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xNBA/src/core/buffer.c

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/** @file
*
* Buffer internals.
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*
* A buffer consists of a single, contiguous area of memory, some of
* which is "filled" and the remainder of which is "free". The
* "filled" and "free" spaces are not necessarily contiguous.
*
* When a buffer is initialised via init_buffer(), it consists of a
* single free space. As data is added to the buffer via
* fill_buffer(), this free space decreases and can become fragmented.
*
* Each free block within a buffer starts with a "tail byte". If the
* tail byte is non-zero, this indicates that the free block is the
* tail of the buffer, i.e. occupies all the remaining space up to the
* end of the buffer. When the tail byte is non-zero, it indicates
* that a descriptor (a @c struct @c buffer_free_block) follows the
* tail byte. The descriptor describes the size of the free block and
* the address of the next free block.
*
* We cannot simply always start a free block with a descriptor,
* because it is conceivable that we will, at some point, encounter a
* situation in which the final free block of a buffer is too small to
* contain a descriptor. Consider a protocol with a blocksize of 512
* downloading a 1025-byte file into a 1025-byte buffer. Suppose that
* the first two blocks are received; we have now filled 1024 of the
* 1025 bytes in the buffer, and our only free block consists of the
* 1025th byte. Using a "tail byte" solves this problem.
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*
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*
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* Note that the rather convoluted way of manipulating the buffer
* descriptors (using copy_{to,from}_phys rather than straightforward
* pointers) is needed to cope with operation as a PXE stack, when we
* may be running in real mode or 16-bit protected mode, and therefore
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* cannot directly access arbitrary areas of memory using simple
* pointers.
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*
*/
#include "stddef.h"
#include "string.h"
#include "io.h"
#include "errno.h"
#include "buffer.h"
/**
* Initialise a buffer.
*
* @v buffer The buffer to be initialised
* @ret None
* @err None
*
* Set @c buffer->start and @c buffer->end before calling init_buffer().
* init_buffer() will initialise the buffer to the state of being
* empty.
*
*/
void init_buffer ( struct buffer *buffer ) {
char tail = 1;
buffer->fill = 0;
if ( buffer->end != buffer->start )
copy_to_phys ( buffer->start, &tail, sizeof ( tail ) );
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DBG ( "BUFFER [%x,%x) initialised\n", buffer->start, buffer->end );
}
/**
* Split a free block.
*
* @v desc A descriptor for the free block
* @v block Start address of the block
* @v split Address at which to split the block
* @ret None
* @err None
*
* Split a free block into two separate free blocks. If the split
* point lies outside the block, no action is taken; this is not an
* error.
*
* @b NOTE: It is the reponsibility of the caller to ensure that there
* is enough room in each of the two portions for a free block
* descriptor (a @c struct @c buffer_free_block, except in the case of
* a tail block which requires only a one byte descriptor). If the
* caller fails to do this, data corruption will occur.
*
* In practice, this means that the granularity at which blocks are
* split must be at least @c sizeof(struct @c buffer_free_block).
*
*/
static void split_free_block ( struct buffer_free_block *desc,
physaddr_t block, physaddr_t split ) {
/* If split point is before start of block, do nothing */
if ( split <= block )
return;
/* If split point is after end of block, do nothing */
if ( split >= desc->end )
return;
DBG ( "BUFFER splitting [%x,%x) -> [%x,%x) [%x,%x)\n",
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block, desc->end, block, split, split, desc->end );
/* Create descriptor for new free block */
copy_to_phys ( split, &desc->tail, sizeof ( desc->tail ) );
if ( ! desc->tail )
copy_to_phys ( split, desc, sizeof ( *desc ) );
/* Update descriptor for old free block */
desc->tail = 0;
desc->next_free = split;
desc->end = split;
copy_to_phys ( block, desc, sizeof ( *desc ) );
}
/**
* Mark a free block as used.
*
* @v buffer The buffer containing the block
* @v desc A descriptor for the free block
* @v prev_block Address of the previous block
* @ret None
* @err None
*
* Marks a free block as used, i.e. removes it from the free list.
