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llvm-mirror/lib/Target/X86/X86InstrCompiler.td
Craig Topper bc85d31f23 [X86] Use btc/btr/bts to implement xor/and/or that affects a single bit in the upper 32-bits of a 64-bit operation.
We can't fold a large immediate into a 64-bit operation. But if we know we're only operating on a single bit we can use the bit instructions.

For now only do this for optsize.

Differential Revision: https://reviews.llvm.org/D37418

llvm-svn: 325287
2018-02-15 19:57:35 +00:00

2076 lines
92 KiB
TableGen

//===- X86InstrCompiler.td - Compiler Pseudos and Patterns -*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file describes the various pseudo instructions used by the compiler,
// as well as Pat patterns used during instruction selection.
//
//===----------------------------------------------------------------------===//
//===----------------------------------------------------------------------===//
// Pattern Matching Support
def GetLo32XForm : SDNodeXForm<imm, [{
// Transformation function: get the low 32 bits.
return getI32Imm((unsigned)N->getZExtValue(), SDLoc(N));
}]>;
def GetLo8XForm : SDNodeXForm<imm, [{
// Transformation function: get the low 8 bits.
return getI8Imm((uint8_t)N->getZExtValue(), SDLoc(N));
}]>;
//===----------------------------------------------------------------------===//
// Random Pseudo Instructions.
// PIC base construction. This expands to code that looks like this:
// call $next_inst
// popl %destreg"
let hasSideEffects = 0, isNotDuplicable = 1, Uses = [ESP, SSP],
SchedRW = [WriteJump] in
def MOVPC32r : Ii32<0xE8, Pseudo, (outs GR32:$reg), (ins i32imm:$label),
"", [], IIC_CALL_RI>;
// ADJCALLSTACKDOWN/UP implicitly use/def ESP because they may be expanded into
// a stack adjustment and the codegen must know that they may modify the stack
// pointer before prolog-epilog rewriting occurs.
// Pessimistically assume ADJCALLSTACKDOWN / ADJCALLSTACKUP will become
// sub / add which can clobber EFLAGS.
let Defs = [ESP, EFLAGS, SSP], Uses = [ESP, SSP], SchedRW = [WriteALU] in {
def ADJCALLSTACKDOWN32 : I<0, Pseudo, (outs),
(ins i32imm:$amt1, i32imm:$amt2, i32imm:$amt3),
"#ADJCALLSTACKDOWN", [], IIC_ALU_NONMEM>,
Requires<[NotLP64]>;
def ADJCALLSTACKUP32 : I<0, Pseudo, (outs), (ins i32imm:$amt1, i32imm:$amt2),
"#ADJCALLSTACKUP",
[(X86callseq_end timm:$amt1, timm:$amt2)],
IIC_ALU_NONMEM>, Requires<[NotLP64]>;
}
def : Pat<(X86callseq_start timm:$amt1, timm:$amt2),
(ADJCALLSTACKDOWN32 i32imm:$amt1, i32imm:$amt2, 0)>, Requires<[NotLP64]>;
// ADJCALLSTACKDOWN/UP implicitly use/def RSP because they may be expanded into
// a stack adjustment and the codegen must know that they may modify the stack
// pointer before prolog-epilog rewriting occurs.
// Pessimistically assume ADJCALLSTACKDOWN / ADJCALLSTACKUP will become
// sub / add which can clobber EFLAGS.
let Defs = [RSP, EFLAGS, SSP], Uses = [RSP, SSP], SchedRW = [WriteALU] in {
def ADJCALLSTACKDOWN64 : I<0, Pseudo, (outs),
(ins i32imm:$amt1, i32imm:$amt2, i32imm:$amt3),
"#ADJCALLSTACKDOWN",
[], IIC_ALU_NONMEM>, Requires<[IsLP64]>;
def ADJCALLSTACKUP64 : I<0, Pseudo, (outs), (ins i32imm:$amt1, i32imm:$amt2),
"#ADJCALLSTACKUP",
[(X86callseq_end timm:$amt1, timm:$amt2)],
IIC_ALU_NONMEM>, Requires<[IsLP64]>;
}
def : Pat<(X86callseq_start timm:$amt1, timm:$amt2),
(ADJCALLSTACKDOWN64 i32imm:$amt1, i32imm:$amt2, 0)>, Requires<[IsLP64]>;
let SchedRW = [WriteSystem] in {
// x86-64 va_start lowering magic.
let usesCustomInserter = 1, Defs = [EFLAGS] in {
def VASTART_SAVE_XMM_REGS : I<0, Pseudo,
(outs),
(ins GR8:$al,
i64imm:$regsavefi, i64imm:$offset,
variable_ops),
"#VASTART_SAVE_XMM_REGS $al, $regsavefi, $offset",
[(X86vastart_save_xmm_regs GR8:$al,
imm:$regsavefi,
imm:$offset),
(implicit EFLAGS)]>;
// The VAARG_64 pseudo-instruction takes the address of the va_list,
// and places the address of the next argument into a register.
let Defs = [EFLAGS] in
def VAARG_64 : I<0, Pseudo,
(outs GR64:$dst),
(ins i8mem:$ap, i32imm:$size, i8imm:$mode, i32imm:$align),
"#VAARG_64 $dst, $ap, $size, $mode, $align",
[(set GR64:$dst,
(X86vaarg64 addr:$ap, imm:$size, imm:$mode, imm:$align)),
(implicit EFLAGS)]>;
// When using segmented stacks these are lowered into instructions which first
// check if the current stacklet has enough free memory. If it does, memory is
// allocated by bumping the stack pointer. Otherwise memory is allocated from
// the heap.
let Defs = [EAX, ESP, EFLAGS], Uses = [ESP] in
def SEG_ALLOCA_32 : I<0, Pseudo, (outs GR32:$dst), (ins GR32:$size),
"# variable sized alloca for segmented stacks",
[(set GR32:$dst,
(X86SegAlloca GR32:$size))]>,
Requires<[NotLP64]>;
let Defs = [RAX, RSP, EFLAGS], Uses = [RSP] in
def SEG_ALLOCA_64 : I<0, Pseudo, (outs GR64:$dst), (ins GR64:$size),
"# variable sized alloca for segmented stacks",
[(set GR64:$dst,
(X86SegAlloca GR64:$size))]>,
Requires<[In64BitMode]>;
}
// Dynamic stack allocation yields a _chkstk or _alloca call for all Windows
// targets. These calls are needed to probe the stack when allocating more than
// 4k bytes in one go. Touching the stack at 4K increments is necessary to
// ensure that the guard pages used by the OS virtual memory manager are
// allocated in correct sequence.
