk->x.data[chunk->r_offset]; size_t n = chunk->w_offset - chunk->r_offset; DEBUGASSERT(chunk->w_offset >= chunk->r_offset); if(!n) { return 0; } else if(n <= len) { memcpy(buf, p, n); chunk->r_offset = chunk->w_offset = 0; return n; } else { memcpy(buf, p, len); chunk->r_offset += len; return len; } } static ssize_t chunk_slurpn(struct buf_chunk *chunk, size_t max_len, Curl_bufq_reader *reader, void *reader_ctx, CURLcode *err) { unsigned char *p = &chunk->x.data[chunk->w_offset]; size_t n = chunk->dlen - chunk->w_offset; /* free amount */ ssize_t nread; DEBUGASSERT(chunk->dlen >= chunk->w_offset); if(!n) { *err = CURLE_AGAIN; return -1; } if(max_len && n > max_len) n = max_len; nread = reader(reader_ctx, p, n, err); if(nread > 0) { DEBUGASSERT((size_t)nread <= n); chunk->w_offset += nread; } return nread; } static void chunk_peek(const struct buf_chunk *chunk, const unsigned char **pbuf, size_t *plen) { DEBUGASSERT(chunk->w_offset >= chunk->r_offset); *pbuf = &chunk->x.data[chunk->r_offset]; *plen = chunk->w_offset - chunk->r_offset; } static void chunk_peek_at(const struct buf_chunk *chunk, size_t offset, const unsigned char **pbuf, size_t *plen) { offset += chunk->r_offset; DEBUGASSERT(chunk->w_offset >= offset); *pbuf = &chunk->x.data[offset]; *plen = chunk->w_offset - offset; } static size_t chunk_skip(struct buf_chunk *chunk, size_t amount) { size_t n = chunk->w_offset - chunk->r_offset; DEBUGASSERT(chunk->w_offset >= chunk->r_offset); if(n) { n = CURLMIN(n, amount); chunk->r_offset += n; if(chunk->r_offset == chunk->w_offset) chunk->r_offset = chunk->w_offset = 0; } return n; } static void chunk_list_free(struct buf_chunk **anchor) { struct buf_chunk *chunk; while(*anchor) { chunk = *anchor; *anchor = chunk->next; free(chunk); } } void Curl_bufcp_init(struct bufc_pool *pool, size_t chunk_size, size_t spare_max) { DEBUGASSERT(chunk_size > 0); DEBUGASSERT(spare_max > 0); memset(pool, 0, sizeof(*pool)); pool->chunk_size = chunk_size; pool->spare_max = spare_max; } static CURLcode bufcp_take(struct bufc_pool *pool, struct buf_chunk **pchunk) { struct buf_chunk *chunk = NULL; if(pool->spare) { chunk = pool->spare; pool->spare = chunk->next; --pool->spare_count; chunk_reset(chunk); *pchunk = chunk; return CURLE_OK; } chunk = calloc(1, sizeof(*chunk) + pool->chunk_size); if(!chunk) { *pchunk = NULL; return CURLE_OUT_OF_MEMORY; } chunk->dlen = pool->chunk_size; *pchunk = chunk; return CURLE_OK; } static void bufcp_put(struct bufc_pool *pool, struct buf_chunk *chunk) { if(pool->spare_count >= pool->spare_max) { free(chunk); } else { chunk_reset(chunk); chunk->next = pool->spare; pool->spare = chunk; ++pool->spare_count; } } void Curl_bufcp_free(struct bufc_pool *pool) { chunk_list_free(&pool->spare); pool->spare_count = 0; } static void bufq_init(struct bufq *q, struct bufc_pool *pool, size_t chunk_size, size_t max_chunks, int opts) { DEBUGASSERT(chunk_size > 0); DEBUGASSERT(max_chunks > 0); memset(q, 0, sizeof(*q)); q->chunk_size = chunk_size; q->max_chunks = max_chunks; q->pool = pool; q->opts = opts; } void Curl_bufq_init2(struct bufq *q, size_t chunk_size, size_t max_chunks, int opts) { bufq_init(q, NULL, chunk_size, max_chunks, opts); } void Curl_bufq_init(struct bufq *q, size_t chunk_size, size_t max_chunks) { bufq_init(q, NULL, chunk_size, max_chunks, BUFQ_OPT_NONE); } void Curl_bufq_initp(struct bufq *q, struct bufc_pool *pool, size_t max_chunks, int opts) { bufq_init(q, pool, pool->chunk_size, max_chunks, opts); } void Curl_bufq_free(struct bufq *q) { chunk_list_free(&q->head); chunk_list_free(&q->spare); q->tail = NULL; q->chunk_count = 0; } void Curl_bufq_reset(struct bufq *q) { struct buf_chunk *chunk; while(q->head) { chunk = q->head; q->head = chunk->next; chunk->next = q->spare; q->spare = chunk; } q->tail = NULL; } size_t Curl_bufq_len(const struct