Replace the experimental ARM64 filter with a new experimental version.

This is incompatible with the previous version. This has space/tab fixes in filter_*.c and bcj.h too.
2022-11-14 23:14:41 +02:00 · 2022-11-14 23:14:41 +02:00 · 8370ec8edf
parent f644473a21
commit 8370ec8edf
11 changed files with 143 additions and 283 deletions
--- a/src/liblzma/api/lzma/bcj.h
+++ b/src/liblzma/api/lzma/bcj.h
@ -49,12 +49,13 @@
 	 * Filter for SPARC binaries.
 	 */
-#define LZMA_FILTER_ARM64       LZMA_VLI_C(0x3FDB87B33B27000B)
+#define LZMA_FILTER_ARM64       LZMA_VLI_C(0x3FDB87B33B27010B)
 	/**<
 	 * Filter for ARM64 binaries.
 	 *
-        * \note         In contrast to the other BCJ filters, this uses
+	 * \note    THIS IS AN EXPERIMENTAL VERSION WHICH WILL
-        *               its own options structure, lzma_options_arm64.
+	 *          STILL CHANGE! FILES CREATED WITH THIS
 	 *          WILL NOT BE SUPPORTED IN THE FUTURE!
 	 */
 /**
@ -95,29 +96,3 @@ typedef struct {
 	uint32_t start_offset;
 } lzma_options_bcj;
 /**
 * \brief       Options for the ARM64 filter
 *
 * This filter never changes the size of the data.
 * Specifying options is mandatory.
 */
 typedef struct {
 	/**
 	 * \brief       How wide range of relative addresses are converted
 	 *
 	 * The ARM64 BL instruction has 26-bit immediate field that encodes
 	 * a relative address as a multiple of four bytes, so the effective
 	 * range is 2^28 bytes (+/-128 MiB).
 	 *
 	 * If width is 28 bits (LZMA_ARM64_WIDTH_MAX), then all BL
 	 * instructions will be converted. This has a downside of some
 	 * false matches that make compression worse. The best value
 	 * depends on the input file and the differences can be significant;
 	 * with large executables the maximum value is sometimes the best.
 	 */
 	uint32_t width;
 #	define LZMA_ARM64_WIDTH_MIN     18
 #	define LZMA_ARM64_WIDTH_MAX     28
 #	define LZMA_ARM64_WIDTH_DEFAULT 26
 } lzma_options_arm64;
--- a/src/liblzma/common/filter_common.c
+++ b/src/liblzma/common/filter_common.c
@ -100,7 +100,7 @@ static const struct {
 #if defined(HAVE_ENCODER_ARM64) || defined(HAVE_DECODER_ARM64)
 	{
 		.id = LZMA_FILTER_ARM64,
-		.options_size = sizeof(lzma_options_arm64),
+		.options_size = sizeof(lzma_options_bcj),
 		.non_last_ok = true,
 		.last_ok = false,
 		.changes_size = false,
--- a/src/liblzma/common/filter_decoder.c
+++ b/src/liblzma/common/filter_decoder.c
@ -104,7 +104,7 @@ static const lzma_filter_decoder decoders[] = {
 		.id = LZMA_FILTER_ARM64,
 		.init = &lzma_simple_arm64_decoder_init,
 		.memusage = NULL,
-               .props_decode = &lzma_arm64_props_decode,
+		.props_decode = &lzma_simple_props_decode,
 	},
 #endif
 #ifdef HAVE_DECODER_SPARC
--- a/src/liblzma/common/filter_encoder.c
+++ b/src/liblzma/common/filter_encoder.c
@ -132,9 +132,8 @@ static const lzma_filter_encoder encoders[] = {
 		.init = &lzma_simple_arm64_encoder_init,
 		.memusage = NULL,
 		.block_size = NULL,
-               .props_size_get = NULL,
+		.props_size_get = &lzma_simple_props_size,
-               .props_size_fixed = 1,
+		.props_encode = &lzma_simple_props_encode,
               .props_encode = &lzma_arm64_props_encode,
 	},
 #endif
 #ifdef HAVE_ENCODER_SPARC
--- a/src/liblzma/simple/arm64.c
+++ b/src/liblzma/simple/arm64.c
@ -3,6 +3,22 @@
 /// \file       arm64.c
 /// \brief      Filter for ARM64 binaries
 ///
 /// This converts ARM64 relative addresses in the BL and ADRP immediates
 /// to absolute values to increase redundancy of ARM64 code.
