fs/ntfs3/lib/decompress_common.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-or-later */
 /*
  * decompress_common.h - Code shared by the XPRESS and LZX decompressors
  *
  * Copyright (C) 2015 Eric Biggers
  */

 #ifndef _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H
 #define _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H

 #include <linux/string.h>
 #include <linux/compiler.h>
 #include <linux/types.h>
 #include <linux/slab.h>
 #include <asm/unaligned.h>


 /* "Force inline" macro (not required, but helpful for performance)  */
 #define forceinline __always_inline

 /* Enable whole-word match copying on selected architectures  */
 #if defined(__i386__) || defined(__x86_64__) || defined(__ARM_FEATURE_UNALIGNED)
 #  define FAST_UNALIGNED_ACCESS
 #endif

 /* Size of a machine word  */
 #define WORDBYTES (sizeof(size_t))

 static forceinline void
 copy_unaligned_word(const void *src, void *dst)
 {
 	put_unaligned(get_unaligned((const size_t *)src), (size_t *)dst);
 }


 /* Generate a "word" with platform-dependent size whose bytes all contain the
  * value 'b'.
  */
 static forceinline size_t repeat_byte(u8 b)
 {
 	size_t v;

 	v = b;
 	v |= v << 8;
 	v |= v << 16;
 	v |= v << ((WORDBYTES == 8) ? 32 : 0);
 	return v;
 }

 /* Structure that encapsulates a block of in-memory data being interpreted as a
  * stream of bits, optionally with interwoven literal bytes.  Bits are assumed
  * to be stored in little endian 16-bit coding units, with the bits ordered high
  * to low.
  */
 struct input_bitstream {

 	/* Bits that have been read from the input buffer.  The bits are
 	 * left-justified; the next bit is always bit 31.
 	 */
 	u32 bitbuf;

 	/* Number of bits currently held in @bitbuf.  */
 	u32 bitsleft;

 	/* Pointer to the next byte to be retrieved from the input buffer.  */
 	const u8 *next;

 	/* Pointer to just past the end of the input buffer.  */
 	const u8 *end;
 };

 /* Initialize a bitstream to read from the specified input buffer.  */
 static forceinline void init_input_bitstream(struct input_bitstream *is,
 					     const void *buffer, u32 size)
 {
 	is->bitbuf = 0;
 	is->bitsleft = 0;
 	is->next = buffer;
 	is->end = is->next + size;
 }

 /* Ensure the bit buffer variable for the bitstream contains at least @num_bits
  * bits.  Following this, bitstream_peek_bits() and/or bitstream_remove_bits()
  * may be called on the bitstream to peek or remove up to @num_bits bits.  Note
  * that @num_bits must be <= 16.
  */
 static forceinline void bitstream_ensure_bits(struct input_bitstream *is,
 					      u32 num_bits)
 {
 	if (is->bitsleft < num_bits) {
 		if (is->end - is->next >= 2) {
 			is->bitbuf |= (u32)get_unaligned_le16(is->next)
 					<< (16 - is->bitsleft);
 			is->next += 2;
 		}
 		is->bitsleft += 16;
 	}
 }

 /* Return the next @num_bits bits from the bitstream, without removing them.
  * There must be at least @num_bits remaining in the buffer variable, from a
  * previous call to bitstream_ensure_bits().
  */
 static forceinline u32
 bitstream_peek_bits(const struct input_bitstream *is, const u32 num_bits)
 {
 	return (is->bitbuf >> 1) >> (sizeof(is->bitbuf) * 8 - num_bits - 1);
 }

 /* Remove @num_bits from the bitstream.  There must be at least @num_bits
  * remaining in the buffer variable, from a previous call to
  * bitstream_ensure_bits().
  */
 static forceinline void
 bitstream_remove_bits(struct input_bitstream *is, u32 num_bits)
 {
 	is->bitbuf <<= num_bits;
 	is->bitsleft -= num_bits;
 }

 /* Remove and return @num_bits bits from the bitstream.  There must be at least
  * @num_bits remaining in the buffer variable, from a previous call to
  * bitstream_ensure_bits().
  */
 static forceinline u32
 bitstream_pop_bits(struct input_bitstream *is, u32 num_bits)
 {
 	u32 bits = bitstream_peek_bits(is, num_bits);

 	bitstream_remove_bits(is, num_bits);
 	return bits;
 }

 /* Read and return the next @num_bits bits from the bitstream.  */
 static forceinline u32
 bitstream_read_bits(struct input_bitstream *is, u32 num_bits)
 {
 	bitstream_ensure_bits(is, num_bits);
 	return bitstream_pop_bits(is, num_bits);
 }