// The main point of having separate instruction are extra unmodelled effects
// (compared to ordinary calls) like stack pointer change.
let Defs = [EAX, ESP, EFLAGS], Uses = [ESP] in
def WIN_ALLOCA_32 : I<0, Pseudo, (outs), (ins GR32:$size),
"# dynamic stack allocation",
[(X86WinAlloca GR32:$size)]>,
Requires<[NotLP64]>;
let Defs = [RAX, RSP, EFLAGS], Uses = [RSP] in
def WIN_ALLOCA_64 : I<0, Pseudo, (outs), (ins GR64:$size),
"# dynamic stack allocation",
[(X86WinAlloca GR64:$size)]>,
Requires<[In64BitMode]>;
} // SchedRW
// These instructions XOR the frame pointer into a GPR. They are used in some
// stack protection schemes. These are post-RA pseudos because we only know the
// frame register after register allocation.
let Constraints = "$src = $dst", isPseudo = 1, Defs = [EFLAGS] in {
def XOR32_FP : I<0, Pseudo, (outs GR32:$dst), (ins GR32:$src),
"xorl\t$$FP, $src", [], IIC_BIN_NONMEM>,
Requires<[NotLP64]>, Sched<[WriteALU]>;
def XOR64_FP : I<0, Pseudo, (outs GR64:$dst), (ins GR64:$src),
"xorq\t$$FP $src", [], IIC_BIN_NONMEM>,
Requires<[In64BitMode]>, Sched<[WriteALU]>;
}
//===----------------------------------------------------------------------===//
// EH Pseudo Instructions
//
let SchedRW = [WriteSystem] in {
let isTerminator = 1, isReturn = 1, isBarrier = 1,
hasCtrlDep = 1, isCodeGenOnly = 1 in {
def EH_RETURN : I<0xC3, RawFrm, (outs), (ins GR32:$addr),
"ret\t#eh_return, addr: $addr",
[(X86ehret GR32:$addr)], IIC_RET>, Sched<[WriteJumpLd]>;
}
let isTerminator = 1, isReturn = 1, isBarrier = 1,
hasCtrlDep = 1, isCodeGenOnly = 1 in {
def EH_RETURN64 : I<0xC3, RawFrm, (outs), (ins GR64:$addr),
"ret\t#eh_return, addr: $addr",
[(X86ehret GR64:$addr)], IIC_RET>, Sched<[WriteJumpLd]>;
}
let isTerminator = 1, hasSideEffects = 1, isBarrier = 1, hasCtrlDep = 1,
isCodeGenOnly = 1, isReturn = 1 in {
def CLEANUPRET : I<0, Pseudo, (outs), (ins), "# CLEANUPRET", [(cleanupret)]>;
// CATCHRET needs a custom inserter for SEH.
let usesCustomInserter = 1 in
def CATCHRET : I<0, Pseudo, (outs), (ins brtarget32:$dst, brtarget32:$from),
"# CATCHRET",
[(catchret bb:$dst, bb:$from)]>;
}
let hasSideEffects = 1, hasCtrlDep = 1, isCodeGenOnly = 1,
usesCustomInserter = 1 in
def CATCHPAD : I<0, Pseudo, (outs), (ins), "# CATCHPAD", [(catchpad)]>;
// This instruction is responsible for re-establishing stack pointers after an
// exception has been caught and we are rejoining normal control flow in the
// parent function or funclet. It generally sets ESP and EBP, and optionally
// ESI. It is only needed for 32-bit WinEH, as the runtime restores CSRs for us
// elsewhere.
let hasSideEffects = 1, hasCtrlDep = 1, isCodeGenOnly = 1 in
def EH_RESTORE : I<0, Pseudo, (outs), (ins), "# EH_RESTORE", []>;
let hasSideEffects = 1, isBarrier = 1, isCodeGenOnly = 1,
usesCustomInserter = 1 in {
def EH_SjLj_SetJmp32 : I<0, Pseudo, (outs GR32:$dst), (ins i32mem:$buf),
"#EH_SJLJ_SETJMP32",
[(set GR32:$dst, (X86eh_sjlj_setjmp addr:$buf))]>,
Requires<[Not64BitMode]>;
def EH_SjLj_SetJmp64 : I<0, Pseudo, (outs GR32:$dst), (ins i64mem:$buf),
"#EH_SJLJ_SETJMP64",
[(set GR32:$dst, (X86eh_sjlj_setjmp addr:$buf))]>,
Requires<[In64BitMode]>;
let isTerminator = 1 in {
def EH_SjLj_LongJmp32 : I<0, Pseudo, (outs), (ins i32mem:$buf),
"#EH_SJLJ_LONGJMP32",
[(X86eh_sjlj_longjmp addr:$buf)]>,
Requires<[Not64BitMode]>;
def EH_SjLj_LongJmp64 : I<0, Pseudo, (outs), (ins i64mem:$buf),
"#EH_SJLJ_LONGJMP64",
[(X86eh_sjlj_longjmp addr:$buf)]>,
Requires<[In64BitMode]>;
}
}
let isBranch = 1, isTerminator = 1, isCodeGenOnly = 1 in {
def EH_SjLj_Setup : I<0, Pseudo, (outs), (ins brtarget:$dst),
"#EH_SjLj_Setup\t$dst", []>;
}
} // SchedRW
//===----------------------------------------------------------------------===//
// Pseudo instructions used by unwind info.
//
let isPseudo = 1, SchedRW = [WriteSystem] in {
def SEH_PushReg : I<0, Pseudo, (outs), (ins i32imm:$reg),
"#SEH_PushReg $reg", []>;
def SEH_SaveReg : I<0, Pseudo, (outs), (ins i32imm:$reg, i32imm:$dst),
"#SEH_SaveReg $reg, $dst", []>;
def SEH_SaveXMM : I<0, Pseudo, (outs), (ins i32imm:$reg, i32imm:$dst),
"#SEH_SaveXMM $reg, $dst", []>;
def SEH_StackAlloc : I<0, Pseudo, (outs), (ins i32imm:$size),
"#SEH_StackAlloc $size", []>;
def SEH_SetFrame : I<0, Pseudo, (outs), (ins i32imm:$reg, i32imm:$offset),
"#SEH_SetFrame $reg, $offset", []>;
def SEH_PushFrame : I<0, Pseudo, (outs), (ins i1imm:$mode),
"#SEH_PushFrame $mode", []>;
def SEH_EndPrologue : I<0, Pseudo, (outs), (ins),
"#SEH_EndPrologue", []>;
def SEH_Epilogue : I<0, Pseudo, (outs), (ins),
"#SEH_Epilogue", []>;
}
//===----------------------------------------------------------------------===//
// Pseudo instructions used by segmented stacks.
//
// This is lowered into a RET instruction by MCInstLower. We need
// this so that we don't have to have a MachineBasicBlock which ends
// with a RET and also has successors.
let isPseudo = 1, SchedRW = [WriteJumpLd] in {
def MORESTACK_RET: I<0, Pseudo, (outs), (ins),
"", [], IIC_RET>;
// This instruction is lowered to a RET followed by a MOV. The two
// instructions are not generated on a higher level since then the
// verifier sees a MachineBasicBlock ending with a non-terminator.
def MORESTACK_RET_RESTORE_R10 : I<0, Pseudo, (outs), (ins),
"", [], IIC_RET>;
}
//===----------------------------------------------------------------------===//
// Alias Instructions
//===----------------------------------------------------------------------===//
// Alias instruction mapping movr0 to xor.