 ///
 /// Unlike the older BCJ filters, this handles zeros specially. This way
 /// the filter won't be counterproductive on Linux kernel modules, object
 /// files, and static libraries where the immediates are all zeros (to be
 /// filled later by a linker). Usually this has no downsides but with bad
 /// luck it can reduce the effectiveness of the filter and trying a different
 /// start offset can mitigate the problem.
 ///
 /// Converting B or ADR instructions was also tested but it's not useful.
 /// A majority of the jumps for the B instruction are very small (+/- 0xFF).
 /// These are typical for loops and if-statements. Encoding them to their
 /// absolute address reduces redundancy since many of the small relative
 /// jump values are repeated, but very few of the absolute addresses are.
 //
 //  Authors:    Lasse Collin
 //              Jia Tan
 //
@ -13,126 +29,110 @@
 #include "simple_private.h"
 #ifdef HAVE_ENCODER_ARM64
 #	include "simple_encoder.h"
 #endif
-#ifdef HAVE_DECODER_ARM64
+static uint32_t
-#	include "simple_decoder.h"
+arm64_conv(uint32_t src, uint32_t pc, uint32_t mask, bool is_encoder)
-#endif
+{
 	if (!is_encoder)
 		pc = 0U - pc;
 	uint32_t dest = src + pc;
 	if ((dest & mask) == 0)
 		dest = pc;
-// In ARM64, there are two main branch instructions.
+	return dest;
-// bl - branch and link: Calls a function and stores the return address.
+}
 // b - branch: Jumps to a location, but does not store a return address.
 //
 // After some benchmarking, it was determined that only the bl instruction
 // is beneficial for compression. A majority of the jumps for the b
 // instruction are very small (+/- 0xFF). These are typical for loops
 // and if-statements. Encoding them to their absolute address reduces
 // redundancy since many of the small relative jump values are repeated,
 // but very few of the absolute addresses are.
 //
 // Thus, only the bl instruction will be encoded and decoded.
 // The bl instruction is 32 bits in size. The highest 6 bits contain
 // the opcode (10 0101 == 0x25) and the remaining 26 bits are
 // the immediate value. The immediate is a signed integer that
 // encodes the target address as a multiple of four bytes so
 // the range is +/-128 MiB.
 // The 6-bit op code for the bl instruction in ARM64
 #define ARM64_BL_OPCODE 0x25
 // Once the 26-bit immediate is multiple by four, the address is 28 bits
 // with the two lowest bits being zero. This mask is used to clear the
 // unwanted bits.
 #define ADDR28_MASK 0x0FFFFFFCU
 typedef struct {
 	uint32_t sign_bit;
 	uint32_t sign_mask;
 } lzma_simple_arm64;
 static size_t
-arm64_code(void *simple_ptr, uint32_t now_pos, bool is_encoder,
+arm64_code(void *simple lzma_attribute((__unused__)),
 		uint32_t now_pos, bool is_encoder,
 		uint8_t *buffer, size_t size)
 {
 	const lzma_simple_arm64 *simple = simple_ptr;
 	const uint32_t sign_bit = simple->sign_bit;
 	const uint32_t sign_mask = simple->sign_mask;
 	size_t i;
 	// Clang 14.0.6 on x86-64 makes this four times bigger and 60 % slower
 	// with auto-vectorization that is enabled by default with -O2.
 	// Even -Os, which doesn't use vectorization, produces faster code.
 	// Disabling vectorization with -O2 gives good speed (faster than -Os)
 	// and reasonable code size.
 	//
 	// Such vectorization bloat happens with -O2 when targeting ARM64 too
 	// but performance hasn't been tested.