 /* Read and return the next literal byte embedded in the bitstream.  */
 static forceinline u8
 bitstream_read_byte(struct input_bitstream *is)
 {
 	if (unlikely(is->end == is->next))
 		return 0;
 	return *is->next++;
 }

 /* Read and return the next 16-bit integer embedded in the bitstream.  */
 static forceinline u16
 bitstream_read_u16(struct input_bitstream *is)
 {
 	u16 v;

 	if (unlikely(is->end - is->next < 2))
 		return 0;
 	v = get_unaligned_le16(is->next);
 	is->next += 2;
 	return v;
 }

 /* Read and return the next 32-bit integer embedded in the bitstream.  */
 static forceinline u32
 bitstream_read_u32(struct input_bitstream *is)
 {
 	u32 v;

 	if (unlikely(is->end - is->next < 4))
 		return 0;
 	v = get_unaligned_le32(is->next);
 	is->next += 4;
 	return v;
 }

 /* Read into @dst_buffer an array of literal bytes embedded in the bitstream.
  * Return either a pointer to the byte past the last written, or NULL if the
  * read overflows the input buffer.
  */
 static forceinline void *bitstream_read_bytes(struct input_bitstream *is,
 					      void *dst_buffer, size_t count)
 {
 	if ((size_t)(is->end - is->next) < count)
 		return NULL;
 	memcpy(dst_buffer, is->next, count);
 	is->next += count;
 	return (u8 *)dst_buffer + count;
 }

 /* Align the input bitstream on a coding-unit boundary.  */
 static forceinline void bitstream_align(struct input_bitstream *is)
 {
 	is->bitsleft = 0;
 	is->bitbuf = 0;
 }

 extern int make_huffman_decode_table(u16 decode_table[], const u32 num_syms,
 				     const u32 num_bits, const u8 lens[],
 				     const u32 max_codeword_len,
 				     u16 working_space[]);


 /* Reads and returns the next Huffman-encoded symbol from a bitstream.  If the
  * input data is exhausted, the Huffman symbol is decoded as if the missing bits
  * are all zeroes.
  */
 static forceinline u32 read_huffsym(struct input_bitstream *istream,
 					 const u16 decode_table[],
 					 u32 table_bits,
 					 u32 max_codeword_len)
 {
 	u32 entry;
 	u32 key_bits;

 	bitstream_ensure_bits(istream, max_codeword_len);

 	/* Index the decode table by the next table_bits bits of the input.  */
 	key_bits = bitstream_peek_bits(istream, table_bits);
 	entry = decode_table[key_bits];
 	if (entry < 0xC000) {
 		/* Fast case: The decode table directly provided the
 		 * symbol and codeword length.  The low 11 bits are the
 		 * symbol, and the high 5 bits are the codeword length.
 		 */
 		bitstream_remove_bits(istream, entry >> 11);
 		return entry & 0x7FF;
 	}
 	/* Slow case: The codeword for the symbol is longer than
 	 * table_bits, so the symbol does not have an entry
 	 * directly in the first (1 << table_bits) entries of the
 	 * decode table.  Traverse the appropriate binary tree
 	 * bit-by-bit to decode the symbol.
 	 */
 	bitstream_remove_bits(istream, table_bits);
 	do {
 		key_bits = (entry & 0x3FFF) + bitstream_pop_bits(istream, 1);
 	} while ((entry = decode_table[key_bits]) >= 0xC000);
 	return entry;
 }

 /*
  * Copy an LZ77 match at (dst - offset) to dst.
  *
  * The length and offset must be already validated --- that is, (dst - offset)
  * can't underrun the output buffer, and (dst + length) can't overrun the output
  * buffer.  Also, the length cannot be 0.
  *
  * @bufend points to the byte past the end of the output buffer.  This function
  * won't write any data beyond this position.
  *
  * Returns dst + length.
  */
 static forceinline u8 *lz_copy(u8 *dst, u32 length, u32 offset, const u8 *bufend,
 			       u32 min_length)
 {
 	const u8 *src = dst - offset;

