Optimise memchr for NEON-enabled processors

2017-01-26 10:06:10 +00:00 · 2017-01-26 10:06:10 +00:00 · c47c9bdc1b
parent c6c7dfc493
commit c47c9bdc1b
2 changed files with 185 additions and 2 deletions
--- a/newlib/libc/machine/arm/memchr-stub.c
+++ b/newlib/libc/machine/arm/memchr-stub.c
@ -29,7 +29,9 @@
 #include "acle-compat.h"
-#if __ARM_ARCH_ISA_THUMB >= 2 && defined (__ARM_FEATURE_DSP)
+#if defined (__ARM_NEON__) || defined (__ARM_NEON)
 /* Defined in memchr.S.  */
 #elif __ARM_ARCH_ISA_THUMB >= 2 && defined (__ARM_FEATURE_DSP)
 /* Defined in memchr.S.  */
 #else
 # include "../../string/memchr.c"
--- a/newlib/libc/machine/arm/memchr.S
+++ b/newlib/libc/machine/arm/memchr.S
@ -78,7 +78,188 @@
 #include "acle-compat.h"
@ NOTE: This ifdef MUST match the one in memchr-stub.c
-#if __ARM_ARCH_ISA_THUMB >= 2 && defined (__ARM_FEATURE_DSP)
+#if defined (__ARM_NEON__) || defined (__ARM_NEON)
 	.arch	armv7-a
 	.fpu	neon
 /* Arguments */
 #define srcin		r0
 #define chrin		r1
 #define cntin		r2
 /* Retval */
 #define result		r0	/* Live range does not overlap with srcin */
 /* Working registers */
 #define src		r1	/* Live range does not overlap with chrin */
 #define tmp		r3
 #define synd		r0	/* No overlap with srcin or result */
 #define soff		r12
 /* Working NEON registers */
 #define vrepchr		q0
 #define vdata0		q1
 #define vdata0_0	d2	/* Lower half of vdata0 */
 #define vdata0_1	d3	/* Upper half of vdata0 */
 #define vdata1		q2
 #define vdata1_0	d4	/* Lower half of vhas_chr0 */
 #define vdata1_1	d5	/* Upper half of vhas_chr0 */
 #define vrepmask	q3
 #define vrepmask0	d6
 #define vrepmask1	d7
 #define vend		q4
 #define vend0		d8
 #define vend1		d9
 /*
 * Core algorithm:
 *
 * For each 32-byte chunk we calculate a 32-bit syndrome value, with one bit per
 * byte. Each bit is set if the relevant byte matched the requested character
 * and cleared otherwise. Since the bits in the syndrome reflect exactly the
 * order in which things occur in the original string, counting trailing zeros
 * allows to identify exactly which byte has matched.
 */
 	.text
 	.thumb_func
 	.align 4
 	.p2align 4,,15
 	.global memchr
 	.type memchr,%function
 memchr:
 	.cfi_sections .debug_frame
 	.cfi_startproc
 	/* Use a simple loop if there are less than 8 bytes to search.  */
 	cmp	cntin, #7
 	bhi	.Llargestr
 .Lsmallstr:
 	subs	cntin, cntin, #1
 	blt	.Lnotfound	/* Return not found if reached end.  */
 	ldrb	tmp, [srcin], #1
 	cmp	tmp, chrin
 	bne	.Lsmallstr	/* Loop again if not found.  */
 	/* Otherwise fixup address and return.  */
 	sub	result, result, #1
 	bx	lr
 .Llargestr:
 	vdup.8	vrepchr, chrin	/* Duplicate char across all lanes. */
 	/*
 	 * Magic constant 0x8040201008040201 allows us to identify which lane
 	 * matches the requested byte.
 	 */
 	movw	tmp, #0x0201
 	movt	tmp, #0x0804
 	lsl	soff, tmp, #4
 	vmov	vrepmask0, tmp, soff
 	vmov	vrepmask1, tmp, soff
 	/* Work with aligned 32-byte chunks */
 	bic	src, srcin, #31
 	ands	soff, srcin, #31
 	beq	.Lloopintro	/* Go straight to main loop if it's aligned. */
 	/*
 	 * Input string is not 32-byte aligned. We calculate the syndrome
 	 * value for the aligned 32 bytes block containing the first bytes
 	 * and mask the irrelevant part.