 	//
 	// Clang 14 and 15 won't auto-vectorize this loop if the condition
 	// for ADRP is replaced with the commented-out version. However,
 	// at least Clang 14.0.6 doesn't generate as fast code with that
 	// condition. The commented-out code is also bigger.
 	//
 	// GCC 12.2 on x86-64 with -O2 produces good code with both versions
 	// of the ADRP if-statement although the single-branch version is
 	// slightly faster and smaller than the commented-out version.
 	// Speed is similar to non-vectorized clang -O2.
 #ifdef __clang__
 #	pragma clang loop vectorize(disable)
 #endif
 	for (i = 0; i + 4 <= size; i += 4) {
-		if ((buffer[i + 3] >> 2) == ARM64_BL_OPCODE) {
+		const uint32_t pc = (uint32_t)(now_pos + i);
-			// Get the relative 28-bit address from
+		uint32_t instr = read32le(buffer + i);
 			// the 26-bit immediate.
 			uint32_t src = read32le(buffer + i);
 			src <<= 2;
 			src &= ADDR28_MASK;
-			// When the conversion width isn't the maximum,
+		if ((instr >> 26) == 0x25) {
-			// check that the highest bits are either all zero
+			// BL instruction:
-			// or all one.
+			// The full 26-bit immediate is converted.
-			if ((src & sign_mask) != 0
+			// The range is +/-128 MiB.
-					&& (src & sign_mask) != sign_mask)
+			//
-				continue;
+			// Using the full range is helps quite a lot with
 			// big executables. Smaller range would reduce false
 			// positives in non-code sections of the input though
 			// so this is a compromise that slightly favors big
 			// files. With the full range only six bits of the 32
 			// need to match to trigger a conversion.
 			const uint32_t mask26 = 0x03FFFFFF;
 			const uint32_t src = instr & mask26;
 			instr = 0x94000000;
 			// Some files like static libraries or Linux kernel
 			// modules have the immediate value filled with
 			// zeros. Converting these placeholder values would
 			// make compression worse so don't touch them.
 			if (src == 0)
 				continue;
-			const uint32_t pc = now_pos + (uint32_t)(i);
+			instr |= arm64_conv(src, pc >> 2, mask26, is_encoder)
 					& mask26;
 			write32le(buffer + i, instr);
-			uint32_t dest;
+/*
-			if (is_encoder)
+		// This is a more readable version of the one below but this
-				dest = pc + src;
+		// has two branches. It results in bigger and slower code.
-			else
+		} else if ((instr & 0x9FF00000) == 0x90000000
-				dest = src - pc;
+				|| (instr & 0x9FF00000) == 0x90F00000) {
 */
 		// This is only a rotation, addition, and testing that
 		// none of the bits covered by the bitmask are set.
 		} else if (((((instr << 8) | (instr >> 24))
 				+ (0x10000000 - 0x90)) & 0xE000009F) == 0) {
 			// ADRP instruction:
 			// Only values in the range +/-512 MiB are converted.
 			//
 			// Using less than the full +/-4 GiB range reduces
 			// false positives on non-code sections of the input
 			// while being excellent for executables up to 512 MiB.
 			// The positive effect of ADRP conversion is smaller
 			// than that of BL but it also doesn't hurt so much in
 			// non-code sections of input because, with +/-512 MiB
 			// range, nine bits of 32 need to match to trigger a
 			// conversion (two 10-bit match choices = 9 bits).
 			const uint32_t src = ((instr >> 29) & 3)
 					| ((instr >> 3) & 0x0003FFFC);
 			instr &= 0x9000001F;
-			dest &= ADDR28_MASK;
+			if (src == 0)
 				continue;
-			// Sign-extend negative values or unset sign bits
+			const uint32_t dest = arm64_conv(
-			// from positive values.
