src/runtime/memclr_ppc64x.s - go - Git at Google

 // Copyright 2014 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 //go:build ppc64 || ppc64le

 #include "textflag.h"

 // See memclrNoHeapPointers Go doc for important implementation constraints.

 // func memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr)
 TEXT runtime·memclrNoHeapPointers<ABIInternal>(SB), NOSPLIT|NOFRAME, $0-16
 	// R3 = ptr
 	// R4 = n

 	// Determine if there are doublewords to clear
 check:
 	ANDCC $7, R4, R5  // R5: leftover bytes to clear
 	SRD   $3, R4, R6  // R6: double words to clear
 	CMP   R6, $0, CR1 // CR1[EQ] set if no double words

 	BC    12, 6, nozerolarge // only single bytes
 	CMP   R4, $512
 	BLT   under512           // special case for < 512
 	ANDCC $127, R3, R8       // check for 128 alignment of address
 	BEQ   zero512setup

 	ANDCC $7, R3, R15
 	BEQ   zero512xsetup // at least 8 byte aligned

 	// zero bytes up to 8 byte alignment

 	ANDCC $1, R3, R15 // check for byte alignment
 	BEQ   byte2
 	MOVB  R0, 0(R3)   // zero 1 byte
 	ADD   $1, R3      // bump ptr by 1
 	ADD   $-1, R4

 byte2:
 	ANDCC $2, R3, R15 // check for 2 byte alignment
 	BEQ   byte4
 	MOVH  R0, 0(R3)   // zero 2 bytes
 	ADD   $2, R3      // bump ptr by 2
 	ADD   $-2, R4

 byte4:
 	ANDCC $4, R3, R15   // check for 4 byte alignment
 	BEQ   zero512xsetup
 	MOVW  R0, 0(R3)     // zero 4 bytes
 	ADD   $4, R3        // bump ptr by 4
 	ADD   $-4, R4
 	BR    zero512xsetup // ptr should now be 8 byte aligned

 under512:
 	SRDCC $3, R6, R7  // 64 byte chunks?
 	XXLXOR VS32, VS32, VS32 // clear VS32 (V0)
 	BEQ   lt64gt8

 	// Prepare to clear 64 bytes at a time.

 zero64setup:
 	DCBTST (R3)             // prepare data cache
 	MOVD   R7, CTR          // number of 64 byte chunks
 	MOVD   $16, R8
 	MOVD   $32, R16
 	MOVD   $48, R17

 zero64:
 	STXVD2X VS32, (R3+R0)   // store 16 bytes
 	STXVD2X VS32, (R3+R8)
 	STXVD2X VS32, (R3+R16)
 	STXVD2X VS32, (R3+R17)
 	ADD     $64, R3
 	ADD     $-64, R4
 	BDNZ    zero64          // dec ctr, br zero64 if ctr not 0
 	SRDCC   $3, R4, R6	// remaining doublewords
 	BEQ     nozerolarge

 lt64gt8:
 	CMP	R4, $32
 	BLT	lt32gt8
 	MOVD	$16, R8
 	STXVD2X	VS32, (R3+R0)
 	STXVD2X	VS32, (R3+R8)
 	ADD	$-32, R4
 	ADD	$32, R3
 lt32gt8:
 	CMP	R4, $16
 	BLT	lt16gt8
 	STXVD2X	VS32, (R3+R0)
 	ADD	$16, R3
 	ADD	$-16, R4
 lt16gt8:
 #ifdef GOPPC64_power10
 	SLD	$56, R4, R7
 	STXVL   V0, R3, R7
 	RET
 #else
 	CMP	R4, $8
 	BLT	nozerolarge
 	MOVD	R0, 0(R3)
 	ADD	$8, R3
 	ADD	$-8, R4
 #endif
 nozerolarge:
 	ANDCC $7, R4, R5 // any remaining bytes
 	BC    4, 1, LR   // ble lr
 #ifdef GOPPC64_power10
 	XXLXOR  VS32, VS32, VS32 // clear VS32 (V0)
 	SLD	$56, R5, R7
 	STXVL   V0, R3, R7
 	RET
 #else
 	CMP   R5, $4
 	BLT   next2
 	MOVW  R0, 0(R3)
 	ADD   $4, R3
 	ADD   $-4, R5
 next2:
 	CMP   R5, $2
 	BLT   next1
 	MOVH  R0, 0(R3)
 	ADD   $2, R3
 	ADD   $-2, R5
 next1:
 	CMP   R5, $0
 	BC    12, 2, LR      // beqlr
 	MOVB  R0, 0(R3)
 	RET
 #endif

