arch/ppc/kernel/vector.S - LeafOS-Devices/android_kernel_samsung_gta4xl - Gitiles

 #include <asm/ppc_asm.h>
 #include <asm/processor.h>

 /*
  * The routines below are in assembler so we can closely control the
  * usage of floating-point registers.  These routines must be called
  * with preempt disabled.
  */
 	.data
 fpzero:
 	.long	0
 fpone:
 	.long	0x3f800000	/* 1.0 in single-precision FP */
 fphalf:
 	.long	0x3f000000	/* 0.5 in single-precision FP */

 	.text
 /*
  * Internal routine to enable floating point and set FPSCR to 0.
  * Don't call it from C; it doesn't use the normal calling convention.
  */
 fpenable:
 	mfmsr	r10
 	ori	r11,r10,MSR_FP
 	mtmsr	r11
 	isync
 	stfd	fr0,24(r1)
 	stfd	fr1,16(r1)
 	stfd	fr31,8(r1)
 	lis	r11,fpzero@ha
 	mffs	fr31
 	lfs	fr1,fpzero@l(r11)
 	mtfsf	0xff,fr1
 	blr

 fpdisable:
 	mtfsf	0xff,fr31
 	lfd	fr31,8(r1)
 	lfd	fr1,16(r1)
 	lfd	fr0,24(r1)
 	mtmsr	r10
 	isync
 	blr

 /*
  * Vector add, floating point.
  */
 	.globl	vaddfp
 vaddfp:
 	stwu	r1,-32(r1)
 	mflr	r0
 	stw	r0,36(r1)
 	bl	fpenable
 	li	r0,4
 	mtctr	r0
 	li	r6,0
 1:	lfsx	fr0,r4,r6
 	lfsx	fr1,r5,r6
 	fadds	fr0,fr0,fr1
 	stfsx	fr0,r3,r6
 	addi	r6,r6,4
 	bdnz	1b
 	bl	fpdisable
 	lwz	r0,36(r1)
 	mtlr	r0
 	addi	r1,r1,32
 	blr

 /*
  * Vector subtract, floating point.
  */
 	.globl	vsubfp
 vsubfp:
 	stwu	r1,-32(r1)
 	mflr	r0
 	stw	r0,36(r1)
 	bl	fpenable
 	li	r0,4
 	mtctr	r0
 	li	r6,0
 1:	lfsx	fr0,r4,r6
 	lfsx	fr1,r5,r6
 	fsubs	fr0,fr0,fr1
 	stfsx	fr0,r3,r6
 	addi	r6,r6,4
 	bdnz	1b
 	bl	fpdisable
 	lwz	r0,36(r1)
 	mtlr	r0
 	addi	r1,r1,32
 	blr

 /*
  * Vector multiply and add, floating point.
  */
 	.globl	vmaddfp
 vmaddfp:
 	stwu	r1,-48(r1)
 	mflr	r0
 	stw	r0,52(r1)
 	bl	fpenable
 	stfd	fr2,32(r1)
 	li	r0,4
 	mtctr	r0
 	li	r7,0
 1:	lfsx	fr0,r4,r7
 	lfsx	fr1,r5,r7
 	lfsx	fr2,r6,r7
 	fmadds	fr0,fr0,fr2,fr1
 	stfsx	fr0,r3,r7
 	addi	r7,r7,4
 	bdnz	1b
 	lfd	fr2,32(r1)
 	bl	fpdisable
 	lwz	r0,52(r1)
 	mtlr	r0
 	addi	r1,r1,48
 	blr

 /*
  * Vector negative multiply and subtract, floating point.
  */
 	.globl	vnmsubfp
 vnmsubfp:
 	stwu	r1,-48(r1)
 	mflr	r0
 	stw	r0,52(r1)
 	bl	fpenable
 	stfd	fr2,32(r1)
 	li	r0,4
 	mtctr	r0
 	li	r7,0
 1:	lfsx	fr0,r4,r7
 	lfsx	fr1,r5,r7
 	lfsx	fr2,r6,r7
 	fnmsubs	fr0,fr0,fr2,fr1
 	stfsx	fr0,r3,r7
 	addi	r7,r7,4
 	bdnz	1b
 	lfd	fr2,32(r1)
 	bl	fpdisable
 	lwz	r0,52(r1)
 	mtlr	r0
 	addi	r1,r1,48
 	blr

