lib/xz/xz_dec_bcj.c - linux - Git at Google

 /*
  * Branch/Call/Jump (BCJ) filter decoders
  *
  * Authors: Lasse Collin <lasse.collin@tukaani.org>
  *          Igor Pavlov <https://7-zip.org/>
  *
  * This file has been put into the public domain.
  * You can do whatever you want with this file.
  */

 #include "xz_private.h"

 /*
  * The rest of the file is inside this ifdef. It makes things a little more
  * convenient when building without support for any BCJ filters.
  */
 #ifdef XZ_DEC_BCJ

 struct xz_dec_bcj {
 	/* Type of the BCJ filter being used */
 	enum {
 		BCJ_X86 = 4,        /* x86 or x86-64 */
 		BCJ_POWERPC = 5,    /* Big endian only */
 		BCJ_IA64 = 6,       /* Big or little endian */
 		BCJ_ARM = 7,        /* Little endian only */
 		BCJ_ARMTHUMB = 8,   /* Little endian only */
 		BCJ_SPARC = 9       /* Big or little endian */
 	} type;

 	/*
 	 * Return value of the next filter in the chain. We need to preserve
 	 * this information across calls, because we must not call the next
 	 * filter anymore once it has returned XZ_STREAM_END.
 	 */
 	enum xz_ret ret;

 	/* True if we are operating in single-call mode. */
 	bool single_call;

 	/*
 	 * Absolute position relative to the beginning of the uncompressed
 	 * data (in a single .xz Block). We care only about the lowest 32
 	 * bits so this doesn't need to be uint64_t even with big files.
 	 */
 	uint32_t pos;

 	/* x86 filter state */
 	uint32_t x86_prev_mask;

 	/* Temporary space to hold the variables from struct xz_buf */
 	uint8_t *out;
 	size_t out_pos;
 	size_t out_size;

 	struct {
 		/* Amount of already filtered data in the beginning of buf */
 		size_t filtered;

 		/* Total amount of data currently stored in buf  */
 		size_t size;

 		/*
 		 * Buffer to hold a mix of filtered and unfiltered data. This
 		 * needs to be big enough to hold Alignment + 2 * Look-ahead:
 		 *
 		 * Type         Alignment   Look-ahead
 		 * x86              1           4
 		 * PowerPC          4           0
 		 * IA-64           16           0
 		 * ARM              4           0
 		 * ARM-Thumb        2           2
 		 * SPARC            4           0
 		 */
 		uint8_t buf[16];
 	} temp;
 };

 #ifdef XZ_DEC_X86
 /*
  * This is used to test the most significant byte of a memory address
  * in an x86 instruction.
  */
 static inline int bcj_x86_test_msbyte(uint8_t b)
 {
 	return b == 0x00 || b == 0xFF;
 }

 static size_t bcj_x86(struct xz_dec_bcj *s, uint8_t *buf, size_t size)
 {
 	static const bool mask_to_allowed_status[8]
 		= { true, true, true, false, true, false, false, false };

 	static const uint8_t mask_to_bit_num[8] = { 0, 1, 2, 2, 3, 3, 3, 3 };

 	size_t i;
 	size_t prev_pos = (size_t)-1;
 	uint32_t prev_mask = s->x86_prev_mask;
 	uint32_t src;
 	uint32_t dest;
 	uint32_t j;
 	uint8_t b;

 	if (size <= 4)
 		return 0;

 	size -= 4;
 	for (i = 0; i < size; ++i) {
 		if ((buf[i] & 0xFE) != 0xE8)
 			continue;

 		prev_pos = i - prev_pos;
 		if (prev_pos > 3) {
 			prev_mask = 0;
 		} else {
 			prev_mask = (prev_mask << (prev_pos - 1)) & 7;
 			if (prev_mask != 0) {
 				b = buf[i + 4 - mask_to_bit_num[prev_mask]];
 				if (!mask_to_allowed_status[prev_mask]
 						|| bcj_x86_test_msbyte(b)) {
 					prev_pos = i;
 					prev_mask = (prev_mask << 1) | 1;
 					continue;
 				}
 			}
 		}

 		prev_pos = i;

 		if (bcj_x86_test_msbyte(buf[i + 4])) {
 			src = get_unaligned_le32(buf + i + 1);
 			while (true) {
 				dest = src - (s->pos + (uint32_t)i + 5);
 				if (prev_mask == 0)
 					break;

 				j = mask_to_bit_num[prev_mask] * 8;
 				b = (uint8_t)(dest >> (24 - j));
 				if (!bcj_x86_test_msbyte(b))
 					break;

 				src = dest ^ (((uint32_t)1 << (32 - j)) - 1);
 			}

 			dest &= 0x01FFFFFF;
 			dest |= (uint32_t)0 - (dest & 0x01000000);
 			put_unaligned_le32(dest, buf + i + 1);
 			i += 4;
 		} else {
 			prev_mask = (prev_mask << 1) | 1;
 		}
 	}

 	prev_pos = i - prev_pos;
 	s->x86_prev_mask = prev_pos > 3 ? 0 : prev_mask << (prev_pos - 1);
 	return i;
 }
 #endif