 zero512xsetup:  // 512 chunk with extra needed
 	ANDCC $8, R3, R11    // 8 byte alignment?
 	BEQ   zero512setup16
 	MOVD  R0, 0(R3)      // clear 8 bytes
 	ADD   $8, R3         // update ptr to next 8
 	ADD   $-8, R4        // dec count by 8

 zero512setup16:
 	ANDCC $127, R3, R14 // < 128 byte alignment
 	BEQ   zero512setup  // handle 128 byte alignment
 	MOVD  $128, R15
 	SUB   R14, R15, R14 // find increment to 128 alignment
 	SRD   $4, R14, R15  // number of 16 byte chunks
 	MOVD   R15, CTR         // loop counter of 16 bytes
 	XXLXOR VS32, VS32, VS32 // clear VS32 (V0)

 zero512preloop:  // clear up to 128 alignment
 	STXVD2X VS32, (R3+R0)         // clear 16 bytes
 	ADD     $16, R3               // update ptr
 	ADD     $-16, R4              // dec count
 	BDNZ    zero512preloop

 zero512setup:  // setup for dcbz loop
 	CMP  R4, $512   // check if at least 512
 	BLT  remain
 	SRD  $9, R4, R8 // loop count for 512 chunks
 	MOVD R8, CTR    // set up counter
 	MOVD $128, R9   // index regs for 128 bytes
 	MOVD $256, R10
 	MOVD $384, R11
 	PCALIGN $16
 zero512:
 	DCBZ (R3+R0)        // clear first chunk
 	DCBZ (R3+R9)        // clear second chunk
 	DCBZ (R3+R10)       // clear third chunk
 	DCBZ (R3+R11)       // clear fourth chunk
 	ADD  $512, R3
 	BDNZ zero512
 	ANDCC $511, R4

 remain:
 	CMP  R4, $128  // check if 128 byte chunks left
 	BLT  smaller
 	DCBZ (R3+R0)   // clear 128
 	ADD  $128, R3
 	ADD  $-128, R4
 	BR   remain

 smaller:
 	ANDCC $127, R4, R7 // find leftovers
 	BEQ   done
 	CMP   R7, $64      // more than 64, do 64 at a time
 	XXLXOR VS32, VS32, VS32
 	BLT   lt64gt8	   // less than 64
 	SRD   $6, R7, R7   // set up counter for 64
 	BR    zero64setup

 done:
 	RET
	// Copyright 2014 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	//go:build ppc64 \|\| ppc64le

	#include "textflag.h"

	// See memclrNoHeapPointers Go doc for important implementation constraints.

	// func memclrNoHeapPointers(ptr unsafe.Pointer, n uintptr)
	TEXT runtime·memclrNoHeapPointers<ABIInternal>(SB), NOSPLIT\|NOFRAME, $0-16
	// R3 = ptr
	// R4 = n

	// Determine if there are doublewords to clear
	check:
	ANDCC $7, R4, R5 // R5: leftover bytes to clear
	SRD $3, R4, R6 // R6: double words to clear
	CMP R6, $0, CR1 // CR1[EQ] set if no double words

	BC 12, 6, nozerolarge // only single bytes
	CMP R4, $512
	BLT under512 // special case for < 512
	ANDCC $127, R3, R8 // check for 128 alignment of address
	BEQ zero512setup

	ANDCC $7, R3, R15
	BEQ zero512xsetup // at least 8 byte aligned

	// zero bytes up to 8 byte alignment

	ANDCC $1, R3, R15 // check for byte alignment
	BEQ byte2
	MOVB R0, 0(R3) // zero 1 byte
	ADD $1, R3 // bump ptr by 1
	ADD $-1, R4

	byte2:
	ANDCC $2, R3, R15 // check for 2 byte alignment
	BEQ byte4
	MOVH R0, 0(R3) // zero 2 bytes
	ADD $2, R3 // bump ptr by 2
	ADD $-2, R4

	byte4:
	ANDCC $4, R3, R15 // check for 4 byte alignment
	BEQ zero512xsetup
	MOVW R0, 0(R3) // zero 4 bytes
	ADD $4, R3 // bump ptr by 4
	ADD $-4, R4
	BR zero512xsetup // ptr should now be 8 byte aligned

	under512:
	SRDCC $3, R6, R7 // 64 byte chunks?
	XXLXOR VS32, VS32, VS32 // clear VS32 (V0)
	BEQ lt64gt8