 	/*
 	 * Try to copy one machine word at a time.  On i386 and x86_64 this is
 	 * faster than copying one byte at a time, unless the data is
 	 * near-random and all the matches have very short lengths.  Note that
 	 * since this requires unaligned memory accesses, it won't necessarily
 	 * be faster on every architecture.
 	 *
 	 * Also note that we might copy more than the length of the match.  For
 	 * example, if a word is 8 bytes and the match is of length 5, then
 	 * we'll simply copy 8 bytes.  This is okay as long as we don't write
 	 * beyond the end of the output buffer, hence the check for (bufend -
 	 * end >= WORDBYTES - 1).
 	 */
 #ifdef FAST_UNALIGNED_ACCESS
 	u8 * const end = dst + length;

 	if (bufend - end >= (ptrdiff_t)(WORDBYTES - 1)) {

 		if (offset >= WORDBYTES) {
 			/* The source and destination words don't overlap.  */

 			/* To improve branch prediction, one iteration of this
 			 * loop is unrolled.  Most matches are short and will
 			 * fail the first check.  But if that check passes, then
 			 * it becomes increasing likely that the match is long
 			 * and we'll need to continue copying.
 			 */

 			copy_unaligned_word(src, dst);
 			src += WORDBYTES;
 			dst += WORDBYTES;

 			if (dst < end) {
 				do {
 					copy_unaligned_word(src, dst);
 					src += WORDBYTES;
 					dst += WORDBYTES;
 				} while (dst < end);
 			}
 			return end;
 		} else if (offset == 1) {

 			/* Offset 1 matches are equivalent to run-length
 			 * encoding of the previous byte.  This case is common
 			 * if the data contains many repeated bytes.
 			 */
 			size_t v = repeat_byte(*(dst - 1));

 			do {
 				put_unaligned(v, (size_t *)dst);
 				src += WORDBYTES;
 				dst += WORDBYTES;
 			} while (dst < end);
 			return end;
 		}
 		/*
 		 * We don't bother with special cases for other 'offset <
 		 * WORDBYTES', which are usually rarer than 'offset == 1'.  Extra
 		 * checks will just slow things down.  Actually, it's possible
 		 * to handle all the 'offset < WORDBYTES' cases using the same
 		 * code, but it still becomes more complicated doesn't seem any
 		 * faster overall; it definitely slows down the more common
 		 * 'offset == 1' case.
 		 */
 	}
 #endif /* FAST_UNALIGNED_ACCESS */

 	/* Fall back to a bytewise copy.  */

 	if (min_length >= 2) {
 		*dst++ = *src++;
 		length--;
 	}
 	if (min_length >= 3) {
 		*dst++ = *src++;
 		length--;
 	}
 	do {
 		*dst++ = *src++;
 	} while (--length);

 	return dst;
 }

 #endif /* _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H */
	/* SPDX-License-Identifier: GPL-2.0-or-later */
	/*
	* decompress_common.h - Code shared by the XPRESS and LZX decompressors
	*
	* Copyright (C) 2015 Eric Biggers
	*/

	#ifndef _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H
	#define _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H

	#include <linux/string.h>
	#include <linux/compiler.h>
	#include <linux/types.h>
	#include <linux/slab.h>
	#include <asm/unaligned.h>


	/* "Force inline" macro (not required, but helpful for performance) */
	#define forceinline __always_inline

	/* Enable whole-word match copying on selected architectures */
	#if defined(__i386__) \|\| defined(__x86_64__) \|\| defined(__ARM_FEATURE_UNALIGNED)
	# define FAST_UNALIGNED_ACCESS
	#endif

	/* Size of a machine word */
	#define WORDBYTES (sizeof(size_t))

	static forceinline void
	copy_unaligned_word(const void src, void dst)
	{
	put_unaligned(get_unaligned((const size_t )src), (size_t )dst);
	}


	/* Generate a "word" with platform-dependent size whose bytes all contain the
	* value 'b'.
	*/
	static forceinline size_t repeat_byte(u8 b)
	{
	size_t v;

	v = b;
	v \|= v << 8;
	v \|= v << 16;
	v \|= v << ((WORDBYTES == 8) ? 32 : 0);
	return v;
	}

	/* Structure that encapsulates a block of in-memory data being interpreted as a
	* stream of bits, optionally with interwoven literal bytes. Bits are assumed
	* to be stored in little endian 16-bit coding units, with the bits ordered high
	* to low.
	*/
	struct input_bitstream {

	/* Bits that have been read from the input buffer. The bits are
	* left-justified; the next bit is always bit 31.
	*/
	u32 bitbuf;

	/* Number of bits currently held in @bitbuf. */
	u32 bitsleft;

	/* Pointer to the next byte to be retrieved from the input buffer. */
	const u8 *next;