+					src, pc >> 12, 0x3FFFF, is_encoder);
 			if (dest & sign_bit)
 				dest |= sign_mask;
 			else
 				dest &= ~sign_mask;
-			assert((dest & sign_mask) == 0
+			instr |= (dest & 3) << 29;
-					|| (dest & sign_mask) == sign_mask);
+			instr |= (dest & 0x0003FFFC) << 3;
-
+			instr |= (0U - (dest & 0x00020000)) & 0x00E00000;
-			// Since also the decoder will ignore src values
+			write32le(buffer + i, instr);
 			// of 0, we must ensure that nothing is ever encoded
 			// to 0. This is achieved by encoding such values
 			// as pc instead. When decoding, pc will be first
 			// converted to 0 which we will catch here and fix.
 			if (dest == 0) {
 				// We cannot get here if pc is zero because
 				// then src would need to be zero too but we
 				// already ensured that src != 0.
 				assert((pc & ADDR28_MASK) != 0);
 				dest = is_encoder ? pc : 0U - pc;
 				dest &= ADDR28_MASK;
 				if (dest & sign_bit)
 					dest |= sign_mask;
 				else
 					dest &= ~sign_mask;
 			}
 			assert((dest & sign_mask) == 0
 					|| (dest & sign_mask) == sign_mask);
 			assert((dest & ~ADDR28_MASK) == 0);
 			// Construct and store the modified 32-bit instruction.
 			dest >>= 2;
 			dest |= (uint32_t)ARM64_BL_OPCODE << 26;
 			write32le(buffer + i, dest);
 		}
 	}
@ -140,81 +140,12 @@ arm64_code(void *simple_ptr, uint32_t now_pos, bool is_encoder,
 }
 #ifdef HAVE_ENCODER_ARM64
 extern lzma_ret
 lzma_arm64_props_encode(const void *options, uint8_t *out)
 {
 	const lzma_options_arm64 *const opt = options;
 	if (opt->width < LZMA_ARM64_WIDTH_MIN
 			|| opt->width > LZMA_ARM64_WIDTH_MAX)
 		return LZMA_OPTIONS_ERROR;
 	out[0] = (uint8_t)(opt->width - LZMA_ARM64_WIDTH_MIN);
 	return LZMA_OK;
 }
 #endif
 #ifdef HAVE_DECODER_ARM64
 extern lzma_ret
 lzma_arm64_props_decode(void **options, const lzma_allocator *allocator,
 		const uint8_t *props, size_t props_size)
 {
 	if (props_size != 1)
 		return LZMA_OPTIONS_ERROR;
 	if (props[0] > LZMA_ARM64_WIDTH_MAX - LZMA_ARM64_WIDTH_MIN)
 		return LZMA_OPTIONS_ERROR;
 	lzma_options_arm64 *opt = lzma_alloc(sizeof(lzma_options_arm64),
 			allocator);
 	if (opt == NULL)
 		return LZMA_MEM_ERROR;
 	opt->width = props[0] + LZMA_ARM64_WIDTH_MIN;
 	*options = opt;
 	return LZMA_OK;
 }
 #endif
 static lzma_ret
 arm64_coder_init(lzma_next_coder *next, const lzma_allocator *allocator,
 		const lzma_filter_info *filters, bool is_encoder)
 {
-	if (filters[0].options == NULL)
+	return lzma_simple_coder_init(next, allocator, filters,
-		return LZMA_PROG_ERROR;
+			&arm64_code, 0, 4, 4, is_encoder, true);
 	const lzma_options_arm64 *opt = filters[0].options;
 	if (opt->width < LZMA_ARM64_WIDTH_MIN
 			|| opt->width > LZMA_ARM64_WIDTH_MAX)
 		return LZMA_OPTIONS_ERROR;
 	const lzma_ret ret = lzma_simple_coder_init(next, allocator, filters,
 			&arm64_code, sizeof(lzma_simple_arm64), 4, 4,
 			is_encoder, false);
 	if (ret == LZMA_OK) {
 		lzma_simple_coder *coder = next->coder;
 		lzma_simple_arm64 *simple = coder->simple;
 		// This will be used to detect if the value, after
 		// conversion has been done, is negative. The location
 		// of the sign bit depends on the conversion width.
 		simple->sign_bit = UINT32_C(1) << (opt->width - 1);
 		// When conversion width isn't the maximum, the highest
 		// bits must all be either zero or one, that is, they
 		// all are copies of the sign bit. This mask is used to
 		// (1) detect if input value is in the range specified
 		// by the conversion width and (2) clearing or setting
 		// the high bits after conversion (integers can wrap around).