 #ifdef XZ_DEC_POWERPC
 static size_t bcj_powerpc(struct xz_dec_bcj *s, uint8_t *buf, size_t size)
 {
 	size_t i;
 	uint32_t instr;

 	for (i = 0; i + 4 <= size; i += 4) {
 		instr = get_unaligned_be32(buf + i);
 		if ((instr & 0xFC000003) == 0x48000001) {
 			instr &= 0x03FFFFFC;
 			instr -= s->pos + (uint32_t)i;
 			instr &= 0x03FFFFFC;
 			instr |= 0x48000001;
 			put_unaligned_be32(instr, buf + i);
 		}
 	}

 	return i;
 }
 #endif

 #ifdef XZ_DEC_IA64
 static size_t bcj_ia64(struct xz_dec_bcj *s, uint8_t *buf, size_t size)
 {
 	static const uint8_t branch_table[32] = {
 		0, 0, 0, 0, 0, 0, 0, 0,
 		0, 0, 0, 0, 0, 0, 0, 0,
 		4, 4, 6, 6, 0, 0, 7, 7,
 		4, 4, 0, 0, 4, 4, 0, 0
 	};

 	/*
 	 * The local variables take a little bit stack space, but it's less
 	 * than what LZMA2 decoder takes, so it doesn't make sense to reduce
 	 * stack usage here without doing that for the LZMA2 decoder too.
 	 */

 	/* Loop counters */
 	size_t i;
 	size_t j;

 	/* Instruction slot (0, 1, or 2) in the 128-bit instruction word */
 	uint32_t slot;

 	/* Bitwise offset of the instruction indicated by slot */
 	uint32_t bit_pos;

 	/* bit_pos split into byte and bit parts */
 	uint32_t byte_pos;
 	uint32_t bit_res;

 	/* Address part of an instruction */
 	uint32_t addr;

 	/* Mask used to detect which instructions to convert */
 	uint32_t mask;

 	/* 41-bit instruction stored somewhere in the lowest 48 bits */
 	uint64_t instr;

 	/* Instruction normalized with bit_res for easier manipulation */
 	uint64_t norm;

 	for (i = 0; i + 16 <= size; i += 16) {
 		mask = branch_table[buf[i] & 0x1F];
 		for (slot = 0, bit_pos = 5; slot < 3; ++slot, bit_pos += 41) {
 			if (((mask >> slot) & 1) == 0)
 				continue;

 			byte_pos = bit_pos >> 3;
 			bit_res = bit_pos & 7;
 			instr = 0;
 			for (j = 0; j < 6; ++j)
 				instr |= (uint64_t)(buf[i + j + byte_pos])
 						<< (8 * j);

 			norm = instr >> bit_res;

 			if (((norm >> 37) & 0x0F) == 0x05
 					&& ((norm >> 9) & 0x07) == 0) {
 				addr = (norm >> 13) & 0x0FFFFF;
 				addr |= ((uint32_t)(norm >> 36) & 1) << 20;
 				addr <<= 4;
 				addr -= s->pos + (uint32_t)i;
 				addr >>= 4;

 				norm &= ~((uint64_t)0x8FFFFF << 13);
 				norm |= (uint64_t)(addr & 0x0FFFFF) << 13;
 				norm |= (uint64_t)(addr & 0x100000)
 						<< (36 - 20);

 				instr &= (1 << bit_res) - 1;
 				instr |= norm << bit_res;

 				for (j = 0; j < 6; j++)
 					buf[i + j + byte_pos]
 						= (uint8_t)(instr >> (8 * j));
 			}
 		}
 	}

 	return i;
 }
 #endif

 #ifdef XZ_DEC_ARM
 static size_t bcj_arm(struct xz_dec_bcj *s, uint8_t *buf, size_t size)
 {
 	size_t i;
 	uint32_t addr;

 	for (i = 0; i + 4 <= size; i += 4) {
 		if (buf[i + 3] == 0xEB) {
 			addr = (uint32_t)buf[i] | ((uint32_t)buf[i + 1] << 8)
 					| ((uint32_t)buf[i + 2] << 16);
 			addr <<= 2;
 			addr -= s->pos + (uint32_t)i + 8;
 			addr >>= 2;
 			buf[i] = (uint8_t)addr;
 			buf[i + 1] = (uint8_t)(addr >> 8);
 			buf[i + 2] = (uint8_t)(addr >> 16);
 		}
 	}