 /*
  * Vector reciprocal estimate.  We just compute 1.0/x.
  * r3 -> destination, r4 -> source.
  */
 	.globl	vrefp
 vrefp:
 	stwu	r1,-32(r1)
 	mflr	r0
 	stw	r0,36(r1)
 	bl	fpenable
 	lis	r9,fpone@ha
 	li	r0,4
 	lfs	fr1,fpone@l(r9)
 	mtctr	r0
 	li	r6,0
 1:	lfsx	fr0,r4,r6
 	fdivs	fr0,fr1,fr0
 	stfsx	fr0,r3,r6
 	addi	r6,r6,4
 	bdnz	1b
 	bl	fpdisable
 	lwz	r0,36(r1)
 	mtlr	r0
 	addi	r1,r1,32
 	blr

 /*
  * Vector reciprocal square-root estimate, floating point.
  * We use the frsqrte instruction for the initial estimate followed
  * by 2 iterations of Newton-Raphson to get sufficient accuracy.
  * r3 -> destination, r4 -> source.
  */
 	.globl	vrsqrtefp
 vrsqrtefp:
 	stwu	r1,-48(r1)
 	mflr	r0
 	stw	r0,52(r1)
 	bl	fpenable
 	stfd	fr2,32(r1)
 	stfd	fr3,40(r1)
 	stfd	fr4,48(r1)
 	stfd	fr5,56(r1)
 	lis	r9,fpone@ha
 	lis	r8,fphalf@ha
 	li	r0,4
 	lfs	fr4,fpone@l(r9)
 	lfs	fr5,fphalf@l(r8)
 	mtctr	r0
 	li	r6,0
 1:	lfsx	fr0,r4,r6
 	frsqrte	fr1,fr0		/* r = frsqrte(s) */
 	fmuls	fr3,fr1,fr0	/* r * s */
 	fmuls	fr2,fr1,fr5	/* r * 0.5 */
 	fnmsubs	fr3,fr1,fr3,fr4	/* 1 - s * r * r */
 	fmadds	fr1,fr2,fr3,fr1	/* r = r + 0.5 * r * (1 - s * r * r) */
 	fmuls	fr3,fr1,fr0	/* r * s */
 	fmuls	fr2,fr1,fr5	/* r * 0.5 */
 	fnmsubs	fr3,fr1,fr3,fr4	/* 1 - s * r * r */
 	fmadds	fr1,fr2,fr3,fr1	/* r = r + 0.5 * r * (1 - s * r * r) */
 	stfsx	fr1,r3,r6
 	addi	r6,r6,4
 	bdnz	1b
 	lfd	fr5,56(r1)
 	lfd	fr4,48(r1)
 	lfd	fr3,40(r1)
 	lfd	fr2,32(r1)
 	bl	fpdisable
 	lwz	r0,36(r1)
 	mtlr	r0
 	addi	r1,r1,32
 	blr
	#include <asm/ppc_asm.h>
	#include <asm/processor.h>

	/*
	* The routines below are in assembler so we can closely control the
	* usage of floating-point registers. These routines must be called
	* with preempt disabled.
	*/
	.data
	fpzero:
	.long 0
	fpone:
	.long 0x3f800000 /* 1.0 in single-precision FP */
	fphalf:
	.long 0x3f000000 /* 0.5 in single-precision FP */

	.text
	/*
	* Internal routine to enable floating point and set FPSCR to 0.
	* Don't call it from C; it doesn't use the normal calling convention.
	*/
	fpenable:
	mfmsr r10
	ori r11,r10,MSR_FP
	mtmsr r11
	isync
	stfd fr0,24(r1)
	stfd fr1,16(r1)
	stfd fr31,8(r1)
	lis r11,fpzero@ha
	mffs fr31
	lfs fr1,fpzero@l(r11)
	mtfsf 0xff,fr1
	blr

	fpdisable:
	mtfsf 0xff,fr31
	lfd fr31,8(r1)
	lfd fr1,16(r1)
	lfd fr0,24(r1)
	mtmsr r10
	isync
	blr

	/*
	* Vector add, floating point.
	*/
	.globl vaddfp
	vaddfp:
	stwu r1,-32(r1)
	mflr r0
	stw r0,36(r1)
	bl fpenable
	li r0,4
	mtctr r0
	li r6,0
	1: lfsx fr0,r4,r6
	lfsx fr1,r5,r6
	fadds fr0,fr0,fr1
	stfsx fr0,r3,r6
	addi r6,r6,4
	bdnz 1b
	bl fpdisable
	lwz r0,36(r1)
	mtlr r0
	addi r1,r1,32
	blr

