src/cmd/compile/internal/ssa/_gen/PPC64latelower.rules - go - Git at Google

 // Copyright 2022 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.

 // This file contains rules used by the laterLower pass.

 // Simplify ISEL x $0 z into ISELZ
 (ISEL [a] x (MOVDconst [0]) z) => (ISELZ [a] x z)
 // Simplify ISEL $0 y z into ISELZ by inverting comparison and reversing arguments.
 (ISEL [a] (MOVDconst [0]) y z) => (ISELZ [a^0x4] y z)

 // SETBC, SETBCR is supported on ISA 3.1(Power10) and newer, use ISELZ for
 // older targets
 (SETBC [2] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [2] (MOVDconst [1]) cmp)
 (SETBCR [2] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [6] (MOVDconst [1]) cmp)
 (SETBC [0] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [0] (MOVDconst [1]) cmp)
 (SETBCR [0] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [4] (MOVDconst [1]) cmp)
 (SETBC [1] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [1] (MOVDconst [1]) cmp)
 (SETBCR [1] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [5] (MOVDconst [1]) cmp)

 // Avoid using ANDCCconst if the value for CR0 is not needed, since ANDCCconst
 // always sets it.
 (Select0 z:(ANDCCconst [m] x)) && z.Uses == 1 && isPPC64ValidShiftMask(m) => (RLDICL [encodePPC64RotateMask(0,m,64)] x)
 // The upper bits of the smaller than register values is undefined. Take advantage of that.
 (AND <t> x:(MOVDconst [m]) n) && t.Size() <= 2 => (Select0 (ANDCCconst [int64(int16(m))] n))

 // Convert simple bit masks to an equivalent rldic[lr] if possible.
 (AND x:(MOVDconst [m]) n) && isPPC64ValidShiftMask(m) => (RLDICL [encodePPC64RotateMask(0,m,64)] n)
 (AND x:(MOVDconst [m]) n) && m != 0 && isPPC64ValidShiftMask(^m) => (RLDICR [encodePPC64RotateMask(0,m,64)] n)

 // If the RLDICL does not rotate its value, a shifted value can be merged.
 (RLDICL [em] x:(SRDconst [s] a)) && (em&0xFF0000) == 0 => (RLDICL [mergePPC64RLDICLandSRDconst(em, s)] a)

 // Convert rotated 32 bit masks on 32 bit values into rlwinm. In general, this leaves the upper 32 bits in an undefined state.
 (AND <t> x:(MOVDconst [m]) n) && t.Size() == 4 && isPPC64WordRotateMask(m) => (RLWINM [encodePPC64RotateMask(0,m,32)] n)

 // When PCRel is supported, paddi can add a 34b signed constant in one instruction.
 (ADD (MOVDconst [m]) x) && supportsPPC64PCRel() && (m<<30)>>30 == m => (ADDconst [m] x)


 // Where possible and practical, generate CC opcodes. Due to the structure of the rules, there are limits to how
 // a Value can be rewritten which make it impossible to correctly rewrite sibling Value users. To workaround this
 // case, candidates for CC opcodes are converted in two steps:
 //   1. Convert all (x (Op ...) ...) into (x (Select0 (OpCC ...) ...). See convertPPC64OpToOpCC for more
 //      detail on how and why this is done there.
 //   2. Rewrite (CMPconst [0] (Select0 (OpCC ...))) into (Select1 (OpCC...))
 // Note: to minimize potentially expensive regeneration of CC opcodes during the flagalloc pass, only rewrite if
 //       both ops are in the same block.
 (CMPconst [0] z:((ADD|AND|ANDN|OR|SUB|NOR|XOR) x y)) && v.Block == z.Block => (CMPconst [0] convertPPC64OpToOpCC(z))
 (CMPconst [0] z:((NEG|CNTLZD) x)) && v.Block == z.Block => (CMPconst [0] convertPPC64OpToOpCC(z))
 // Note: ADDCCconst only assembles to 1 instruction for int16 constants.
 (CMPconst [0] z:(ADDconst [c] x)) && int64(int16(c)) == c && v.Block == z.Block => (CMPconst [0] convertPPC64OpToOpCC(z))
 // And finally, fixup the flag user.
 (CMPconst <t> [0] (Select0 z:((ADD|AND|ANDN|OR|SUB|NOR|XOR)CC x y))) => (Select1 <t> z)
 (CMPconst <t> [0] (Select0 z:((ADDCCconst|NEGCC|CNTLZDCC) y))) => (Select1 <t> z)
	// Copyright 2022 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.

