liblzma: Add new output queue (lzma_outq) features.
Add lzma_outq_clear_cache2() which may leave one buffer allocated in the cache. Add lzma_outq_outbuf_memusage() to get the memory needed for a single lzma_outbuf. This is now used internally in outqueue.c too. Track both the total amount of memory allocated and the amount of memory that is in active use (not in cache). In lzma_outbuf, allow storing the current input position that matches the current output position. This way the main thread can notice when no more output is possible without first providing more input. Allow specifying return code for lzma_outq_read() in a finished lzma_outbuf.
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@ -34,7 +34,8 @@ lzma_outq_memusage(uint64_t buf_size_max, uint32_t threads)
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if (threads > LZMA_THREADS_MAX || buf_size_max > limit)
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if (threads > LZMA_THREADS_MAX || buf_size_max > limit)
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return UINT64_MAX;
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return UINT64_MAX;
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return GET_BUFS_LIMIT(threads) * (sizeof(lzma_outbuf) + buf_size_max);
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return GET_BUFS_LIMIT(threads)
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* lzma_outq_outbuf_memusage(buf_size_max);
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}
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}
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@ -45,8 +46,6 @@ move_head_to_cache(lzma_outq *outq, const lzma_allocator *allocator)
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assert(outq->tail != NULL);
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assert(outq->tail != NULL);
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assert(outq->bufs_in_use > 0);
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assert(outq->bufs_in_use > 0);
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--outq->bufs_in_use;
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lzma_outbuf *buf = outq->head;
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lzma_outbuf *buf = outq->head;
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outq->head = buf->next;
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outq->head = buf->next;
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if (outq->head == NULL)
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if (outq->head == NULL)
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@ -58,6 +57,9 @@ move_head_to_cache(lzma_outq *outq, const lzma_allocator *allocator)
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buf->next = outq->cache;
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buf->next = outq->cache;
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outq->cache = buf;
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outq->cache = buf;
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--outq->bufs_in_use;
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outq->mem_in_use -= lzma_outq_outbuf_memusage(buf->allocated);
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return;
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return;
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}
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}
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@ -71,7 +73,7 @@ free_one_cached_buffer(lzma_outq *outq, const lzma_allocator *allocator)
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outq->cache = buf->next;
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outq->cache = buf->next;
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--outq->bufs_allocated;
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--outq->bufs_allocated;
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outq->memusage -= sizeof(*buf) + buf->allocated;
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outq->mem_allocated -= lzma_outq_outbuf_memusage(buf->allocated);
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lzma_free(buf, allocator);
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lzma_free(buf, allocator);
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return;
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return;
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@ -88,6 +90,25 @@ lzma_outq_clear_cache(lzma_outq *outq, const lzma_allocator *allocator)
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}
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}
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extern void
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lzma_outq_clear_cache2(lzma_outq *outq, const lzma_allocator *allocator,
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size_t keep_size)
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{
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if (outq->cache == NULL)
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return;
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// Free all but one.
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while (outq->cache->next != NULL)
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free_one_cached_buffer(outq, allocator);
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// Free the last one only if its size doesn't equal to keep_size.
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if (outq->cache->allocated != keep_size)
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free_one_cached_buffer(outq, allocator);
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return;
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}
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extern lzma_ret
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extern lzma_ret
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lzma_outq_init(lzma_outq *outq, const lzma_allocator *allocator,
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lzma_outq_init(lzma_outq *outq, const lzma_allocator *allocator,
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uint32_t threads)
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uint32_t threads)
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@ -139,10 +160,12 @@ lzma_outq_prealloc_buf(lzma_outq *outq, const lzma_allocator *allocator,
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if (size > SIZE_MAX - sizeof(lzma_outbuf))
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if (size > SIZE_MAX - sizeof(lzma_outbuf))
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return LZMA_MEM_ERROR;
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return LZMA_MEM_ERROR;
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const size_t alloc_size = lzma_outq_outbuf_memusage(size);
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// The cache may have buffers but their size is wrong.
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// The cache may have buffers but their size is wrong.