// FIXME: remove when we can teach regalloc that xor reg, reg is ok.
let Defs = [EFLAGS], isReMaterializable = 1, isAsCheapAsAMove = 1,
isPseudo = 1, AddedComplexity = 10 in
def MOV32r0 : I<0, Pseudo, (outs GR32:$dst), (ins), "",
[(set GR32:$dst, 0)], IIC_ALU_NONMEM>, Sched<[WriteZero]>;
// Other widths can also make use of the 32-bit xor, which may have a smaller
// encoding and avoid partial register updates.
let AddedComplexity = 10 in {
def : Pat<(i8 0), (EXTRACT_SUBREG (MOV32r0), sub_8bit)>;
def : Pat<(i16 0), (EXTRACT_SUBREG (MOV32r0), sub_16bit)>;
def : Pat<(i64 0), (SUBREG_TO_REG (i64 0), (MOV32r0), sub_32bit)>;
}
let Predicates = [OptForSize, Not64BitMode],
AddedComplexity = 10 in {
let SchedRW = [WriteALU] in {
// Pseudo instructions for materializing 1 and -1 using XOR+INC/DEC,
// which only require 3 bytes compared to MOV32ri which requires 5.
let Defs = [EFLAGS], isReMaterializable = 1, isPseudo = 1 in {
def MOV32r1 : I<0, Pseudo, (outs GR32:$dst), (ins), "",
[(set GR32:$dst, 1)], IIC_ALU_NONMEM>;
def MOV32r_1 : I<0, Pseudo, (outs GR32:$dst), (ins), "",
[(set GR32:$dst, -1)], IIC_ALU_NONMEM>;
}
} // SchedRW
// MOV16ri is 4 bytes, so the instructions above are smaller.
def : Pat<(i16 1), (EXTRACT_SUBREG (MOV32r1), sub_16bit)>;
def : Pat<(i16 -1), (EXTRACT_SUBREG (MOV32r_1), sub_16bit)>;
}
let isReMaterializable = 1, isPseudo = 1, AddedComplexity = 5,
SchedRW = [WriteALU] in {
// AddedComplexity higher than MOV64ri but lower than MOV32r0 and MOV32r1.
def MOV32ImmSExti8 : I<0, Pseudo, (outs GR32:$dst), (ins i32i8imm:$src), "",
[(set GR32:$dst, i32immSExt8:$src)], IIC_ALU_NONMEM>,
Requires<[OptForMinSize, NotWin64WithoutFP]>;
def MOV64ImmSExti8 : I<0, Pseudo, (outs GR64:$dst), (ins i64i8imm:$src), "",
[(set GR64:$dst, i64immSExt8:$src)], IIC_ALU_NONMEM>,
Requires<[OptForMinSize, NotWin64WithoutFP]>;
}
// Materialize i64 constant where top 32-bits are zero. This could theoretically
// use MOV32ri with a SUBREG_TO_REG to represent the zero-extension, however
// that would make it more difficult to rematerialize.
let isReMaterializable = 1, isAsCheapAsAMove = 1,
isPseudo = 1, hasSideEffects = 0, SchedRW = [WriteALU] in
def MOV32ri64 : I<0, Pseudo, (outs GR32:$dst), (ins i64i32imm:$src), "", [],
IIC_ALU_NONMEM>;
// This 64-bit pseudo-move can be used for both a 64-bit constant that is
// actually the zero-extension of a 32-bit constant and for labels in the
// x86-64 small code model.
def mov64imm32 : ComplexPattern<i64, 1, "selectMOV64Imm32", [imm, X86Wrapper]>;
let AddedComplexity = 1 in
def : Pat<(i64 mov64imm32:$src),
(SUBREG_TO_REG (i64 0), (MOV32ri64 mov64imm32:$src), sub_32bit)>;
// Use sbb to materialize carry bit.
let Uses = [EFLAGS], Defs = [EFLAGS], isPseudo = 1, SchedRW = [WriteALU] in {
// FIXME: These are pseudo ops that should be replaced with Pat<> patterns.
// However, Pat<> can't replicate the destination reg into the inputs of the
// result.
def SETB_C8r : I<0, Pseudo, (outs GR8:$dst), (ins), "",
[(set GR8:$dst, (X86setcc_c X86_COND_B, EFLAGS))]>;
def SETB_C16r : I<0, Pseudo, (outs GR16:$dst), (ins), "",
[(set GR16:$dst, (X86setcc_c X86_COND_B, EFLAGS))]>;
def SETB_C32r : I<0, Pseudo, (outs GR32:$dst), (ins), "",
[(set GR32:$dst, (X86setcc_c X86_COND_B, EFLAGS))]>;
def SETB_C64r : I<0, Pseudo, (outs GR64:$dst), (ins), "",
[(set GR64:$dst, (X86setcc_c X86_COND_B, EFLAGS))]>;
} // isCodeGenOnly
def : Pat<(i16 (anyext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C16r)>;
def : Pat<(i32 (anyext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C32r)>;
def : Pat<(i64 (anyext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C64r)>;
def : Pat<(i16 (sext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C16r)>;
def : Pat<(i32 (sext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C32r)>;
def : Pat<(i64 (sext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C64r)>;
// We canonicalize 'setb' to "(and (sbb reg,reg), 1)" on the hope that the and
// will be eliminated and that the sbb can be extended up to a wider type. When
// this happens, it is great. However, if we are left with an 8-bit sbb and an
// and, we might as well just match it as a setb.
def : Pat<(and (i8 (X86setcc_c X86_COND_B, EFLAGS)), 1),
(SETBr)>;
// (add OP, SETB) -> (adc OP, 0)
def : Pat<(add (and (i8 (X86setcc_c X86_COND_B, EFLAGS)), 1), GR8:$op),
(ADC8ri GR8:$op, 0)>;
def : Pat<(add (and (i32 (X86setcc_c X86_COND_B, EFLAGS)), 1), GR32:$op),
(ADC32ri8 GR32:$op, 0)>;
def : Pat<(add (and (i64 (X86setcc_c X86_COND_B, EFLAGS)), 1), GR64:$op),
(ADC64ri8 GR64:$op, 0)>;
// (sub OP, SETB) -> (sbb OP, 0)
def : Pat<(sub GR8:$op, (and (i8 (X86setcc_c X86_COND_B, EFLAGS)), 1)),
(SBB8ri GR8:$op, 0)>;
def : Pat<(sub GR32:$op, (and (i32 (X86setcc_c X86_COND_B, EFLAGS)), 1)),
(SBB32ri8 GR32:$op, 0)>;
def : Pat<(sub GR64:$op, (and (i64 (X86setcc_c X86_COND_B, EFLAGS)), 1)),
(SBB64ri8 GR64:$op, 0)>;
// (sub OP, SETCC_CARRY) -> (adc OP, 0)
def : Pat<(sub GR8:$op, (i8 (X86setcc_c X86_COND_B, EFLAGS))),
(ADC8ri GR8:$op, 0)>;
def : Pat<(sub GR32:$op, (i32 (X86setcc_c X86_COND_B, EFLAGS))),
(ADC32ri8 GR32:$op, 0)>;
def : Pat<(sub GR64:$op, (i64 (X86setcc_c X86_COND_B, EFLAGS))),
(ADC64ri8 GR64:$op, 0)>;
//===----------------------------------------------------------------------===//
// String Pseudo Instructions
//
let SchedRW = [WriteMicrocoded] in {
let Defs = [ECX,EDI,ESI], Uses = [ECX,EDI,ESI], isCodeGenOnly = 1 in {
def REP_MOVSB_32 : I<0xA4, RawFrm, (outs), (ins), "{rep;movsb|rep movsb}",
[(X86rep_movs i8)], IIC_REP_MOVS>, REP,
Requires<[Not64BitMode]>;
def REP_MOVSW_32 : I<0xA5, RawFrm, (outs), (ins), "{rep;movsw|rep movsw}",
[(X86rep_movs i16)], IIC_REP_MOVS>, REP, OpSize16,
Requires<[Not64BitMode]>;
def REP_MOVSD_32 : I<0xA5, RawFrm, (outs), (ins), "{rep;movsl|rep movsd}",
[(X86rep_movs i32)], IIC_REP_MOVS>, REP, OpSize32,
Requires<[Not64BitMode]>;
}
let Defs = [RCX,RDI,RSI], Uses = [RCX,RDI,RSI], isCodeGenOnly = 1 in {
def REP_MOVSB_64 : I<0xA4, RawFrm, (outs), (ins), "{rep;movsb|rep movsb}",
[(X86rep_movs i8)], IIC_REP_MOVS>, REP,
Requires<[In64BitMode]>;
def REP_MOVSW_64 : I<0xA5, RawFrm, (outs), (ins), "{rep;movsw|rep movsw}",
[(X86rep_movs i16)], IIC_REP_MOVS>, REP, OpSize16,
Requires<[In64BitMode]>;
def REP_MOVSD_64 : I<0xA5, RawFrm, (outs), (ins), "{rep;movsl|rep movsd}",
[(X86rep_movs i32)], IIC_REP_MOVS>, REP, OpSize32,
Requires<[In64BitMode]>;
def REP_MOVSQ_64 : RI<0xA5, RawFrm, (outs), (ins), "{rep;movsq|rep movsq}",
[(X86rep_movs i64)], IIC_REP_MOVS>, REP,
Requires<[In64BitMode]>;
}
// FIXME: Should use "(X86rep_stos AL)" as the pattern.