	// Prepare to clear 64 bytes at a time.

	zero64setup:
	DCBTST (R3) // prepare data cache
	MOVD R7, CTR // number of 64 byte chunks
	MOVD $16, R8
	MOVD $32, R16
	MOVD $48, R17

	zero64:
	STXVD2X VS32, (R3+R0) // store 16 bytes
	STXVD2X VS32, (R3+R8)
	STXVD2X VS32, (R3+R16)
	STXVD2X VS32, (R3+R17)
	ADD $64, R3
	ADD $-64, R4
	BDNZ zero64 // dec ctr, br zero64 if ctr not 0
	SRDCC $3, R4, R6 // remaining doublewords
	BEQ nozerolarge

	lt64gt8:
	CMP R4, $32
	BLT lt32gt8
	MOVD $16, R8
	STXVD2X VS32, (R3+R0)
	STXVD2X VS32, (R3+R8)
	ADD $-32, R4
	ADD $32, R3
	lt32gt8:
	CMP R4, $16
	BLT lt16gt8
	STXVD2X VS32, (R3+R0)
	ADD $16, R3
	ADD $-16, R4
	lt16gt8:
	#ifdef GOPPC64_power10
	SLD $56, R4, R7
	STXVL V0, R3, R7
	RET
	#else
	CMP R4, $8
	BLT nozerolarge
	MOVD R0, 0(R3)
	ADD $8, R3
	ADD $-8, R4
	#endif
	nozerolarge:
	ANDCC $7, R4, R5 // any remaining bytes
	BC 4, 1, LR // ble lr
	#ifdef GOPPC64_power10
	XXLXOR VS32, VS32, VS32 // clear VS32 (V0)
	SLD $56, R5, R7
	STXVL V0, R3, R7
	RET
	#else
	CMP R5, $4
	BLT next2
	MOVW R0, 0(R3)
	ADD $4, R3
	ADD $-4, R5
	next2:
	CMP R5, $2
	BLT next1
	MOVH R0, 0(R3)
	ADD $2, R3
	ADD $-2, R5
	next1:
	CMP R5, $0
	BC 12, 2, LR // beqlr
	MOVB R0, 0(R3)
	RET
	#endif

	zero512xsetup: // 512 chunk with extra needed
	ANDCC $8, R3, R11 // 8 byte alignment?
	BEQ zero512setup16
	MOVD R0, 0(R3) // clear 8 bytes
	ADD $8, R3 // update ptr to next 8
	ADD $-8, R4 // dec count by 8

	zero512setup16:
	ANDCC $127, R3, R14 // < 128 byte alignment
	BEQ zero512setup // handle 128 byte alignment
	MOVD $128, R15
	SUB R14, R15, R14 // find increment to 128 alignment
	SRD $4, R14, R15 // number of 16 byte chunks
	MOVD R15, CTR // loop counter of 16 bytes
	XXLXOR VS32, VS32, VS32 // clear VS32 (V0)

	zero512preloop: // clear up to 128 alignment
	STXVD2X VS32, (R3+R0) // clear 16 bytes
	ADD $16, R3 // update ptr
	ADD $-16, R4 // dec count
	BDNZ zero512preloop

	zero512setup: // setup for dcbz loop
	CMP R4, $512 // check if at least 512
	BLT remain
	SRD $9, R4, R8 // loop count for 512 chunks
	MOVD R8, CTR // set up counter
	MOVD $128, R9 // index regs for 128 bytes
	MOVD $256, R10
	MOVD $384, R11
	PCALIGN $16
	zero512:
	DCBZ (R3+R0) // clear first chunk
	DCBZ (R3+R9) // clear second chunk
	DCBZ (R3+R10) // clear third chunk
	DCBZ (R3+R11) // clear fourth chunk
	ADD $512, R3
	BDNZ zero512
	ANDCC $511, R4

	remain:
	CMP R4, $128 // check if 128 byte chunks left
	BLT smaller
	DCBZ (R3+R0) // clear 128
	ADD $128, R3
	ADD $-128, R4
	BR remain

	smaller:
	ANDCC $127, R4, R7 // find leftovers
	BEQ done
	CMP R7, $64 // more than 64, do 64 at a time
	XXLXOR VS32, VS32, VS32
	BLT lt64gt8 // less than 64
	SRD $6, R7, R7 // set up counter for 64
	BR zero64setup

	done:
	RET