 	return i;
 }
 #endif

 #ifdef XZ_DEC_ARMTHUMB
 static size_t bcj_armthumb(struct xz_dec_bcj *s, uint8_t *buf, size_t size)
 {
 	size_t i;
 	uint32_t addr;

 	for (i = 0; i + 4 <= size; i += 2) {
 		if ((buf[i + 1] & 0xF8) == 0xF0
 				&& (buf[i + 3] & 0xF8) == 0xF8) {
 			addr = (((uint32_t)buf[i + 1] & 0x07) << 19)
 					| ((uint32_t)buf[i] << 11)
 					| (((uint32_t)buf[i + 3] & 0x07) << 8)
 					| (uint32_t)buf[i + 2];
 			addr <<= 1;
 			addr -= s->pos + (uint32_t)i + 4;
 			addr >>= 1;
 			buf[i + 1] = (uint8_t)(0xF0 | ((addr >> 19) & 0x07));
 			buf[i] = (uint8_t)(addr >> 11);
 			buf[i + 3] = (uint8_t)(0xF8 | ((addr >> 8) & 0x07));
 			buf[i + 2] = (uint8_t)addr;
 			i += 2;
 		}
 	}

 	return i;
 }
 #endif

 #ifdef XZ_DEC_SPARC
 static size_t bcj_sparc(struct xz_dec_bcj *s, uint8_t *buf, size_t size)
 {
 	size_t i;
 	uint32_t instr;

 	for (i = 0; i + 4 <= size; i += 4) {
 		instr = get_unaligned_be32(buf + i);
 		if ((instr >> 22) == 0x100 || (instr >> 22) == 0x1FF) {
 			instr <<= 2;
 			instr -= s->pos + (uint32_t)i;
 			instr >>= 2;
 			instr = ((uint32_t)0x40000000 - (instr & 0x400000))
 					| 0x40000000 | (instr & 0x3FFFFF);
 			put_unaligned_be32(instr, buf + i);
 		}
 	}

 	return i;
 }
 #endif

 /*
  * Apply the selected BCJ filter. Update *pos and s->pos to match the amount
  * of data that got filtered.
  *
  * NOTE: This is implemented as a switch statement to avoid using function
  * pointers, which could be problematic in the kernel boot code, which must
  * avoid pointers to static data (at least on x86).
  */
 static void bcj_apply(struct xz_dec_bcj *s,
 		      uint8_t *buf, size_t *pos, size_t size)
 {
 	size_t filtered;

 	buf += *pos;
 	size -= *pos;

 	switch (s->type) {
 #ifdef XZ_DEC_X86
 	case BCJ_X86:
 		filtered = bcj_x86(s, buf, size);
 		break;
 #endif
 #ifdef XZ_DEC_POWERPC
 	case BCJ_POWERPC:
 		filtered = bcj_powerpc(s, buf, size);
 		break;
 #endif
 #ifdef XZ_DEC_IA64
 	case BCJ_IA64:
 		filtered = bcj_ia64(s, buf, size);
 		break;
 #endif
 #ifdef XZ_DEC_ARM
 	case BCJ_ARM:
 		filtered = bcj_arm(s, buf, size);
 		break;
 #endif
 #ifdef XZ_DEC_ARMTHUMB
 	case BCJ_ARMTHUMB:
 		filtered = bcj_armthumb(s, buf, size);
 		break;
 #endif
 #ifdef XZ_DEC_SPARC
 	case BCJ_SPARC:
 		filtered = bcj_sparc(s, buf, size);
 		break;
 #endif
 	default:
 		/* Never reached but silence compiler warnings. */
 		filtered = 0;
 		break;
 	}

 	*pos += filtered;
 	s->pos += filtered;
 }

 /*
  * Flush pending filtered data from temp to the output buffer.
  * Move the remaining mixture of possibly filtered and unfiltered
  * data to the beginning of temp.
  */
 static void bcj_flush(struct xz_dec_bcj *s, struct xz_buf *b)
 {
 	size_t copy_size;

 	copy_size = min_t(size_t, s->temp.filtered, b->out_size - b->out_pos);
 	memcpy(b->out + b->out_pos, s->temp.buf, copy_size);
 	b->out_pos += copy_size;

 	s->temp.filtered -= copy_size;
 	s->temp.size -= copy_size;
 	memmove(s->temp.buf, s->temp.buf + copy_size, s->temp.size);
 }

 /*
  * The BCJ filter functions are primitive in sense that they process the
  * data in chunks of 1-16 bytes. To hide this issue, this function does
  * some buffering.
  */
 XZ_EXTERN enum xz_ret xz_dec_bcj_run(struct xz_dec_bcj *s,
 				     struct xz_dec_lzma2 *lzma2,
 				     struct xz_buf *b)
 {
 	size_t out_start;