let Defs = [ECX,EDI], isCodeGenOnly = 1 in {
let Uses = [AL,ECX,EDI] in
def REP_STOSB_32 : I<0xAA, RawFrm, (outs), (ins), "{rep;stosb|rep stosb}",
[(X86rep_stos i8)], IIC_REP_STOS>, REP,
Requires<[Not64BitMode]>;
let Uses = [AX,ECX,EDI] in
def REP_STOSW_32 : I<0xAB, RawFrm, (outs), (ins), "{rep;stosw|rep stosw}",
[(X86rep_stos i16)], IIC_REP_STOS>, REP, OpSize16,
Requires<[Not64BitMode]>;
let Uses = [EAX,ECX,EDI] in
def REP_STOSD_32 : I<0xAB, RawFrm, (outs), (ins), "{rep;stosl|rep stosd}",
[(X86rep_stos i32)], IIC_REP_STOS>, REP, OpSize32,
Requires<[Not64BitMode]>;
}
let Defs = [RCX,RDI], isCodeGenOnly = 1 in {
let Uses = [AL,RCX,RDI] in
def REP_STOSB_64 : I<0xAA, RawFrm, (outs), (ins), "{rep;stosb|rep stosb}",
[(X86rep_stos i8)], IIC_REP_STOS>, REP,
Requires<[In64BitMode]>;
let Uses = [AX,RCX,RDI] in
def REP_STOSW_64 : I<0xAB, RawFrm, (outs), (ins), "{rep;stosw|rep stosw}",
[(X86rep_stos i16)], IIC_REP_STOS>, REP, OpSize16,
Requires<[In64BitMode]>;
let Uses = [RAX,RCX,RDI] in
def REP_STOSD_64 : I<0xAB, RawFrm, (outs), (ins), "{rep;stosl|rep stosd}",
[(X86rep_stos i32)], IIC_REP_STOS>, REP, OpSize32,
Requires<[In64BitMode]>;
let Uses = [RAX,RCX,RDI] in
def REP_STOSQ_64 : RI<0xAB, RawFrm, (outs), (ins), "{rep;stosq|rep stosq}",
[(X86rep_stos i64)], IIC_REP_STOS>, REP,
Requires<[In64BitMode]>;
}
} // SchedRW
//===----------------------------------------------------------------------===//
// Thread Local Storage Instructions
//
let SchedRW = [WriteSystem] in {
// ELF TLS Support
// All calls clobber the non-callee saved registers. ESP is marked as
// a use to prevent stack-pointer assignments that appear immediately
// before calls from potentially appearing dead.
let Defs = [EAX, ECX, EDX, FP0, FP1, FP2, FP3, FP4, FP5, FP6, FP7,
ST0, ST1, ST2, ST3, ST4, ST5, ST6, ST7,
MM0, MM1, MM2, MM3, MM4, MM5, MM6, MM7,
XMM0, XMM1, XMM2, XMM3, XMM4, XMM5, XMM6, XMM7,
XMM8, XMM9, XMM10, XMM11, XMM12, XMM13, XMM14, XMM15, EFLAGS],
usesCustomInserter = 1, Uses = [ESP, SSP] in {
def TLS_addr32 : I<0, Pseudo, (outs), (ins i32mem:$sym),
"# TLS_addr32",
[(X86tlsaddr tls32addr:$sym)]>,
Requires<[Not64BitMode]>;
def TLS_base_addr32 : I<0, Pseudo, (outs), (ins i32mem:$sym),
"# TLS_base_addr32",
[(X86tlsbaseaddr tls32baseaddr:$sym)]>,
Requires<[Not64BitMode]>;
}
// All calls clobber the non-callee saved registers. RSP is marked as
// a use to prevent stack-pointer assignments that appear immediately
// before calls from potentially appearing dead.
let Defs = [RAX, RCX, RDX, RSI, RDI, R8, R9, R10, R11,
FP0, FP1, FP2, FP3, FP4, FP5, FP6, FP7,
ST0, ST1, ST2, ST3, ST4, ST5, ST6, ST7,
MM0, MM1, MM2, MM3, MM4, MM5, MM6, MM7,
XMM0, XMM1, XMM2, XMM3, XMM4, XMM5, XMM6, XMM7,
XMM8, XMM9, XMM10, XMM11, XMM12, XMM13, XMM14, XMM15, EFLAGS],
usesCustomInserter = 1, Uses = [RSP, SSP] in {
def TLS_addr64 : I<0, Pseudo, (outs), (ins i64mem:$sym),
"# TLS_addr64",
[(X86tlsaddr tls64addr:$sym)]>,
Requires<[In64BitMode]>;
def TLS_base_addr64 : I<0, Pseudo, (outs), (ins i64mem:$sym),
"# TLS_base_addr64",
[(X86tlsbaseaddr tls64baseaddr:$sym)]>,
Requires<[In64BitMode]>;
}
// Darwin TLS Support
// For i386, the address of the thunk is passed on the stack, on return the
// address of the variable is in %eax. %ecx is trashed during the function
// call. All other registers are preserved.
let Defs = [EAX, ECX, EFLAGS],
Uses = [ESP, SSP],
usesCustomInserter = 1 in
def TLSCall_32 : I<0, Pseudo, (outs), (ins i32mem:$sym),
"# TLSCall_32",
[(X86TLSCall addr:$sym)]>,
Requires<[Not64BitMode]>;
// For x86_64, the address of the thunk is passed in %rdi, but the
// pseudo directly use the symbol, so do not add an implicit use of
// %rdi. The lowering will do the right thing with RDI.