	/* Pointer to just past the end of the input buffer. */
	const u8 *end;
	};

	/* Initialize a bitstream to read from the specified input buffer. */
	static forceinline void init_input_bitstream(struct input_bitstream *is,
	const void *buffer, u32 size)
	{
	is->bitbuf = 0;
	is->bitsleft = 0;
	is->next = buffer;
	is->end = is->next + size;
	}

	/* Ensure the bit buffer variable for the bitstream contains at least @num_bits
	* bits. Following this, bitstream_peek_bits() and/or bitstream_remove_bits()
	* may be called on the bitstream to peek or remove up to @num_bits bits. Note
	* that @num_bits must be <= 16.
	*/
	static forceinline void bitstream_ensure_bits(struct input_bitstream *is,
	u32 num_bits)
	{
	if (is->bitsleft < num_bits) {
	if (is->end - is->next >= 2) {
	is->bitbuf \|= (u32)get_unaligned_le16(is->next)
	<< (16 - is->bitsleft);
	is->next += 2;
	}
	is->bitsleft += 16;
	}
	}

	/* Return the next @num_bits bits from the bitstream, without removing them.
	* There must be at least @num_bits remaining in the buffer variable, from a
	* previous call to bitstream_ensure_bits().
	*/
	static forceinline u32
	bitstream_peek_bits(const struct input_bitstream *is, const u32 num_bits)
	{
	return (is->bitbuf >> 1) >> (sizeof(is->bitbuf) * 8 - num_bits - 1);
	}

	/* Remove @num_bits from the bitstream. There must be at least @num_bits
	* remaining in the buffer variable, from a previous call to
	* bitstream_ensure_bits().
	*/
	static forceinline void
	bitstream_remove_bits(struct input_bitstream *is, u32 num_bits)
	{
	is->bitbuf <<= num_bits;
	is->bitsleft -= num_bits;
	}

	/* Remove and return @num_bits bits from the bitstream. There must be at least
	* @num_bits remaining in the buffer variable, from a previous call to
	* bitstream_ensure_bits().
	*/
	static forceinline u32
	bitstream_pop_bits(struct input_bitstream *is, u32 num_bits)
	{
	u32 bits = bitstream_peek_bits(is, num_bits);

	bitstream_remove_bits(is, num_bits);
	return bits;
	}

	/* Read and return the next @num_bits bits from the bitstream. */
	static forceinline u32
	bitstream_read_bits(struct input_bitstream *is, u32 num_bits)
	{
	bitstream_ensure_bits(is, num_bits);
	return bitstream_pop_bits(is, num_bits);
	}

	/* Read and return the next literal byte embedded in the bitstream. */
	static forceinline u8
	bitstream_read_byte(struct input_bitstream *is)
	{
	if (unlikely(is->end == is->next))
	return 0;
	return *is->next++;
	}

	/* Read and return the next 16-bit integer embedded in the bitstream. */
	static forceinline u16
	bitstream_read_u16(struct input_bitstream *is)
	{
	u16 v;

	if (unlikely(is->end - is->next < 2))
	return 0;
	v = get_unaligned_le16(is->next);
	is->next += 2;
	return v;
	}

	/* Read and return the next 32-bit integer embedded in the bitstream. */
	static forceinline u32
	bitstream_read_u32(struct input_bitstream *is)
	{
	u32 v;

	if (unlikely(is->end - is->next < 4))
	return 0;
	v = get_unaligned_le32(is->next);
	is->next += 4;
	return v;
	}

	/* Read into @dst_buffer an array of literal bytes embedded in the bitstream.
	* Return either a pointer to the byte past the last written, or NULL if the
	* read overflows the input buffer.
	*/
	static forceinline void bitstream_read_bytes(struct input_bitstream is,
	void *dst_buffer, size_t count)
	{
	if ((size_t)(is->end - is->next) < count)
	return NULL;
	memcpy(dst_buffer, is->next, count);
	is->next += count;
	return (u8 *)dst_buffer + count;
	}

	/* Align the input bitstream on a coding-unit boundary. */
	static forceinline void bitstream_align(struct input_bitstream *is)
	{
	is->bitsleft = 0;
	is->bitbuf = 0;
	}

	extern int make_huffman_decode_table(u16 decode_table[], const u32 num_syms,
	const u32 num_bits, const u8 lens[],
	const u32 max_codeword_len,
	u16 working_space[]);