 	/*
 	 * Flush pending already filtered data to the output buffer. Return
 	 * immediately if we couldn't flush everything, or if the next
 	 * filter in the chain had already returned XZ_STREAM_END.
 	 */
 	if (s->temp.filtered > 0) {
 		bcj_flush(s, b);
 		if (s->temp.filtered > 0)
 			return XZ_OK;

 		if (s->ret == XZ_STREAM_END)
 			return XZ_STREAM_END;
 	}

 	/*
 	 * If we have more output space than what is currently pending in
 	 * temp, copy the unfiltered data from temp to the output buffer
 	 * and try to fill the output buffer by decoding more data from the
 	 * next filter in the chain. Apply the BCJ filter on the new data
 	 * in the output buffer. If everything cannot be filtered, copy it
 	 * to temp and rewind the output buffer position accordingly.
 	 *
 	 * This needs to be always run when temp.size == 0 to handle a special
 	 * case where the output buffer is full and the next filter has no
 	 * more output coming but hasn't returned XZ_STREAM_END yet.
 	 */
 	if (s->temp.size < b->out_size - b->out_pos || s->temp.size == 0) {
 		out_start = b->out_pos;
 		memcpy(b->out + b->out_pos, s->temp.buf, s->temp.size);
 		b->out_pos += s->temp.size;

 		s->ret = xz_dec_lzma2_run(lzma2, b);
 		if (s->ret != XZ_STREAM_END
 				&& (s->ret != XZ_OK || s->single_call))
 			return s->ret;

 		bcj_apply(s, b->out, &out_start, b->out_pos);

 		/*
 		 * As an exception, if the next filter returned XZ_STREAM_END,
 		 * we can do that too, since the last few bytes that remain
 		 * unfiltered are meant to remain unfiltered.
 		 */
 		if (s->ret == XZ_STREAM_END)
 			return XZ_STREAM_END;

 		s->temp.size = b->out_pos - out_start;
 		b->out_pos -= s->temp.size;
 		memcpy(s->temp.buf, b->out + b->out_pos, s->temp.size);

 		/*
 		 * If there wasn't enough input to the next filter to fill
 		 * the output buffer with unfiltered data, there's no point
 		 * to try decoding more data to temp.
 		 */
 		if (b->out_pos + s->temp.size < b->out_size)
 			return XZ_OK;
 	}

 	/*
 	 * We have unfiltered data in temp. If the output buffer isn't full
 	 * yet, try to fill the temp buffer by decoding more data from the
 	 * next filter. Apply the BCJ filter on temp. Then we hopefully can
 	 * fill the actual output buffer by copying filtered data from temp.
 	 * A mix of filtered and unfiltered data may be left in temp; it will
 	 * be taken care on the next call to this function.
 	 */
 	if (b->out_pos < b->out_size) {
 		/* Make b->out{,_pos,_size} temporarily point to s->temp. */
 		s->out = b->out;
 		s->out_pos = b->out_pos;
 		s->out_size = b->out_size;
 		b->out = s->temp.buf;
 		b->out_pos = s->temp.size;
 		b->out_size = sizeof(s->temp.buf);

 		s->ret = xz_dec_lzma2_run(lzma2, b);

 		s->temp.size = b->out_pos;
 		b->out = s->out;
 		b->out_pos = s->out_pos;
 		b->out_size = s->out_size;

 		if (s->ret != XZ_OK && s->ret != XZ_STREAM_END)
 			return s->ret;

 		bcj_apply(s, s->temp.buf, &s->temp.filtered, s->temp.size);

 		/*
 		 * If the next filter returned XZ_STREAM_END, we mark that
 		 * everything is filtered, since the last unfiltered bytes
 		 * of the stream are meant to be left as is.
 		 */
 		if (s->ret == XZ_STREAM_END)
 			s->temp.filtered = s->temp.size;

 		bcj_flush(s, b);
 		if (s->temp.filtered > 0)
 			return XZ_OK;
 	}

 	return s->ret;
 }

 XZ_EXTERN struct xz_dec_bcj *xz_dec_bcj_create(bool single_call)
 {
 	struct xz_dec_bcj *s = kmalloc(sizeof(*s), GFP_KERNEL);
 	if (s != NULL)
 		s->single_call = single_call;

 	return s;
 }

 XZ_EXTERN enum xz_ret xz_dec_bcj_reset(struct xz_dec_bcj *s, uint8_t id)
 {
 	switch (id) {
 #ifdef XZ_DEC_X86
 	case BCJ_X86:
 #endif
 #ifdef XZ_DEC_POWERPC
 	case BCJ_POWERPC:
 #endif
 #ifdef XZ_DEC_IA64
 	case BCJ_IA64:
 #endif
 #ifdef XZ_DEC_ARM
 	case BCJ_ARM:
 #endif
 #ifdef XZ_DEC_ARMTHUMB
 	case BCJ_ARMTHUMB:
 #endif
 #ifdef XZ_DEC_SPARC
 	case BCJ_SPARC:
 #endif
 		break;