bufq *q) { const struct buf_chunk *chunk = q->head; size_t len = 0; while(chunk) { len += chunk_len(chunk); chunk = chunk->next; } return len; } size_t Curl_bufq_space(const struct bufq *q) { size_t space = 0; if(q->tail) space += chunk_space(q->tail); if(q->spare) { struct buf_chunk *chunk = q->spare; while(chunk) { space += chunk->dlen; chunk = chunk->next; } } if(q->chunk_count < q->max_chunks) { space += (q->max_chunks - q->chunk_count) * q->chunk_size; } return space; } bool Curl_bufq_is_empty(const struct bufq *q) { return !q->head || chunk_is_empty(q->head); } bool Curl_bufq_is_full(const struct bufq *q) { if(!q->tail || q->spare) return FALSE; if(q->chunk_count < q->max_chunks) return FALSE; if(q->chunk_count > q->max_chunks) return TRUE; /* we have no spares and cannot make more, is the tail full? */ return chunk_is_full(q->tail); } static struct buf_chunk *get_spare(struct bufq *q) { struct buf_chunk *chunk = NULL; if(q->spare) { chunk = q->spare; q->spare = chunk->next; chunk_reset(chunk); return chunk; } if(q->chunk_count >= q->max_chunks && (!(q->opts & BUFQ_OPT_SOFT_LIMIT))) return NULL; if(q->pool) { if(bufcp_take(q->pool, &chunk)) return NULL; ++q->chunk_count; return chunk; } else { chunk = calloc(1, sizeof(*chunk) + q->chunk_size); if(!chunk) return NULL; chunk->dlen = q->chunk_size; ++q->chunk_count; return chunk; } } static void prune_head(struct bufq *q) { struct buf_chunk *chunk; while(q->head && chunk_is_empty(q->head)) { chunk = q->head; q->head = chunk->next; if(q->tail == chunk) q->tail = q->head; if(q->pool) { bufcp_put(q->pool, chunk); --q->chunk_count; } else if((q->chunk_count > q->max_chunks) || (q->opts & BUFQ_OPT_NO_SPARES)) { /* SOFT_LIMIT allowed us more than max. free spares until * we are at max again. Or free them if we are configured * to not use spares. */ free(chunk); --q->chunk_count; } else { chunk->next = q->spare; q->spare = chunk; } } } static struct buf_chunk *get_non_full_tail(struct bufq *q) { struct buf_chunk *chunk; if(q->tail && !chunk_is_full(q->tail)) return q->tail; chunk = get_spare(q); if(chunk) { /* new tail, and possibly new head */ if(q->tail) { q->tail->next = chunk; q->tail = chunk; } else { DEBUGASSERT(!q->head); q->head = q->tail = chunk; } } return chunk; } ssize_t Curl_bufq_write(struct bufq *q, const unsigned char *buf, size_t len, CURLcode *err) { struct buf_chunk *tail; ssize_t nwritten = 0; size_t n; DEBUGASSERT(q->max_chunks > 0); while(len) { tail = get_non_full_tail(q); if(!tail) { if((q->chunk_count < q->max_chunks) || (q->opts & BUFQ_OPT_SOFT_LIMIT)) { *err = CURLE_OUT_OF_MEMORY; return -1; } break; } n = chunk_append(tail, buf, len); if(!n) break; nwritten += n; buf += n; len -= n; } if(nwritten == 0 && len) { *err = CURLE_AGAIN; return -1; } *err = CURLE_OK; return nwritten; } CURLcode Curl_bufq_cwrite(struct bufq *q, const char *buf, size_t len, size_t *pnwritten) { ssize_t n; CURLcode result; n = Curl_bufq_write(q, (const unsigned char *)buf, len, &result); *pnwritten = (n < 0)? 0 : (size_t)n; return result; } ssize_t Curl_bufq_read(struct bufq *q, unsigned char *buf, size_t len, CURLcode *err) { ssize_t nread = 0; size_t n; *err = CURLE_OK; while(len && q->head) { n = chunk_read(q->head, buf, len); if(n) { nread += n; buf += n; len -= n; } prune_head(q); } if(nread == 0) { *err = CURLE_AGAIN; return -1; } return nread; } CURLcode Curl_bufq_cread(struct bufq *q, char *buf, size_t len, size_t *pnread) { ssize_t n; CURLcode result; n = Curl_bufq_read(q, (unsigned char *)buf, len, &result); *pnread = (n < 0)? 