 	 */
 	vld1.8		{vdata0, vdata1}, [src:256]!
 	sub		tmp, soff, #32
 	adds		cntin, cntin, tmp
 	vceq.i8		vdata0, vdata0, vrepchr
 	vceq.i8		vdata1, vdata1, vrepchr
 	vand		vdata0, vdata0, vrepmask
 	vand		vdata1, vdata1, vrepmask
 	vpadd.i8	vdata0_0, vdata0_0, vdata0_1
 	vpadd.i8	vdata1_0, vdata1_0, vdata1_1
 	vpadd.i8	vdata0_0, vdata0_0, vdata1_0
 	vpadd.i8	vdata0_0, vdata0_0, vdata0_0
 	vmov		synd, vdata0_0[0]
 	/* Clear the soff lower bits */
 	lsr		synd, synd, soff
 	lsl		synd, synd, soff
 	/* The first block can also be the last */
 	bls		.Lmasklast
 	/* Have we found something already? */
 	cbnz		synd, .Ltail
 .Lloopintro:
 	vpush	{vend}
 	/* 264/265 correspond to d8/d9 for q4 */
 	.cfi_adjust_cfa_offset	16
 	.cfi_rel_offset	264, 0
 	.cfi_rel_offset	265, 8
 	.p2align 3,,7
 .Lloop:
 	vld1.8		{vdata0, vdata1}, [src:256]!
 	subs		cntin, cntin, #32
 	vceq.i8		vdata0, vdata0, vrepchr
 	vceq.i8		vdata1, vdata1, vrepchr
 	/* If we're out of data we finish regardless of the result. */
 	bls		.Lend
 	/* Use a fast check for the termination condition. */
 	vorr		vend, vdata0, vdata1
 	vorr		vend0, vend0, vend1
 	vmov		synd, tmp, vend0
 	orrs		synd, synd, tmp
 	/* We're not out of data, loop if we haven't found the character. */
 	beq		.Lloop
 .Lend:
 	vpop		{vend}
 	.cfi_adjust_cfa_offset	-16
 	.cfi_restore	264
 	.cfi_restore	265
 	/* Termination condition found, let's calculate the syndrome value. */
 	vand		vdata0, vdata0, vrepmask
 	vand		vdata1, vdata1, vrepmask
 	vpadd.i8	vdata0_0, vdata0_0, vdata0_1
 	vpadd.i8	vdata1_0, vdata1_0, vdata1_1
 	vpadd.i8	vdata0_0, vdata0_0, vdata1_0
 	vpadd.i8	vdata0_0, vdata0_0, vdata0_0
 	vmov		synd, vdata0_0[0]
 	cbz		synd, .Lnotfound
 	bhi		.Ltail
 .Lmasklast:
 	/* Clear the (-cntin) upper bits to avoid out-of-bounds matches. */
 	neg	cntin, cntin
 	lsl	synd, synd, cntin
 	lsrs	synd, synd, cntin
 	it	eq
 	moveq	src, #0	/* If no match, set src to 0 so the retval is 0. */
 .Ltail:
 	/* Count the trailing zeros using bit reversing */
 	rbit	synd, synd
 	/* Compensate the last post-increment */
 	sub	src, src, #32
 	/* Count the leading zeros */
 	clz	synd, synd
 	/* Compute the potential result and return */
 	add	result, src, synd
 	bx	lr
 .Lnotfound:
 	/* Set result to NULL if not found and return */
 	mov	result, #0
 	bx	lr
 	.cfi_endproc
 	.size	memchr, . - memchr
 #elif __ARM_ARCH_ISA_THUMB >= 2 && defined (__ARM_FEATURE_DSP)
 #if __ARM_ARCH_PROFILE == 'M'
       .arch armv7e-m