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lzma_outq_clear_cache(outq, allocator);
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lzma_outq_clear_cache(outq, allocator);
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outq->cache = lzma_alloc(sizeof(lzma_outbuf) + size, allocator);
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outq->cache = lzma_alloc(alloc_size, allocator);
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if (outq->cache == NULL)
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if (outq->cache == NULL)
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return LZMA_MEM_ERROR;
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return LZMA_MEM_ERROR;
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@ -150,7 +173,7 @@ lzma_outq_prealloc_buf(lzma_outq *outq, const lzma_allocator *allocator,
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outq->cache->allocated = size;
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outq->cache->allocated = size;
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++outq->bufs_allocated;
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++outq->bufs_allocated;
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outq->memusage += sizeof(lzma_outbuf) + size;
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outq->mem_allocated += alloc_size;
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return LZMA_OK;
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return LZMA_OK;
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}
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}
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@ -180,12 +203,15 @@ lzma_outq_get_buf(lzma_outq *outq, void *worker)
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buf->worker = worker;
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buf->worker = worker;
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buf->finished = false;
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buf->finished = false;
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buf->finish_ret = LZMA_STREAM_END;
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buf->pos = 0;
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buf->pos = 0;
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buf->decoder_in_pos = 0;
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buf->unpadded_size = 0;
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buf->unpadded_size = 0;
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buf->uncompressed_size = 0;
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buf->uncompressed_size = 0;
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++outq->bufs_in_use;
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++outq->bufs_in_use;
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outq->mem_in_use += lzma_outq_outbuf_memusage(buf->allocated);
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return buf;
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return buf;
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}
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}
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@ -234,11 +260,14 @@ lzma_outq_read(lzma_outq *restrict outq,
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if (uncompressed_size != NULL)
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if (uncompressed_size != NULL)
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*uncompressed_size = buf->uncompressed_size;
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*uncompressed_size = buf->uncompressed_size;
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// Remember the return value.
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const lzma_ret finish_ret = buf->finish_ret;
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// Free this buffer for further use.
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// Free this buffer for further use.
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move_head_to_cache(outq, allocator);
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move_head_to_cache(outq, allocator);
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outq->read_pos = 0;
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outq->read_pos = 0;
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return LZMA_STREAM_END;
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return finish_ret;
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}
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}
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@ -36,12 +36,28 @@ struct lzma_outbuf_s {
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/// to this variable needs a mutex.
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/// to this variable needs a mutex.
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size_t pos;
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size_t pos;
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/// Decompression: Position in the input buffer in the worker thread
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/// that matches the output "pos" above. This is used to detect if
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/// more output might be possible from the worker thread: if it has
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/// consumed all its input, then more output isn't possible.
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///
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/// \note This is read by another thread and thus access
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/// to this variable needs a mutex.
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size_t decoder_in_pos;
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/// True when no more data will be written into this buffer.
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/// True when no more data will be written into this buffer.
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///
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///
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/// \note This is read by another thread and thus access
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/// \note This is read by another thread and thus access
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/// to this variable needs a mutex.
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/// to this variable needs a mutex.
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bool finished;
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bool finished;
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/// Return value for lzma_outq_read() when the last byte from
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/// a finished buffer has been read. Defaults to LZMA_STREAM_END.
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/// This must *not* be LZMA_OK. The idea is to allow a decoder to
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/// pass an error code to the main thread, setting the code here
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/// together with finished = true.
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lzma_ret finish_ret;
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/// Additional size information. lzma_outq_read() may read these
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/// Additional size information. lzma_outq_read() may read these
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/// when "finished" is true.
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/// when "finished" is true.
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lzma_vli unpadded_size;
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lzma_vli unpadded_size;
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@ -69,7 +85,11 @@ typedef struct {
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lzma_outbuf *cache;
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lzma_outbuf *cache;
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/// Total amount of memory allocated for buffers
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/// Total amount of memory allocated for buffers
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uint64_t memusage;
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uint64_t mem_allocated;
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/// Amount of memory used by the buffers that are in use in
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/// the head...tail linked list.
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uint64_t mem_in_use;
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/// Number of buffers in use in the head...tail list. If and only if
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/// Number of buffers in use in the head...tail list. If and only if
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/// this is zero, the pointers head and tail above are NULL.
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/// this is zero, the pointers head and tail above are NULL.
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@ -123,6 +143,16 @@ extern void lzma_outq_clear_cache(
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lzma_outq *outq, const lzma_allocator *allocator);
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lzma_outq *outq, const lzma_allocator *allocator);
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/// \brief Like lzma_outq_clear_cache() but might keep one buffer
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///
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/// One buffer is not freed if its size is equal to keep_size.
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/// This is useful if the caller knows that it will soon need a buffer of
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/// keep_size bytes. This way it won't be freed and immediately reallocated.
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extern void lzma_outq_clear_cache2(
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lzma_outq *outq, const lzma_allocator *allocator,
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size_t keep_size);
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/// \brief Preallocate a new buffer into cache
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/// \brief Preallocate a new buffer into cache
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///
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///
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/// Splitting the buffer allocation into a separate function makes it
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/// Splitting the buffer allocation into a separate function makes it
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@ -210,3 +240,15 @@ lzma_outq_is_empty(const lzma_outq *outq)
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{
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{
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return outq->bufs_in_use == 0;
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return outq->bufs_in_use == 0;
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}
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}
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/// \brief Get the amount of memory needed for a single lzma_outbuf
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///
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/// \note Caller must check that the argument is significantly less
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/// than SIZE_MAX to avoid an integer overflow!
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static inline uint64_t
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lzma_outq_outbuf_memusage(size_t buf_size)
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{
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assert(buf_size <= SIZE_MAX - sizeof(lzma_outbuf));
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return sizeof(lzma_outbuf) + buf_size;
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}
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