 	default:
 		/* Unsupported Filter ID */
 		return XZ_OPTIONS_ERROR;
 	}

 	s->type = id;
 	s->ret = XZ_OK;
 	s->pos = 0;
 	s->x86_prev_mask = 0;
 	s->temp.filtered = 0;
 	s->temp.size = 0;

 	return XZ_OK;
 }

 #endif
	/*
	* Branch/Call/Jump (BCJ) filter decoders
	*
	* Authors: Lasse Collin <lasse.collin@tukaani.org>
	* Igor Pavlov <https://7-zip.org/>
	*
	* This file has been put into the public domain.
	* You can do whatever you want with this file.
	*/

	#include "xz_private.h"

	/*
	* The rest of the file is inside this ifdef. It makes things a little more
	* convenient when building without support for any BCJ filters.
	*/
	#ifdef XZ_DEC_BCJ

	struct xz_dec_bcj {
	/* Type of the BCJ filter being used */
	enum {
	BCJ_X86 = 4, /* x86 or x86-64 */
	BCJ_POWERPC = 5, /* Big endian only */
	BCJ_IA64 = 6, /* Big or little endian */
	BCJ_ARM = 7, /* Little endian only */
	BCJ_ARMTHUMB = 8, /* Little endian only */
	BCJ_SPARC = 9 /* Big or little endian */
	} type;

	/*
	* Return value of the next filter in the chain. We need to preserve
	* this information across calls, because we must not call the next
	* filter anymore once it has returned XZ_STREAM_END.
	*/
	enum xz_ret ret;

	/* True if we are operating in single-call mode. */
	bool single_call;

	/*
	* Absolute position relative to the beginning of the uncompressed
	* data (in a single .xz Block). We care only about the lowest 32
	* bits so this doesn't need to be uint64_t even with big files.
	*/
	uint32_t pos;

	/* x86 filter state */
	uint32_t x86_prev_mask;

	/* Temporary space to hold the variables from struct xz_buf */
	uint8_t *out;
	size_t out_pos;
	size_t out_size;

	struct {
	/* Amount of already filtered data in the beginning of buf */
	size_t filtered;

	/* Total amount of data currently stored in buf */
	size_t size;

	/*
	* Buffer to hold a mix of filtered and unfiltered data. This
	* needs to be big enough to hold Alignment + 2 * Look-ahead:
	*
	* Type Alignment Look-ahead
	* x86 1 4
	* PowerPC 4 0
	* IA-64 16 0
	* ARM 4 0
	* ARM-Thumb 2 2
	* SPARC 4 0
	*/
	uint8_t buf[16];
	} temp;
	};

	#ifdef XZ_DEC_X86
	/*
	* This is used to test the most significant byte of a memory address
	* in an x86 instruction.
	*/
	static inline int bcj_x86_test_msbyte(uint8_t b)
	{
	return b == 0x00 \|\| b == 0xFF;
	}

	static size_t bcj_x86(struct xz_dec_bcj s, uint8_t buf, size_t size)
	{
	static const bool mask_to_allowed_status[8]
	= { true, true, true, false, true, false, false, false };

	static const uint8_t mask_to_bit_num[8] = { 0, 1, 2, 2, 3, 3, 3, 3 };

	size_t i;
	size_t prev_pos = (size_t)-1;
	uint32_t prev_mask = s->x86_prev_mask;
	uint32_t src;
	uint32_t dest;
	uint32_t j;
	uint8_t b;

	if (size <= 4)
	return 0;

	size -= 4;
	for (i = 0; i < size; ++i) {
	if ((buf[i] & 0xFE) != 0xE8)
	continue;

	prev_pos = i - prev_pos;
	if (prev_pos > 3) {
	prev_mask = 0;
	} else {
	prev_mask = (prev_mask << (prev_pos - 1)) & 7;
	if (prev_mask != 0) {
	b = buf[i + 4 - mask_to_bit_num[prev_mask]];
	if (!mask_to_allowed_status[prev_mask]
	\|\| bcj_x86_test_msbyte(b)) {
	prev_pos = i;
	prev_mask = (prev_mask << 1) \| 1;
	continue;
	}
	}
	}

	prev_pos = i;

	if (bcj_x86_test_msbyte(buf[i + 4])) {
	src = get_unaligned_le32(buf + i + 1);
	while (true) {
	dest = src - (s->pos + (uint32_t)i + 5);
	if (prev_mask == 0)
	break;

	j = mask_to_bit_num[prev_mask] * 8;
	b = (uint8_t)(dest >> (24 - j));
	if (!bcj_x86_test_msbyte(b))
	break;

	src = dest ^ (((uint32_t)1 << (32 - j)) - 1);
	}

	dest &= 0x01FFFFFF;
	dest \|= (uint32_t)0 - (dest & 0x01000000);
	put_unaligned_le32(dest, buf + i + 1);
	i += 4;
	} else {
	prev_mask = (prev_mask << 1) \| 1;
	}
	}

	prev_pos = i - prev_pos;
	s->x86_prev_mask = prev_pos > 3 ? 0 : prev_mask << (prev_pos - 1);
	return i;
	}
	#endif