	/*
	* Vector subtract, floating point.
	*/
	.globl vsubfp
	vsubfp:
	stwu r1,-32(r1)
	mflr r0
	stw r0,36(r1)
	bl fpenable
	li r0,4
	mtctr r0
	li r6,0
	1: lfsx fr0,r4,r6
	lfsx fr1,r5,r6
	fsubs fr0,fr0,fr1
	stfsx fr0,r3,r6
	addi r6,r6,4
	bdnz 1b
	bl fpdisable
	lwz r0,36(r1)
	mtlr r0
	addi r1,r1,32
	blr

	/*
	* Vector multiply and add, floating point.
	*/
	.globl vmaddfp
	vmaddfp:
	stwu r1,-48(r1)
	mflr r0
	stw r0,52(r1)
	bl fpenable
	stfd fr2,32(r1)
	li r0,4
	mtctr r0
	li r7,0
	1: lfsx fr0,r4,r7
	lfsx fr1,r5,r7
	lfsx fr2,r6,r7
	fmadds fr0,fr0,fr2,fr1
	stfsx fr0,r3,r7
	addi r7,r7,4
	bdnz 1b
	lfd fr2,32(r1)
	bl fpdisable
	lwz r0,52(r1)
	mtlr r0
	addi r1,r1,48
	blr

	/*
	* Vector negative multiply and subtract, floating point.
	*/
	.globl vnmsubfp
	vnmsubfp:
	stwu r1,-48(r1)
	mflr r0
	stw r0,52(r1)
	bl fpenable
	stfd fr2,32(r1)
	li r0,4
	mtctr r0
	li r7,0
	1: lfsx fr0,r4,r7
	lfsx fr1,r5,r7
	lfsx fr2,r6,r7
	fnmsubs fr0,fr0,fr2,fr1
	stfsx fr0,r3,r7
	addi r7,r7,4
	bdnz 1b
	lfd fr2,32(r1)
	bl fpdisable
	lwz r0,52(r1)
	mtlr r0
	addi r1,r1,48
	blr

	/*
	* Vector reciprocal estimate. We just compute 1.0/x.
	* r3 -> destination, r4 -> source.
	*/
	.globl vrefp
	vrefp:
	stwu r1,-32(r1)
	mflr r0
	stw r0,36(r1)
	bl fpenable
	lis r9,fpone@ha
	li r0,4
	lfs fr1,fpone@l(r9)
	mtctr r0
	li r6,0
	1: lfsx fr0,r4,r6
	fdivs fr0,fr1,fr0
	stfsx fr0,r3,r6
	addi r6,r6,4
	bdnz 1b
	bl fpdisable
	lwz r0,36(r1)
	mtlr r0
	addi r1,r1,32
	blr

	/*
	* Vector reciprocal square-root estimate, floating point.
	* We use the frsqrte instruction for the initial estimate followed
	* by 2 iterations of Newton-Raphson to get sufficient accuracy.
	* r3 -> destination, r4 -> source.
	*/
	.globl vrsqrtefp
	vrsqrtefp:
	stwu r1,-48(r1)
	mflr r0
	stw r0,52(r1)
	bl fpenable
	stfd fr2,32(r1)
	stfd fr3,40(r1)
	stfd fr4,48(r1)
	stfd fr5,56(r1)
	lis r9,fpone@ha
	lis r8,fphalf@ha
	li r0,4
	lfs fr4,fpone@l(r9)
	lfs fr5,fphalf@l(r8)
	mtctr r0
	li r6,0
	1: lfsx fr0,r4,r6
	frsqrte fr1,fr0 /* r = frsqrte(s) */
	fmuls fr3,fr1,fr0 /* r * s */
	fmuls fr2,fr1,fr5 /* r * 0.5 */
	fnmsubs fr3,fr1,fr3,fr4 /* 1 - s * r * r */
	fmadds fr1,fr2,fr3,fr1 /* r = r + 0.5 * r * (1 - s * r * r) */
	fmuls fr3,fr1,fr0 /* r * s */
	fmuls fr2,fr1,fr5 /* r * 0.5 */
	fnmsubs fr3,fr1,fr3,fr4 /* 1 - s * r * r */
	fmadds fr1,fr2,fr3,fr1 /* r = r + 0.5 * r * (1 - s * r * r) */
	stfsx fr1,r3,r6
	addi r6,r6,4
	bdnz 1b
	lfd fr5,56(r1)
	lfd fr4,48(r1)
	lfd fr3,40(r1)
	lfd fr2,32(r1)
	bl fpdisable
	lwz r0,36(r1)
	mtlr r0
	addi r1,r1,32
	blr