*
*/
static inline void unfree_block ( struct buffer *buffer,
struct buffer_free_block *desc,
physaddr_t prev_block ) {
struct buffer_free_block prev_desc;
/* If this is the first block, just update buffer->fill */
if ( ! prev_block ) {
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DBG ( "BUFFER marking [%x,%x) as used\n",
buffer->start + buffer->fill, desc->end );
buffer->fill = desc->next_free - buffer->start;
return;
}
/* Get descriptor for previous block (which cannot be a tail block) */
copy_from_phys ( &prev_desc, prev_block, sizeof ( prev_desc ) );
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DBG ( "BUFFER marking [%x,%x) as used\n",
prev_desc.next_free, desc->end );
/* Modify descriptor for previous block and write it back */
prev_desc.next_free = desc->next_free;
copy_to_phys ( prev_block, &prev_desc, sizeof ( prev_desc ) );
}
/**
* Write data into a buffer.
*
* @v buffer The buffer into which to write the data
* @v data The data to be written
* @v offset Offset within the buffer at which to write the data
* @v len Length of data to be written
* @ret True Data was successfully written
* @ret False Data was not written
* @err ENOMEM Buffer is too small to contain the data
*
* Writes a block of data into the buffer. The block need not be
* aligned to any particular boundary, or be of any particular size,
* and it may overlap blocks already in the buffer (i.e. duplicate
* calls to fill_buffer() are explicitly permitted).
*
* @c buffer->fill will be updated to indicate the fill level of the
* buffer, i.e. the offset to the first gap within the buffer. If the
* filesize is known (e.g. as with the SLAM protocol), you can test
* for end-of-file by checking for @c buffer->fill==filesize. If the
* filesize is not known, but there is a well-defined end-of-file test
* (e.g. as with the TFTP protocol), you can read @c buffer->fill to
* determine the final filesize. If blocks are known to be delivered
* in a strictly sequential order with no packet loss or duplication,
* then you can pass in @c offset==buffer->fill.
*
* @b NOTE: It is the caller's responsibility to ensure that the
* boundaries between data blocks are more than @c sizeof(struct @c
* buffer_free_block) apart. If this condition is not satisfied, data
* corruption will occur. (See split_free_block() for details.)
*
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* In practice this is not a problem. Callers of fill_buffer() will
* be download protocols such as TFTP, and very few protocols have a
* block size smaller than @c sizeof(struct @c buffer_free_block).
*
*/
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int fill_buffer ( struct buffer *buffer, const void *data,
off_t offset, size_t len ) {
struct buffer_free_block desc;
physaddr_t block, prev_block;
physaddr_t data_start, data_end;
/* Calculate start and end addresses of data */
data_start = buffer->start + offset;
data_end = data_start + len;
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DBG ( "BUFFER [%x,%x) writing portion [%x,%x)\n",
buffer->start, buffer->end, data_start, data_end );
/* Check buffer bounds */
if ( data_end > buffer->end ) {
DBG ( "BUFFER [%x,%x) too small for data!\n",
buffer->start, buffer->end );
errno = ENOMEM;
return 0;
}
/* Iterate through the buffer's free blocks */
prev_block = 0;
block = buffer->start + buffer->fill;
while ( block < buffer->end ) {
/* Read block descriptor */
desc.next_free = buffer->end;
desc.end = buffer->end;
copy_from_phys ( &desc.tail, block, sizeof ( desc.tail ) );
if ( ! desc.tail )
copy_from_phys ( &desc, block, sizeof ( desc ) );
/* Split block at data start and end markers */
split_free_block ( &desc, block, data_start );
split_free_block ( &desc, block, data_end );
/* Block is now either completely contained by or
* completely outside the data area
*/
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if ( ( block >= data_start ) && ( block < data_end ) ) {
/* Block is within the data area */
unfree_block ( buffer, &desc, prev_block );
copy_to_phys ( block, data + ( block - data_start ),
desc.end - block );
} else {
/* Block is outside the data area */
prev_block = block;
}
/* Move to next free block */
block = desc.next_free;
}
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DBG ( "BUFFER [%x,%x) full up to %x\n",
buffer->start, buffer->end, buffer->start + buffer->fill );
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return 1;
}