// On return the address of the variable is in %rax. All other
// registers are preserved.
let Defs = [RAX, EFLAGS],
Uses = [RSP, SSP],
usesCustomInserter = 1 in
def TLSCall_64 : I<0, Pseudo, (outs), (ins i64mem:$sym),
"# TLSCall_64",
[(X86TLSCall addr:$sym)]>,
Requires<[In64BitMode]>;
} // SchedRW
//===----------------------------------------------------------------------===//
// Conditional Move Pseudo Instructions
// CMOV* - Used to implement the SELECT DAG operation. Expanded after
// instruction selection into a branch sequence.
multiclass CMOVrr_PSEUDO<RegisterClass RC, ValueType VT> {
def CMOV#NAME : I<0, Pseudo,
(outs RC:$dst), (ins RC:$t, RC:$f, i8imm:$cond),
"#CMOV_"#NAME#" PSEUDO!",
[(set RC:$dst, (VT (X86cmov RC:$t, RC:$f, imm:$cond,
EFLAGS)))]>;
}
let usesCustomInserter = 1, hasNoSchedulingInfo = 1, Uses = [EFLAGS] in {
// X86 doesn't have 8-bit conditional moves. Use a customInserter to
// emit control flow. An alternative to this is to mark i8 SELECT as Promote,
// however that requires promoting the operands, and can induce additional
// i8 register pressure.
defm _GR8 : CMOVrr_PSEUDO<GR8, i8>;
let Predicates = [NoCMov] in {
defm _GR32 : CMOVrr_PSEUDO<GR32, i32>;
defm _GR16 : CMOVrr_PSEUDO<GR16, i16>;
} // Predicates = [NoCMov]
// fcmov doesn't handle all possible EFLAGS, provide a fallback if there is no
// SSE1/SSE2.
let Predicates = [FPStackf32] in
defm _RFP32 : CMOVrr_PSEUDO<RFP32, f32>;
let Predicates = [FPStackf64] in
defm _RFP64 : CMOVrr_PSEUDO<RFP64, f64>;
defm _RFP80 : CMOVrr_PSEUDO<RFP80, f80>;
defm _FR32 : CMOVrr_PSEUDO<FR32, f32>;
defm _FR64 : CMOVrr_PSEUDO<FR64, f64>;
defm _FR128 : CMOVrr_PSEUDO<FR128, f128>;
defm _V4F32 : CMOVrr_PSEUDO<VR128, v4f32>;
defm _V2F64 : CMOVrr_PSEUDO<VR128, v2f64>;
defm _V2I64 : CMOVrr_PSEUDO<VR128, v2i64>;
defm _V8F32 : CMOVrr_PSEUDO<VR256, v8f32>;
defm _V4F64 : CMOVrr_PSEUDO<VR256, v4f64>;
defm _V4I64 : CMOVrr_PSEUDO<VR256, v4i64>;
defm _V8I64 : CMOVrr_PSEUDO<VR512, v8i64>;
defm _V8F64 : CMOVrr_PSEUDO<VR512, v8f64>;
defm _V16F32 : CMOVrr_PSEUDO<VR512, v16f32>;
defm _V8I1 : CMOVrr_PSEUDO<VK8, v8i1>;
defm _V16I1 : CMOVrr_PSEUDO<VK16, v16i1>;
defm _V32I1 : CMOVrr_PSEUDO<VK32, v32i1>;
defm _V64I1 : CMOVrr_PSEUDO<VK64, v64i1>;
} // usesCustomInserter = 1, hasNoSchedulingInfo = 1, Uses = [EFLAGS]
//===----------------------------------------------------------------------===//
// Normal-Instructions-With-Lock-Prefix Pseudo Instructions
//===----------------------------------------------------------------------===//
// FIXME: Use normal instructions and add lock prefix dynamically.
// Memory barriers
// TODO: Get this to fold the constant into the instruction.
let isCodeGenOnly = 1, Defs = [EFLAGS] in
def OR32mrLocked : I<0x09, MRMDestMem, (outs), (ins i32mem:$dst, GR32:$zero),
"or{l}\t{$zero, $dst|$dst, $zero}", [],
IIC_ALU_MEM>, Requires<[Not64BitMode]>, OpSize32, LOCK,
Sched<[WriteALULd, WriteRMW]>;
let hasSideEffects = 1 in
def Int_MemBarrier : I<0, Pseudo, (outs), (ins),
"#MEMBARRIER",
[(X86MemBarrier)]>, Sched<[WriteLoad]>;
// RegOpc corresponds to the mr version of the instruction
// ImmOpc corresponds to the mi version of the instruction
// ImmOpc8 corresponds to the mi8 version of the instruction
// ImmMod corresponds to the instruction format of the mi and mi8 versions
multiclass LOCK_ArithBinOp<bits<8> RegOpc, bits<8> ImmOpc, bits<8> ImmOpc8,
Format ImmMod, SDNode Op, string mnemonic> {
let Defs = [EFLAGS], mayLoad = 1, mayStore = 1, isCodeGenOnly = 1,
SchedRW = [WriteALULd, WriteRMW] in {
def NAME#8mr : I<{RegOpc{7}, RegOpc{6}, RegOpc{5}, RegOpc{4},
RegOpc{3}, RegOpc{2}, RegOpc{1}, 0 },
MRMDestMem, (outs), (ins i8mem:$dst, GR8:$src2),
!strconcat(mnemonic, "{b}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, GR8:$src2))],
IIC_ALU_NONMEM>, LOCK;
def NAME#16mr : I<{RegOpc{7}, RegOpc{6}, RegOpc{5}, RegOpc{4},
RegOpc{3}, RegOpc{2}, RegOpc{1}, 1 },
MRMDestMem, (outs), (ins i16mem:$dst, GR16:$src2),
!strconcat(mnemonic, "{w}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, GR16:$src2))],
IIC_ALU_NONMEM>, OpSize16, LOCK;
def NAME#32mr : I<{RegOpc{7}, RegOpc{6}, RegOpc{5}, RegOpc{4},
RegOpc{3}, RegOpc{2}, RegOpc{1}, 1 },
MRMDestMem, (outs), (ins i32mem:$dst, GR32:$src2),
!strconcat(mnemonic, "{l}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, GR32:$src2))],
IIC_ALU_NONMEM>, OpSize32, LOCK;
def NAME#64mr : RI<{RegOpc{7}, RegOpc{6}, RegOpc{5}, RegOpc{4},