	// This file contains rules used by the laterLower pass.

	// Simplify ISEL x $0 z into ISELZ
	(ISEL [a] x (MOVDconst [0]) z) => (ISELZ [a] x z)
	// Simplify ISEL $0 y z into ISELZ by inverting comparison and reversing arguments.
	(ISEL [a] (MOVDconst [0]) y z) => (ISELZ [a^0x4] y z)

	// SETBC, SETBCR is supported on ISA 3.1(Power10) and newer, use ISELZ for
	// older targets
	(SETBC [2] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [2] (MOVDconst [1]) cmp)
	(SETBCR [2] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [6] (MOVDconst [1]) cmp)
	(SETBC [0] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [0] (MOVDconst [1]) cmp)
	(SETBCR [0] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [4] (MOVDconst [1]) cmp)
	(SETBC [1] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [1] (MOVDconst [1]) cmp)
	(SETBCR [1] cmp) && buildcfg.GOPPC64 <= 9 => (ISELZ [5] (MOVDconst [1]) cmp)

	// Avoid using ANDCCconst if the value for CR0 is not needed, since ANDCCconst
	// always sets it.
	(Select0 z:(ANDCCconst [m] x)) && z.Uses == 1 && isPPC64ValidShiftMask(m) => (RLDICL [encodePPC64RotateMask(0,m,64)] x)
	// The upper bits of the smaller than register values is undefined. Take advantage of that.
	(AND <t> x:(MOVDconst [m]) n) && t.Size() <= 2 => (Select0 (ANDCCconst [int64(int16(m))] n))

	// Convert simple bit masks to an equivalent rldic[lr] if possible.
	(AND x:(MOVDconst [m]) n) && isPPC64ValidShiftMask(m) => (RLDICL [encodePPC64RotateMask(0,m,64)] n)
	(AND x:(MOVDconst [m]) n) && m != 0 && isPPC64ValidShiftMask(^m) => (RLDICR [encodePPC64RotateMask(0,m,64)] n)

	// If the RLDICL does not rotate its value, a shifted value can be merged.
	(RLDICL [em] x:(SRDconst [s] a)) && (em&0xFF0000) == 0 => (RLDICL [mergePPC64RLDICLandSRDconst(em, s)] a)

	// Convert rotated 32 bit masks on 32 bit values into rlwinm. In general, this leaves the upper 32 bits in an undefined state.
	(AND <t> x:(MOVDconst [m]) n) && t.Size() == 4 && isPPC64WordRotateMask(m) => (RLWINM [encodePPC64RotateMask(0,m,32)] n)

	// When PCRel is supported, paddi can add a 34b signed constant in one instruction.
	(ADD (MOVDconst [m]) x) && supportsPPC64PCRel() && (m<<30)>>30 == m => (ADDconst [m] x)


	// Where possible and practical, generate CC opcodes. Due to the structure of the rules, there are limits to how
	// a Value can be rewritten which make it impossible to correctly rewrite sibling Value users. To workaround this
	// case, candidates for CC opcodes are converted in two steps:
	// 1. Convert all (x (Op ...) ...) into (x (Select0 (OpCC ...) ...). See convertPPC64OpToOpCC for more
	// detail on how and why this is done there.
	// 2. Rewrite (CMPconst [0] (Select0 (OpCC ...))) into (Select1 (OpCC...))
	// Note: to minimize potentially expensive regeneration of CC opcodes during the flagalloc pass, only rewrite if
	// both ops are in the same block.
	(CMPconst [0] z:((ADD\|AND\|ANDN\|OR\|SUB\|NOR\|XOR) x y)) && v.Block == z.Block => (CMPconst [0] convertPPC64OpToOpCC(z))
	(CMPconst [0] z:((NEG\|CNTLZD) x)) && v.Block == z.Block => (CMPconst [0] convertPPC64OpToOpCC(z))
	// Note: ADDCCconst only assembles to 1 instruction for int16 constants.
	(CMPconst [0] z:(ADDconst [c] x)) && int64(int16(c)) == c && v.Block == z.Block => (CMPconst [0] convertPPC64OpToOpCC(z))
	// And finally, fixup the flag user.
	(CMPconst <t> [0] (Select0 z:((ADD\|AND\|ANDN\|OR\|SUB\|NOR\|XOR)CC x y))) => (Select1 <t> z)
	(CMPconst <t> [0] (Select0 z:((ADDCCconst\|NEGCC\|CNTLZDCC) y))) => (Select1 <t> z)