 		simple->sign_mask = (UINT32_C(1) << 28) - simple->sign_bit;
 	}
 	return ret;
 }
--- a/src/liblzma/simple/simple_decoder.h
+++ b/src/liblzma/simple/simple_decoder.h
@ -19,8 +19,4 @@ extern lzma_ret lzma_simple_props_decode(
 		void **options, const lzma_allocator *allocator,
 		const uint8_t *props, size_t props_size);
 extern lzma_ret lzma_arm64_props_decode(
 		void **options, const lzma_allocator *allocator,
 		const uint8_t *props, size_t props_size);
 #endif
--- a/src/liblzma/simple/simple_encoder.h
+++ b/src/liblzma/simple/simple_encoder.h
@ -20,6 +20,4 @@ extern lzma_ret lzma_simple_props_size(uint32_t *size, const void *options);
 extern lzma_ret lzma_simple_props_encode(const void *options, uint8_t *out);
 extern lzma_ret lzma_arm64_props_encode(const void *options, uint8_t *out);
 #endif
--- a/src/xz/args.c
+++ b/src/xz/args.c
@ -374,7 +374,7 @@ parse_real(args_info *args, int argc, char **argv)
 		case OPT_ARM64:
 			coder_add_filter(LZMA_FILTER_ARM64,
-					options_arm64(optarg));
+					options_bcj(optarg));
 			break;
 		case OPT_SPARC:
--- a/src/xz/message.c
+++ b/src/xz/message.c
@ -1034,9 +1034,16 @@ message_filters_to_str(char buf[FILTERS_STR_SIZE],
 		}
 		case LZMA_FILTER_ARM64: {
-			const lzma_options_arm64 *opt = filters[i].options;
+			// FIXME TODO: Merge with the above generic BCJ list
-			my_snprintf(&pos, &left, "arm64=width=%" PRIu32,
+			// once the Filter ID is changed to the final value.
-					opt->width);
+			const lzma_options_bcj *opt = filters[i].options;
 			my_snprintf(&pos, &left, "arm64");
 			// Show the start offset only when really needed.
 			if (opt != NULL && opt->start_offset != 0)
 				my_snprintf(&pos, &left, "=start=%" PRIu32,
 						opt->start_offset);
 			break;
 		}
--- a/src/xz/options.c
+++ b/src/xz/options.c
@ -224,45 +224,6 @@ options_bcj(const char *str)
 }
 ///////////
 // ARM64 //
 ///////////
 enum {
 	OPT_WIDTH,
 };
 static void
 set_arm64(void *options, unsigned key, uint64_t value,
 		const char *valuestr lzma_attribute((__unused__)))
 {
 	lzma_options_arm64 *opt = options;
 	switch (key) {
 	case OPT_WIDTH:
 		opt->width = value;
 		break;
 	}
 }
 extern lzma_options_arm64 *
 options_arm64(const char *str)
 {
 	static const option_map opts[] = {
 		{ "width", NULL, LZMA_ARM64_WIDTH_MIN, LZMA_ARM64_WIDTH_MAX },
 		{ NULL,    NULL, 0, 0 }
 	};
 	lzma_options_arm64 *options = xmalloc(sizeof(lzma_options_arm64));
 	options->width = LZMA_ARM64_WIDTH_DEFAULT;
 	parse_options(str, opts, &set_arm64, options);
 	return options;
 }
 //////////
 // LZMA //
 //////////
--- a/src/xz/options.h
+++ b/src/xz/options.h
@ -24,13 +24,6 @@ extern lzma_options_delta *options_delta(const char *str);
 extern lzma_options_bcj *options_bcj(const char *str);
 /// \brief      Parser for ARM64 options
 ///
 /// \return     Pointer to allocated options structure.
 ///             Doesn't return on error.
 extern lzma_options_arm64 *options_arm64(const char *str);
 /// \brief      Parser for LZMA options
 ///
 /// \return     Pointer to allocated options structure.