	#ifdef XZ_DEC_POWERPC
	static size_t bcj_powerpc(struct xz_dec_bcj s, uint8_t buf, size_t size)
	{
	size_t i;
	uint32_t instr;

	for (i = 0; i + 4 <= size; i += 4) {
	instr = get_unaligned_be32(buf + i);
	if ((instr & 0xFC000003) == 0x48000001) {
	instr &= 0x03FFFFFC;
	instr -= s->pos + (uint32_t)i;
	instr &= 0x03FFFFFC;
	instr \|= 0x48000001;
	put_unaligned_be32(instr, buf + i);
	}
	}

	return i;
	}
	#endif

	#ifdef XZ_DEC_IA64
	static size_t bcj_ia64(struct xz_dec_bcj s, uint8_t buf, size_t size)
	{
	static const uint8_t branch_table[32] = {
	0, 0, 0, 0, 0, 0, 0, 0,
	0, 0, 0, 0, 0, 0, 0, 0,
	4, 4, 6, 6, 0, 0, 7, 7,
	4, 4, 0, 0, 4, 4, 0, 0
	};

	/*
	* The local variables take a little bit stack space, but it's less
	* than what LZMA2 decoder takes, so it doesn't make sense to reduce
	* stack usage here without doing that for the LZMA2 decoder too.
	*/

	/* Loop counters */
	size_t i;
	size_t j;

	/* Instruction slot (0, 1, or 2) in the 128-bit instruction word */
	uint32_t slot;

	/* Bitwise offset of the instruction indicated by slot */
	uint32_t bit_pos;

	/* bit_pos split into byte and bit parts */
	uint32_t byte_pos;
	uint32_t bit_res;

	/* Address part of an instruction */
	uint32_t addr;

	/* Mask used to detect which instructions to convert */
	uint32_t mask;

	/* 41-bit instruction stored somewhere in the lowest 48 bits */
	uint64_t instr;

	/* Instruction normalized with bit_res for easier manipulation */
	uint64_t norm;

	for (i = 0; i + 16 <= size; i += 16) {
	mask = branch_table[buf[i] & 0x1F];
	for (slot = 0, bit_pos = 5; slot < 3; ++slot, bit_pos += 41) {
	if (((mask >> slot) & 1) == 0)
	continue;

	byte_pos = bit_pos >> 3;
	bit_res = bit_pos & 7;
	instr = 0;
	for (j = 0; j < 6; ++j)
	instr \|= (uint64_t)(buf[i + j + byte_pos])
	<< (8 * j);

	norm = instr >> bit_res;

	if (((norm >> 37) & 0x0F) == 0x05
	&& ((norm >> 9) & 0x07) == 0) {
	addr = (norm >> 13) & 0x0FFFFF;
	addr \|= ((uint32_t)(norm >> 36) & 1) << 20;
	addr <<= 4;
	addr -= s->pos + (uint32_t)i;
	addr >>= 4;

	norm &= ~((uint64_t)0x8FFFFF << 13);
	norm \|= (uint64_t)(addr & 0x0FFFFF) << 13;
	norm \|= (uint64_t)(addr & 0x100000)
	<< (36 - 20);

	instr &= (1 << bit_res) - 1;
	instr \|= norm << bit_res;

	for (j = 0; j < 6; j++)
	buf[i + j + byte_pos]
	= (uint8_t)(instr >> (8 * j));
	}
	}
	}

	return i;
	}
	#endif

	#ifdef XZ_DEC_ARM
	static size_t bcj_arm(struct xz_dec_bcj s, uint8_t buf, size_t size)
	{
	size_t i;
	uint32_t addr;

	for (i = 0; i + 4 <= size; i += 4) {
	if (buf[i + 3] == 0xEB) {
	addr = (uint32_t)buf[i] \| ((uint32_t)buf[i + 1] << 8)
	\| ((uint32_t)buf[i + 2] << 16);
	addr <<= 2;
	addr -= s->pos + (uint32_t)i + 8;
	addr >>= 2;
	buf[i] = (uint8_t)addr;
	buf[i + 1] = (uint8_t)(addr >> 8);
	buf[i + 2] = (uint8_t)(addr >> 16);
	}
	}