	/* Reads and returns the next Huffman-encoded symbol from a bitstream. If the
	* input data is exhausted, the Huffman symbol is decoded as if the missing bits
	* are all zeroes.
	*/
	static forceinline u32 read_huffsym(struct input_bitstream *istream,
	const u16 decode_table[],
	u32 table_bits,
	u32 max_codeword_len)
	{
	u32 entry;
	u32 key_bits;

	bitstream_ensure_bits(istream, max_codeword_len);

	/* Index the decode table by the next table_bits bits of the input. */
	key_bits = bitstream_peek_bits(istream, table_bits);
	entry = decode_table[key_bits];
	if (entry < 0xC000) {
	/* Fast case: The decode table directly provided the
	* symbol and codeword length. The low 11 bits are the
	* symbol, and the high 5 bits are the codeword length.
	*/
	bitstream_remove_bits(istream, entry >> 11);
	return entry & 0x7FF;
	}
	/* Slow case: The codeword for the symbol is longer than
	* table_bits, so the symbol does not have an entry
	* directly in the first (1 << table_bits) entries of the
	* decode table. Traverse the appropriate binary tree
	* bit-by-bit to decode the symbol.
	*/
	bitstream_remove_bits(istream, table_bits);
	do {
	key_bits = (entry & 0x3FFF) + bitstream_pop_bits(istream, 1);
	} while ((entry = decode_table[key_bits]) >= 0xC000);
	return entry;
	}

	/*
	* Copy an LZ77 match at (dst - offset) to dst.
	*
	* The length and offset must be already validated --- that is, (dst - offset)
	* can't underrun the output buffer, and (dst + length) can't overrun the output
	* buffer. Also, the length cannot be 0.
	*
	* @bufend points to the byte past the end of the output buffer. This function
	* won't write any data beyond this position.
	*
	* Returns dst + length.
	*/
	static forceinline u8 lz_copy(u8 dst, u32 length, u32 offset, const u8 *bufend,
	u32 min_length)
	{
	const u8 *src = dst - offset;

	/*
	* Try to copy one machine word at a time. On i386 and x86_64 this is
	* faster than copying one byte at a time, unless the data is
	* near-random and all the matches have very short lengths. Note that
	* since this requires unaligned memory accesses, it won't necessarily
	* be faster on every architecture.
	*
	* Also note that we might copy more than the length of the match. For
	* example, if a word is 8 bytes and the match is of length 5, then
	* we'll simply copy 8 bytes. This is okay as long as we don't write
	* beyond the end of the output buffer, hence the check for (bufend -
	* end >= WORDBYTES - 1).
	*/
	#ifdef FAST_UNALIGNED_ACCESS
	u8 * const end = dst + length;

	if (bufend - end >= (ptrdiff_t)(WORDBYTES - 1)) {

	if (offset >= WORDBYTES) {
	/* The source and destination words don't overlap. */

	/* To improve branch prediction, one iteration of this
	* loop is unrolled. Most matches are short and will
	* fail the first check. But if that check passes, then
	* it becomes increasing likely that the match is long
	* and we'll need to continue copying.
	*/

	copy_unaligned_word(src, dst);
	src += WORDBYTES;
	dst += WORDBYTES;

	if (dst < end) {
	do {
	copy_unaligned_word(src, dst);
	src += WORDBYTES;
	dst += WORDBYTES;
	} while (dst < end);
	}
	return end;
	} else if (offset == 1) {

	/* Offset 1 matches are equivalent to run-length
	* encoding of the previous byte. This case is common
	* if the data contains many repeated bytes.
	*/
	size_t v = repeat_byte(*(dst - 1));

	do {
	put_unaligned(v, (size_t *)dst);
	src += WORDBYTES;
	dst += WORDBYTES;
	} while (dst < end);
	return end;
	}
	/*
	* We don't bother with special cases for other 'offset <
	* WORDBYTES', which are usually rarer than 'offset == 1'. Extra
	* checks will just slow things down. Actually, it's possible
	* to handle all the 'offset < WORDBYTES' cases using the same
	* code, but it still becomes more complicated doesn't seem any
	* faster overall; it definitely slows down the more common
	* 'offset == 1' case.
	*/
	}
	#endif /* FAST_UNALIGNED_ACCESS */

	/* Fall back to a bytewise copy. */

	if (min_length >= 2) {
	dst++ = src++;
	length--;
	}
	if (min_length >= 3) {
	dst++ = src++;
	length--;
	}
	do {
	dst++ = src++;
	} while (--length);

	return dst;
	}

	#endif /* _LINUX_NTFS3_LIB_DECOMPRESS_COMMON_H */