RegOpc{3}, RegOpc{2}, RegOpc{1}, 1 },
MRMDestMem, (outs), (ins i64mem:$dst, GR64:$src2),
!strconcat(mnemonic, "{q}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, GR64:$src2))],
IIC_ALU_NONMEM>, LOCK;
def NAME#8mi : Ii8<{ImmOpc{7}, ImmOpc{6}, ImmOpc{5}, ImmOpc{4},
ImmOpc{3}, ImmOpc{2}, ImmOpc{1}, 0 },
ImmMod, (outs), (ins i8mem :$dst, i8imm :$src2),
!strconcat(mnemonic, "{b}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, (i8 imm:$src2)))],
IIC_ALU_MEM>, LOCK;
def NAME#16mi : Ii16<{ImmOpc{7}, ImmOpc{6}, ImmOpc{5}, ImmOpc{4},
ImmOpc{3}, ImmOpc{2}, ImmOpc{1}, 1 },
ImmMod, (outs), (ins i16mem :$dst, i16imm :$src2),
!strconcat(mnemonic, "{w}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, (i16 imm:$src2)))],
IIC_ALU_MEM>, OpSize16, LOCK;
def NAME#32mi : Ii32<{ImmOpc{7}, ImmOpc{6}, ImmOpc{5}, ImmOpc{4},
ImmOpc{3}, ImmOpc{2}, ImmOpc{1}, 1 },
ImmMod, (outs), (ins i32mem :$dst, i32imm :$src2),
!strconcat(mnemonic, "{l}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, (i32 imm:$src2)))],
IIC_ALU_MEM>, OpSize32, LOCK;
def NAME#64mi32 : RIi32S<{ImmOpc{7}, ImmOpc{6}, ImmOpc{5}, ImmOpc{4},
ImmOpc{3}, ImmOpc{2}, ImmOpc{1}, 1 },
ImmMod, (outs), (ins i64mem :$dst, i64i32imm :$src2),
!strconcat(mnemonic, "{q}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, i64immSExt32:$src2))],
IIC_ALU_MEM>, LOCK;
def NAME#16mi8 : Ii8<{ImmOpc8{7}, ImmOpc8{6}, ImmOpc8{5}, ImmOpc8{4},
ImmOpc8{3}, ImmOpc8{2}, ImmOpc8{1}, 1 },
ImmMod, (outs), (ins i16mem :$dst, i16i8imm :$src2),
!strconcat(mnemonic, "{w}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, i16immSExt8:$src2))],
IIC_ALU_MEM>, OpSize16, LOCK;
def NAME#32mi8 : Ii8<{ImmOpc8{7}, ImmOpc8{6}, ImmOpc8{5}, ImmOpc8{4},
ImmOpc8{3}, ImmOpc8{2}, ImmOpc8{1}, 1 },
ImmMod, (outs), (ins i32mem :$dst, i32i8imm :$src2),
!strconcat(mnemonic, "{l}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, i32immSExt8:$src2))],
IIC_ALU_MEM>, OpSize32, LOCK;
def NAME#64mi8 : RIi8<{ImmOpc8{7}, ImmOpc8{6}, ImmOpc8{5}, ImmOpc8{4},
ImmOpc8{3}, ImmOpc8{2}, ImmOpc8{1}, 1 },
ImmMod, (outs), (ins i64mem :$dst, i64i8imm :$src2),
!strconcat(mnemonic, "{q}\t",
"{$src2, $dst|$dst, $src2}"),
[(set EFLAGS, (Op addr:$dst, i64immSExt8:$src2))],
IIC_ALU_MEM>, LOCK;
}
}
defm LOCK_ADD : LOCK_ArithBinOp<0x00, 0x80, 0x83, MRM0m, X86lock_add, "add">;
defm LOCK_SUB : LOCK_ArithBinOp<0x28, 0x80, 0x83, MRM5m, X86lock_sub, "sub">;
defm LOCK_OR : LOCK_ArithBinOp<0x08, 0x80, 0x83, MRM1m, X86lock_or , "or">;
defm LOCK_AND : LOCK_ArithBinOp<0x20, 0x80, 0x83, MRM4m, X86lock_and, "and">;
defm LOCK_XOR : LOCK_ArithBinOp<0x30, 0x80, 0x83, MRM6m, X86lock_xor, "xor">;
multiclass LOCK_ArithUnOp<bits<8> Opc8, bits<8> Opc, Format Form,
string frag, string mnemonic> {
let Defs = [EFLAGS], mayLoad = 1, mayStore = 1, isCodeGenOnly = 1,
SchedRW = [WriteALULd, WriteRMW] in {
def NAME#8m : I<Opc8, Form, (outs), (ins i8mem :$dst),
!strconcat(mnemonic, "{b}\t$dst"),
[(set EFLAGS, (!cast<PatFrag>(frag # "_8") addr:$dst))],
IIC_UNARY_MEM>, LOCK;
def NAME#16m : I<Opc, Form, (outs), (ins i16mem:$dst),
!strconcat(mnemonic, "{w}\t$dst"),
[(set EFLAGS, (!cast<PatFrag>(frag # "_16") addr:$dst))],
IIC_UNARY_MEM>, OpSize16, LOCK;
def NAME#32m : I<Opc, Form, (outs), (ins i32mem:$dst),
!strconcat(mnemonic, "{l}\t$dst"),
[(set EFLAGS, (!cast<PatFrag>(frag # "_32") addr:$dst))],
IIC_UNARY_MEM>, OpSize32, LOCK;
def NAME#64m : RI<Opc, Form, (outs), (ins i64mem:$dst),
!strconcat(mnemonic, "{q}\t$dst"),
[(set EFLAGS, (!cast<PatFrag>(frag # "_64") addr:$dst))],
IIC_UNARY_MEM>, LOCK;
}
}
multiclass unary_atomic_intrin<SDNode atomic_op> {
def _8 : PatFrag<(ops node:$ptr),
(atomic_op node:$ptr), [{
return cast<MemIntrinsicSDNode>(N)->getMemoryVT() == MVT::i8;
}]>;
def _16 : PatFrag<(ops node:$ptr),
(atomic_op node:$ptr), [{
return cast<MemIntrinsicSDNode>(N)->getMemoryVT() == MVT::i16;
}]>;
def _32 : PatFrag<(ops node:$ptr),
(atomic_op node:$ptr), [{
return cast<MemIntrinsicSDNode>(N)->getMemoryVT() == MVT::i32;
}]>;
def _64 : PatFrag<(ops node:$ptr),
(atomic_op node:$ptr), [{
return cast<MemIntrinsicSDNode>(N)->getMemoryVT() == MVT::i64;
}]>;
}
defm X86lock_inc : unary_atomic_intrin<X86lock_inc>;
defm X86lock_dec : unary_atomic_intrin<X86lock_dec>;
defm LOCK_INC : LOCK_ArithUnOp<0xFE, 0xFF, MRM0m, "X86lock_inc", "inc">;
defm LOCK_DEC : LOCK_ArithUnOp<0xFE, 0xFF, MRM1m, "X86lock_dec", "dec">;
// Atomic compare and swap.