	return i;
	}
	#endif

	#ifdef XZ_DEC_ARMTHUMB
	static size_t bcj_armthumb(struct xz_dec_bcj s, uint8_t buf, size_t size)
	{
	size_t i;
	uint32_t addr;

	for (i = 0; i + 4 <= size; i += 2) {
	if ((buf[i + 1] & 0xF8) == 0xF0
	&& (buf[i + 3] & 0xF8) == 0xF8) {
	addr = (((uint32_t)buf[i + 1] & 0x07) << 19)
	\| ((uint32_t)buf[i] << 11)
	\| (((uint32_t)buf[i + 3] & 0x07) << 8)
	\| (uint32_t)buf[i + 2];
	addr <<= 1;
	addr -= s->pos + (uint32_t)i + 4;
	addr >>= 1;
	buf[i + 1] = (uint8_t)(0xF0 \| ((addr >> 19) & 0x07));
	buf[i] = (uint8_t)(addr >> 11);
	buf[i + 3] = (uint8_t)(0xF8 \| ((addr >> 8) & 0x07));
	buf[i + 2] = (uint8_t)addr;
	i += 2;
	}
	}

	return i;
	}
	#endif

	#ifdef XZ_DEC_SPARC
	static size_t bcj_sparc(struct xz_dec_bcj s, uint8_t buf, size_t size)
	{
	size_t i;
	uint32_t instr;

	for (i = 0; i + 4 <= size; i += 4) {
	instr = get_unaligned_be32(buf + i);
	if ((instr >> 22) == 0x100 \|\| (instr >> 22) == 0x1FF) {
	instr <<= 2;
	instr -= s->pos + (uint32_t)i;
	instr >>= 2;
	instr = ((uint32_t)0x40000000 - (instr & 0x400000))
	\| 0x40000000 \| (instr & 0x3FFFFF);
	put_unaligned_be32(instr, buf + i);
	}
	}

	return i;
	}
	#endif

	/*
	* Apply the selected BCJ filter. Update *pos and s->pos to match the amount
	* of data that got filtered.
	*
	* NOTE: This is implemented as a switch statement to avoid using function
	* pointers, which could be problematic in the kernel boot code, which must
	* avoid pointers to static data (at least on x86).
	*/
	static void bcj_apply(struct xz_dec_bcj *s,
	uint8_t buf, size_t pos, size_t size)
	{
	size_t filtered;

	buf += *pos;
	size -= *pos;

	switch (s->type) {
	#ifdef XZ_DEC_X86
	case BCJ_X86:
	filtered = bcj_x86(s, buf, size);
	break;
	#endif
	#ifdef XZ_DEC_POWERPC
	case BCJ_POWERPC:
	filtered = bcj_powerpc(s, buf, size);
	break;
	#endif
	#ifdef XZ_DEC_IA64
	case BCJ_IA64:
	filtered = bcj_ia64(s, buf, size);
	break;
	#endif
	#ifdef XZ_DEC_ARM
	case BCJ_ARM:
	filtered = bcj_arm(s, buf, size);
	break;
	#endif
	#ifdef XZ_DEC_ARMTHUMB
	case BCJ_ARMTHUMB:
	filtered = bcj_armthumb(s, buf, size);
	break;
	#endif
	#ifdef XZ_DEC_SPARC
	case BCJ_SPARC:
	filtered = bcj_sparc(s, buf, size);
	break;
	#endif
	default:
	/* Never reached but silence compiler warnings. */
	filtered = 0;
	break;
	}

	*pos += filtered;
	s->pos += filtered;
	}

	/*
	* Flush pending filtered data from temp to the output buffer.
	* Move the remaining mixture of possibly filtered and unfiltered
	* data to the beginning of temp.
	*/
	static void bcj_flush(struct xz_dec_bcj s, struct xz_buf b)
	{
	size_t copy_size;

	copy_size = min_t(size_t, s->temp.filtered, b->out_size - b->out_pos);
	memcpy(b->out + b->out_pos, s->temp.buf, copy_size);
	b->out_pos += copy_size;

	s->temp.filtered -= copy_size;
	s->temp.size -= copy_size;
	memmove(s->temp.buf, s->temp.buf + copy_size, s->temp.size);
	}

	/*
	* The BCJ filter functions are primitive in sense that they process the
	* data in chunks of 1-16 bytes. To hide this issue, this function does
	* some buffering.
	*/
	XZ_EXTERN enum xz_ret xz_dec_bcj_run(struct xz_dec_bcj *s,
	struct xz_dec_lzma2 *lzma2,
	struct xz_buf *b)
	{
	size_t out_start;

