| <!-- | |
| Copyright (C) Daniel Stenberg, <[email protected]>, et al. | |
| SPDX-License-Identifier: curl | |
| --> | |
| # bufq | |
| This is an internal module for managing I/O buffers. A `bufq` can be written | |
| to and read from. It manages read and write positions and has a maximum size. | |
| ## read/write | |
| Its basic read/write functions have a similar signature and return code handling | |
| as many internal Curl read and write ones. | |
| ``` | |
| ssize_t Curl_bufq_write(struct bufq *q, const unsigned char *buf, size_t len, CURLcode *err); | |
| - returns the length written into `q` or -1 on error. | |
| - writing to a full `q` returns -1 and set *err to CURLE_AGAIN | |
| ssize_t Curl_bufq_read(struct bufq *q, unsigned char *buf, size_t len, CURLcode *err); | |
| - returns the length read from `q` or -1 on error. | |
| - reading from an empty `q` returns -1 and set *err to CURLE_AGAIN | |
| ``` | |
| To pass data into a `bufq` without an extra copy, read callbacks can be used. | |
| ``` | |
| typedef ssize_t Curl_bufq_reader(void *reader_ctx, unsigned char *buf, size_t len, | |
| CURLcode *err); | |
| ssize_t Curl_bufq_slurp(struct bufq *q, Curl_bufq_reader *reader, void *reader_ctx, | |
| CURLcode *err); | |
| ``` | |
| `Curl_bufq_slurp()` invokes the given `reader` callback, passing it its own | |
| internal buffer memory to write to. It may invoke the `reader` several times, | |
| as long as it has space and while the `reader` always returns the length that | |
| was requested. There are variations of `slurp` that call the `reader` at most | |
| once or only read in a maximum amount of bytes. | |
| The analog mechanism for write out buffer data is: | |
| ``` | |
| typedef ssize_t Curl_bufq_writer(void *writer_ctx, const unsigned char *buf, size_t len, | |
| CURLcode *err); | |
| ssize_t Curl_bufq_pass(struct bufq *q, Curl_bufq_writer *writer, void *writer_ctx, | |
| CURLcode *err); | |
| ``` | |
| `Curl_bufq_pass()` invokes the `writer`, passing its internal memory and | |
| remove the amount that `writer` reports. | |
| ## peek and skip | |
| It is possible to get access to the memory of data stored in a `bufq` with: | |
| ``` | |
| bool Curl_bufq_peek(const struct bufq *q, const unsigned char **pbuf, size_t *plen); | |
| ``` | |
| On returning TRUE, `pbuf` points to internal memory with `plen` bytes that one | |
| may read. This is only valid until another operation on `bufq` is performed. | |
| Instead of reading `bufq` data, one may simply skip it: | |
| ``` | |
| void Curl_bufq_skip(struct bufq *q, size_t amount); | |
| ``` | |
| This removes `amount` number of bytes from the `bufq`. | |
| ## unwrite | |
| It is possible to undo writes by calling: | |
| ``` | |
| CURLcode Curl_bufq_unwrite(struct bufq *q, size_t len); | |
| ``` | |
| This will remove `len` bytes from the end of the bufq again. When removing | |
| more bytes than are present, CURLE_AGAIN is returned and the bufq will be | |
| empty. | |
| ## lifetime | |
| `bufq` is initialized and freed similar to the `dynbuf` module. Code using | |
| `bufq` holds a `struct bufq` somewhere. Before it uses it, it invokes: | |
| ``` | |
| void Curl_bufq_init(struct bufq *q, size_t chunk_size, size_t max_chunks); | |
| ``` | |
| The `bufq` is told how many "chunks" of data it shall hold at maximum and how | |
| large those "chunks" should be. There are some variants of this, allowing for | |
| more options. How "chunks" are handled in a `bufq` is presented in the section | |
| about memory management. | |
| The user of the `bufq` has the responsibility to call: | |
| ``` | |
| void Curl_bufq_free(struct bufq *q); | |
| ``` | |
| to free all resources held by `q`. It is possible to reset a `bufq` to empty via: | |
| ``` | |
| void Curl_bufq_reset(struct bufq *q); | |
| ``` | |
| ## memory management | |
| Internally, a `bufq` uses allocation of fixed size, e.g. the "chunk_size", up | |
| to a maximum number, e.g. "max_chunks". These chunks are allocated on demand, | |
| therefore writing to a `bufq` may return `CURLE_OUT_OF_MEMORY`. Once the max | |
| number of chunks are used, the `bufq` reports that it is "full". | |
| Each chunks has a `read` and `write` index. A `bufq` keeps its chunks in a | |
| list. Reading happens always at the head chunk, writing always goes to the | |
| tail chunk. When the head chunk becomes empty, it is removed. When the tail | |
| chunk becomes full, another chunk is added to the end of the list, becoming | |
| the new tail. | |
| Chunks that are no longer used are returned to a `spare` list by default. If | |
| the `bufq` is created with option `BUFQ_OPT_NO_SPARES` those chunks are freed | |
| right away. | |
| If a `bufq` is created with a `bufc_pool`, the no longer used chunks are | |
| returned to the pool. Also `bufq` asks the pool for a chunk when it needs one. | |
| More in section "pools". | |
| ## empty, full and overflow | |
| One can ask about the state of a `bufq` with methods such as | |
| `Curl_bufq_is_empty(q)`, `Curl_bufq_is_full(q)`, etc. The amount of data held | |
| by a `bufq` is the sum of the data in all its chunks. This is what is reported | |
| by `Curl_bufq_len(q)`. | |
| Note that a `bufq` length and it being "full" are only loosely related. A | |
| simple example: | |
| * create a `bufq` with chunk_size=1000 and max_chunks=4. | |
| * write 4000 bytes to it, it reports "full" | |
| * read 1 bytes from it, it still reports "full" | |
| * read 999 more bytes from it, and it is no longer "full" | |
| The reason for this is that full really means: *bufq uses max_chunks and the | |
| last one cannot be written to*. | |
| When you read 1 byte from the head chunk in the example above, the head still | |
| hold 999 unread bytes. Only when those are also read, can the head chunk be | |
| removed and a new tail be added. | |
| There is another variation to this. If you initialized a `bufq` with option | |
| `BUFQ_OPT_SOFT_LIMIT`, it allows writes **beyond** the `max_chunks`. It | |
| reports **full**, but one can **still** write. This option is necessary, if | |
| partial writes need to be avoided. It means that you need other checks to keep | |
| the `bufq` from growing ever larger and larger. | |
| ## pools | |
| A `struct bufc_pool` may be used to create chunks for a `bufq` and keep spare | |
| ones around. It is initialized and used via: | |
| ``` | |
| void Curl_bufcp_init(struct bufc_pool *pool, size_t chunk_size, size_t spare_max); | |
| void Curl_bufq_initp(struct bufq *q, struct bufc_pool *pool, size_t max_chunks, int opts); | |
| ``` | |
| The pool gets the size and the mount of spares to keep. The `bufq` gets the | |
| pool and the `max_chunks`. It no longer needs to know the chunk sizes, as | |
| those are managed by the pool. | |
| A pool can be shared between many `bufq`s, as long as all of them operate in | |
| the same thread. In curl that would be true for all transfers using the same | |
| multi handle. The advantages of a pool are: | |
| * when all `bufq`s are empty, only memory for `max_spare` chunks in the pool | |
| is used. Empty `bufq`s holds no memory. | |
| * the latest spare chunk is the first to be handed out again, no matter which | |
| `bufq` needs it. This keeps the footprint of "recently used" memory smaller. | |