multiclass LCMPXCHG_UnOp<bits<8> Opc, Format Form, string mnemonic,
SDPatternOperator frag, X86MemOperand x86memop,
InstrItinClass itin> {
let isCodeGenOnly = 1, usesCustomInserter = 1 in {
def NAME : I<Opc, Form, (outs), (ins x86memop:$ptr),
!strconcat(mnemonic, "\t$ptr"),
[(frag addr:$ptr)], itin>, TB, LOCK;
}
}
multiclass LCMPXCHG_BinOp<bits<8> Opc8, bits<8> Opc, Format Form,
string mnemonic, SDPatternOperator frag,
InstrItinClass itin8, InstrItinClass itin> {
let isCodeGenOnly = 1, SchedRW = [WriteALULd, WriteRMW] in {
let Defs = [AL, EFLAGS], Uses = [AL] in
def NAME#8 : I<Opc8, Form, (outs), (ins i8mem:$ptr, GR8:$swap),
!strconcat(mnemonic, "{b}\t{$swap, $ptr|$ptr, $swap}"),
[(frag addr:$ptr, GR8:$swap, 1)], itin8>, TB, LOCK;
let Defs = [AX, EFLAGS], Uses = [AX] in
def NAME#16 : I<Opc, Form, (outs), (ins i16mem:$ptr, GR16:$swap),
!strconcat(mnemonic, "{w}\t{$swap, $ptr|$ptr, $swap}"),
[(frag addr:$ptr, GR16:$swap, 2)], itin>, TB, OpSize16, LOCK;
let Defs = [EAX, EFLAGS], Uses = [EAX] in
def NAME#32 : I<Opc, Form, (outs), (ins i32mem:$ptr, GR32:$swap),
!strconcat(mnemonic, "{l}\t{$swap, $ptr|$ptr, $swap}"),
[(frag addr:$ptr, GR32:$swap, 4)], itin>, TB, OpSize32, LOCK;
let Defs = [RAX, EFLAGS], Uses = [RAX] in
def NAME#64 : RI<Opc, Form, (outs), (ins i64mem:$ptr, GR64:$swap),
!strconcat(mnemonic, "{q}\t{$swap, $ptr|$ptr, $swap}"),
[(frag addr:$ptr, GR64:$swap, 8)], itin>, TB, LOCK;
}
}
let Defs = [EAX, EDX, EFLAGS], Uses = [EAX, EBX, ECX, EDX],
SchedRW = [WriteALULd, WriteRMW] in {
defm LCMPXCHG8B : LCMPXCHG_UnOp<0xC7, MRM1m, "cmpxchg8b",
X86cas8, i64mem,
IIC_CMPX_LOCK_8B>;
}
// This pseudo must be used when the frame uses RBX as
// the base pointer. Indeed, in such situation RBX is a reserved
// register and the register allocator will ignore any use/def of
// it. In other words, the register will not fix the clobbering of
// RBX that will happen when setting the arguments for the instrucion.
//
// Unlike the actual related instuction, we mark that this one
// defines EBX (instead of using EBX).
// The rationale is that we will define RBX during the expansion of
// the pseudo. The argument feeding EBX is ebx_input.
//
// The additional argument, $ebx_save, is a temporary register used to
// save the value of RBX across the actual instruction.
//
// To make sure the register assigned to $ebx_save does not interfere with
// the definition of the actual instruction, we use a definition $dst which
// is tied to $rbx_save. That way, the live-range of $rbx_save spans across
// the instruction and we are sure we will have a valid register to restore
// the value of RBX.
let Defs = [EAX, EDX, EBX, EFLAGS], Uses = [EAX, ECX, EDX],
SchedRW = [WriteALULd, WriteRMW], isCodeGenOnly = 1, isPseudo = 1,
Constraints = "$ebx_save = $dst", usesCustomInserter = 1 in {
def LCMPXCHG8B_SAVE_EBX :
I<0, Pseudo, (outs GR32:$dst),
(ins i64mem:$ptr, GR32:$ebx_input, GR32:$ebx_save),
!strconcat("cmpxchg8b", "\t$ptr"),
[(set GR32:$dst, (X86cas8save_ebx addr:$ptr, GR32:$ebx_input,
GR32:$ebx_save))],
IIC_CMPX_LOCK_8B>;
}
let Defs = [RAX, RDX, EFLAGS], Uses = [RAX, RBX, RCX, RDX],
Predicates = [HasCmpxchg16b], SchedRW = [WriteALULd, WriteRMW] in {
defm LCMPXCHG16B : LCMPXCHG_UnOp<0xC7, MRM1m, "cmpxchg16b",
X86cas16, i128mem,
IIC_CMPX_LOCK_16B>, REX_W;
}
// Same as LCMPXCHG8B_SAVE_RBX but for the 16 Bytes variant.
let Defs = [RAX, RDX, RBX, EFLAGS], Uses = [RAX, RCX, RDX],
Predicates = [HasCmpxchg16b], SchedRW = [WriteALULd, WriteRMW],
isCodeGenOnly = 1, isPseudo = 1, Constraints = "$rbx_save = $dst",
usesCustomInserter = 1 in {
def LCMPXCHG16B_SAVE_RBX :
I<0, Pseudo, (outs GR64:$dst),
(ins i128mem:$ptr, GR64:$rbx_input, GR64:$rbx_save),
!strconcat("cmpxchg16b", "\t$ptr"),
[(set GR64:$dst, (X86cas16save_rbx addr:$ptr, GR64:$rbx_input,
GR64:$rbx_save))],
IIC_CMPX_LOCK_16B>;
}
defm LCMPXCHG : LCMPXCHG_BinOp<0xB0, 0xB1, MRMDestMem, "cmpxchg",
X86cas, IIC_CMPX_LOCK_8, IIC_CMPX_LOCK>;
// Atomic exchange and add
multiclass ATOMIC_LOAD_BINOP<bits<8> opc8, bits<8> opc, string mnemonic,
string frag,
InstrItinClass itin8, InstrItinClass itin> {
let Constraints = "$val = $dst", Defs = [EFLAGS], isCodeGenOnly = 1,
SchedRW = [WriteALULd, WriteRMW] in {
def NAME#8 : I<opc8, MRMSrcMem, (outs GR8:$dst),
(ins GR8:$val, i8mem:$ptr),
!strconcat(mnemonic, "{b}\t{$val, $ptr|$ptr, $val}"),
[(set GR8:$dst,
(!cast<PatFrag>(frag # "_8") addr:$ptr, GR8:$val))],
itin8>;
def NAME#16 : I<opc, MRMSrcMem, (outs GR16:$dst),
(ins GR16:$val, i16mem:$ptr),
!strconcat(mnemonic, "{w}\t{$val, $ptr|$ptr, $val}"),
[(set
GR16:$dst,
(!cast<PatFrag>(frag # "_16") addr:$ptr, GR16:$val))],
itin>, OpSize16;
def NAME#32 : I<opc, MRMSrcMem, (outs GR32:$dst),
(ins GR32:$val, i32mem:$ptr),
!strconcat(mnemonic, "{l}\t{$val, $ptr|$ptr, $val}"),
[(set
GR32:$dst,
(!cast<PatFrag>(frag # "_32") addr:$ptr, GR32:$val))],
itin>, OpSize32;
def NAME#64 : RI<opc, MRMSrcMem, (outs GR64:$dst),
(ins GR64:$val, i64mem:$ptr),
!strconcat(mnemonic, "{q}\t{$val, $ptr|$ptr, $val}"),
[(set
GR64:$dst,
(!cast<PatFrag>(frag # "_64") addr:$ptr, GR64:$val))],
itin>;
}
}
defm LXADD : ATOMIC_LOAD_BINOP<0xc0, 0xc1, "xadd", "atomic_load_add",
IIC_XADD_LOCK_MEM8, IIC_XADD_LOCK_MEM>,
TB, LOCK;
/* The following multiclass tries to make sure that in code like
* x.store (immediate op x.load(acquire), release)
* and
* x.store (register op x.load(acquire), release)
* an operation directly on memory is generated instead of wasting a register.