	/*
	* Flush pending already filtered data to the output buffer. Return
	* immediately if we couldn't flush everything, or if the next
	* filter in the chain had already returned XZ_STREAM_END.
	*/
	if (s->temp.filtered > 0) {
	bcj_flush(s, b);
	if (s->temp.filtered > 0)
	return XZ_OK;

	if (s->ret == XZ_STREAM_END)
	return XZ_STREAM_END;
	}

	/*
	* If we have more output space than what is currently pending in
	* temp, copy the unfiltered data from temp to the output buffer
	* and try to fill the output buffer by decoding more data from the
	* next filter in the chain. Apply the BCJ filter on the new data
	* in the output buffer. If everything cannot be filtered, copy it
	* to temp and rewind the output buffer position accordingly.
	*
	* This needs to be always run when temp.size == 0 to handle a special
	* case where the output buffer is full and the next filter has no
	* more output coming but hasn't returned XZ_STREAM_END yet.
	*/
	if (s->temp.size < b->out_size - b->out_pos \|\| s->temp.size == 0) {
	out_start = b->out_pos;
	memcpy(b->out + b->out_pos, s->temp.buf, s->temp.size);
	b->out_pos += s->temp.size;

	s->ret = xz_dec_lzma2_run(lzma2, b);
	if (s->ret != XZ_STREAM_END
	&& (s->ret != XZ_OK \|\| s->single_call))
	return s->ret;

	bcj_apply(s, b->out, &out_start, b->out_pos);

	/*
	* As an exception, if the next filter returned XZ_STREAM_END,
	* we can do that too, since the last few bytes that remain
	* unfiltered are meant to remain unfiltered.
	*/
	if (s->ret == XZ_STREAM_END)
	return XZ_STREAM_END;

	s->temp.size = b->out_pos - out_start;
	b->out_pos -= s->temp.size;
	memcpy(s->temp.buf, b->out + b->out_pos, s->temp.size);

	/*
	* If there wasn't enough input to the next filter to fill
	* the output buffer with unfiltered data, there's no point
	* to try decoding more data to temp.
	*/
	if (b->out_pos + s->temp.size < b->out_size)
	return XZ_OK;
	}

	/*
	* We have unfiltered data in temp. If the output buffer isn't full
	* yet, try to fill the temp buffer by decoding more data from the
	* next filter. Apply the BCJ filter on temp. Then we hopefully can
	* fill the actual output buffer by copying filtered data from temp.
	* A mix of filtered and unfiltered data may be left in temp; it will
	* be taken care on the next call to this function.
	*/
	if (b->out_pos < b->out_size) {
	/* Make b->out{,_pos,_size} temporarily point to s->temp. */
	s->out = b->out;
	s->out_pos = b->out_pos;
	s->out_size = b->out_size;
	b->out = s->temp.buf;
	b->out_pos = s->temp.size;
	b->out_size = sizeof(s->temp.buf);

	s->ret = xz_dec_lzma2_run(lzma2, b);

	s->temp.size = b->out_pos;
	b->out = s->out;
	b->out_pos = s->out_pos;
	b->out_size = s->out_size;

	if (s->ret != XZ_OK && s->ret != XZ_STREAM_END)
	return s->ret;

	bcj_apply(s, s->temp.buf, &s->temp.filtered, s->temp.size);

	/*
	* If the next filter returned XZ_STREAM_END, we mark that
	* everything is filtered, since the last unfiltered bytes
	* of the stream are meant to be left as is.
	*/
	if (s->ret == XZ_STREAM_END)
	s->temp.filtered = s->temp.size;

	bcj_flush(s, b);
	if (s->temp.filtered > 0)
	return XZ_OK;
	}

	return s->ret;
	}

	XZ_EXTERN struct xz_dec_bcj *xz_dec_bcj_create(bool single_call)
	{
	struct xz_dec_bcj s = kmalloc(sizeof(s), GFP_KERNEL);
	if (s != NULL)
	s->single_call = single_call;

	return s;
	}

	XZ_EXTERN enum xz_ret xz_dec_bcj_reset(struct xz_dec_bcj *s, uint8_t id)
	{
	switch (id) {
	#ifdef XZ_DEC_X86
	case BCJ_X86:
	#endif
	#ifdef XZ_DEC_POWERPC
	case BCJ_POWERPC:
	#endif
	#ifdef XZ_DEC_IA64
	case BCJ_IA64:
	#endif
	#ifdef XZ_DEC_ARM
	case BCJ_ARM:
	#endif
	#ifdef XZ_DEC_ARMTHUMB
	case BCJ_ARMTHUMB:
	#endif
	#ifdef XZ_DEC_SPARC
	case BCJ_SPARC:
	#endif
	break;

	default:
	/* Unsupported Filter ID */
	return XZ_OPTIONS_ERROR;
	}

	s->type = id;
	s->ret = XZ_OK;
	s->pos = 0;
	s->x86_prev_mask = 0;
	s->temp.filtered = 0;
	s->temp.size = 0;

	return XZ_OK;
	}

	#endif