0 : (size_t)n; return result; } bool Curl_bufq_peek(struct bufq *q, const unsigned char **pbuf, size_t *plen) { if(q->head && chunk_is_empty(q->head)) { prune_head(q); } if(q->head && !chunk_is_empty(q->head)) { chunk_peek(q->head, pbuf, plen); return TRUE; } *pbuf = NULL; *plen = 0; return FALSE; } bool Curl_bufq_peek_at(struct bufq *q, size_t offset, const unsigned char **pbuf, size_t *plen) { struct buf_chunk *c = q->head; size_t clen; while(c) { clen = chunk_len(c); if(!clen) break; if(offset >= clen) { offset -= clen; c = c->next; continue; } chunk_peek_at(c, offset, pbuf, plen); return TRUE; } *pbuf = NULL; *plen = 0; return FALSE; } void Curl_bufq_skip(struct bufq *q, size_t amount) { size_t n; while(amount && q->head) { n = chunk_skip(q->head, amount); amount -= n; prune_head(q); } } ssize_t Curl_bufq_pass(struct bufq *q, Curl_bufq_writer *writer, void *writer_ctx, CURLcode *err) { const unsigned char *buf; size_t blen; ssize_t nwritten = 0; while(Curl_bufq_peek(q, &buf, &blen)) { ssize_t chunk_written; chunk_written = writer(writer_ctx, buf, blen, err); if(chunk_written < 0) { if(!nwritten || *err != CURLE_AGAIN) { /* blocked on first write or real error, fail */ nwritten = -1; } break; } if(!chunk_written) { if(!nwritten) { /* treat as blocked */ *err = CURLE_AGAIN; nwritten = -1; } break; } Curl_bufq_skip(q, (size_t)chunk_written); nwritten += chunk_written; } return nwritten; } ssize_t Curl_bufq_write_pass(struct bufq *q, const unsigned char *buf, size_t len, Curl_bufq_writer *writer, void *writer_ctx, CURLcode *err) { ssize_t nwritten = 0, n; *err = CURLE_OK; while(len) { if(Curl_bufq_is_full(q)) { /* try to make room in case we are full */ n = Curl_bufq_pass(q, writer, writer_ctx, err); if(n < 0) { if(*err != CURLE_AGAIN) { /* real error, fail */ return -1; } /* would block, bufq is full, give up */ break; } } /* Add whatever is remaining now to bufq */ n = Curl_bufq_write(q, buf, len, err); if(n < 0) { if(*err != CURLE_AGAIN) { /* real error, fail */ return -1; } /* no room in bufq */ break; } /* edge case of writer returning 0 (and len is >0) * break or we might enter an infinite loop here */ if(n == 0) break; /* Maybe only part of `data` has been added, continue to loop */ buf += (size_t)n; len -= (size_t)n; nwritten += (size_t)n; } if(!nwritten && len) { *err = CURLE_AGAIN; return -1; } *err = CURLE_OK; return nwritten; } ssize_t Curl_bufq_sipn(struct bufq *q, size_t max_len, Curl_bufq_reader *reader, void *reader_ctx, CURLcode *err) { struct buf_chunk *tail = NULL; ssize_t nread; *err = CURLE_AGAIN; tail = get_non_full_tail(q); if(!tail) { if(q->chunk_count < q->max_chunks) { *err = CURLE_OUT_OF_MEMORY; return -1; } /* full, blocked */ *err = CURLE_AGAIN; return -1; } nread = chunk_slurpn(tail, max_len, reader, reader_ctx, err); if(nread < 0) { return -1; } else if(nread == 0) { /* eof */ *err = CURLE_OK; } return nread; } /** * Read up to `max_len` bytes and append it to the end of the buffer queue. * if `max_len` is 0, no limit is imposed and the call behaves exactly * the same as `Curl_bufq_slurp()`. * Returns the total amount of buf read (may be 0) or -1 on other * reader errors. * Note that even in case of a -1 chunks may have been read and * the buffer queue will have different length than before. */ static ssize_t bufq_slurpn(struct bufq *q, size_t max_len, Curl_bufq_reader *reader, void *reader_ctx, CURLcode *err) { ssize_t nread = 0, n; *err = CURLE_AGAIN; while(1) { n = Curl_bufq_sipn(q, max_len, reader, reader_ctx, err); if(n < 0) { if(!nread || *err != CURLE_AGAIN) { /* blocked on first read or real error, fail */ nread = -1; } else *err = CURLE_OK; break; } else if(n == 0) { /* eof */ *err = CURLE_OK; break; } nread += (size_t)n; if(max_len) { DEBUGASSERT((size_t)n <= max_len); max_len -= (size_t)n; if(!max_len) break; } /* give up slurping when we get less bytes than we asked for */ if(q->tail && !chunk_is_full(q->tail)) break; } return nread; } ssize_t Curl_bufq_slurp(struct bufq *q, Curl_bufq_reader *reader, void *reader_ctx, CURLcode *err) { return bufq_slurpn(q, 0, reader, reader_ctx, err); }