* It is not automatic as atomic_store/load are only lowered to MOV instructions
* extremely late to prevent them from being accidentally reordered in the backend
* (see below the RELEASE_MOV* / ACQUIRE_MOV* pseudo-instructions)
*/
multiclass RELEASE_BINOP_MI<SDNode op> {
def NAME#8mi : I<0, Pseudo, (outs), (ins i8mem:$dst, i8imm:$src),
"#BINOP "#NAME#"8mi PSEUDO!",
[(atomic_store_8 addr:$dst, (op
(atomic_load_8 addr:$dst), (i8 imm:$src)))]>;
def NAME#8mr : I<0, Pseudo, (outs), (ins i8mem:$dst, GR8:$src),
"#BINOP "#NAME#"8mr PSEUDO!",
[(atomic_store_8 addr:$dst, (op
(atomic_load_8 addr:$dst), GR8:$src))]>;
// NAME#16 is not generated as 16-bit arithmetic instructions are considered
// costly and avoided as far as possible by this backend anyway
def NAME#32mi : I<0, Pseudo, (outs), (ins i32mem:$dst, i32imm:$src),
"#BINOP "#NAME#"32mi PSEUDO!",
[(atomic_store_32 addr:$dst, (op
(atomic_load_32 addr:$dst), (i32 imm:$src)))]>;
def NAME#32mr : I<0, Pseudo, (outs), (ins i32mem:$dst, GR32:$src),
"#BINOP "#NAME#"32mr PSEUDO!",
[(atomic_store_32 addr:$dst, (op
(atomic_load_32 addr:$dst), GR32:$src))]>;
def NAME#64mi32 : I<0, Pseudo, (outs), (ins i64mem:$dst, i64i32imm:$src),
"#BINOP "#NAME#"64mi32 PSEUDO!",
[(atomic_store_64 addr:$dst, (op
(atomic_load_64 addr:$dst), (i64immSExt32:$src)))]>;
def NAME#64mr : I<0, Pseudo, (outs), (ins i64mem:$dst, GR64:$src),
"#BINOP "#NAME#"64mr PSEUDO!",
[(atomic_store_64 addr:$dst, (op
(atomic_load_64 addr:$dst), GR64:$src))]>;
}
let Defs = [EFLAGS], SchedRW = [WriteMicrocoded] in {
defm RELEASE_ADD : RELEASE_BINOP_MI<add>;
defm RELEASE_AND : RELEASE_BINOP_MI<and>;
defm RELEASE_OR : RELEASE_BINOP_MI<or>;
defm RELEASE_XOR : RELEASE_BINOP_MI<xor>;
// Note: we don't deal with sub, because substractions of constants are
// optimized into additions before this code can run.
}
// Same as above, but for floating-point.
// FIXME: imm version.
// FIXME: Version that doesn't clobber $src, using AVX's VADDSS.
// FIXME: This could also handle SIMD operations with *ps and *pd instructions.
let usesCustomInserter = 1, SchedRW = [WriteMicrocoded] in {
multiclass RELEASE_FP_BINOP_MI<SDNode op> {
def NAME#32mr : I<0, Pseudo, (outs), (ins i32mem:$dst, FR32:$src),
"#BINOP "#NAME#"32mr PSEUDO!",
[(atomic_store_32 addr:$dst,
(i32 (bitconvert (op
(f32 (bitconvert (i32 (atomic_load_32 addr:$dst)))),
FR32:$src))))]>, Requires<[HasSSE1]>;
def NAME#64mr : I<0, Pseudo, (outs), (ins i64mem:$dst, FR64:$src),
"#BINOP "#NAME#"64mr PSEUDO!",
[(atomic_store_64 addr:$dst,
(i64 (bitconvert (op
(f64 (bitconvert (i64 (atomic_load_64 addr:$dst)))),
FR64:$src))))]>, Requires<[HasSSE2]>;
}
defm RELEASE_FADD : RELEASE_FP_BINOP_MI<fadd>;
// FIXME: Add fsub, fmul, fdiv, ...
}
multiclass RELEASE_UNOP<dag dag8, dag dag16, dag dag32, dag dag64> {
def NAME#8m : I<0, Pseudo, (outs), (ins i8mem:$dst),
"#UNOP "#NAME#"8m PSEUDO!",
[(atomic_store_8 addr:$dst, dag8)]>;
def NAME#16m : I<0, Pseudo, (outs), (ins i16mem:$dst),
"#UNOP "#NAME#"16m PSEUDO!",
[(atomic_store_16 addr:$dst, dag16)]>;
def NAME#32m : I<0, Pseudo, (outs), (ins i32mem:$dst),
"#UNOP "#NAME#"32m PSEUDO!",
[(atomic_store_32 addr:$dst, dag32)]>;
def NAME#64m : I<0, Pseudo, (outs), (ins i64mem:$dst),
"#UNOP "#NAME#"64m PSEUDO!",
[(atomic_store_64 addr:$dst, dag64)]>;
}
let Defs = [EFLAGS], Predicates = [UseIncDec], SchedRW = [WriteMicrocoded] in {
defm RELEASE_INC : RELEASE_UNOP<
(add (atomic_load_8 addr:$dst), (i8 1)),
(add (atomic_load_16 addr:$dst), (i16 1)),
(add (atomic_load_32 addr:$dst), (i32 1)),
(add (atomic_load_64 addr:$dst), (i64 1))>;
defm RELEASE_DEC : RELEASE_UNOP<
(add (atomic_load_8 addr:$dst), (i8 -1)),
(add (atomic_load_16 addr:$dst), (i16 -1)),
(add (atomic_load_32 addr:$dst), (i32 -1)),
(add (atomic_load_64 addr:$dst), (i64 -1))>;
}
/*
TODO: These don't work because the type inference of TableGen fails.
TODO: find a way to fix it.
let Defs = [EFLAGS] in {
defm RELEASE_NEG : RELEASE_UNOP<
(ineg (atomic_load_8 addr:$dst)),
(ineg (atomic_load_16 addr:$dst)),
(ineg (atomic_load_32 addr:$dst)),
(ineg (atomic_load_64 addr:$dst))>;
}
// NOT doesn't set flags.
defm RELEASE_NOT : RELEASE_UNOP<
(not (atomic_load_8 addr:$dst)),
(not (atomic_load_16 addr:$dst)),
(not (atomic_load_32 addr:$dst)),
(not (atomic_load_64 addr:$dst))>;
*/
let SchedRW = [WriteMicrocoded] in {
def RELEASE_MOV8mi : I<0, Pseudo, (outs), (ins i8mem:$dst, i8imm:$src),
"#RELEASE_MOV8mi PSEUDO!",
[(atomic_store_8 addr:$dst, (i8 imm:$src))]>;
def RELEASE_MOV16mi : I<0, Pseudo, (outs), (ins i16mem:$dst, i16imm:$src),
"#RELEASE_MOV16mi PSEUDO!",
[(atomic_store_16 addr:$dst, (i16 imm:$src))]>;
def RELEASE_MOV32mi : I<0, Pseudo, (outs), (ins i32mem:$dst, i32imm:$src),
"#RELEASE_MOV32mi PSEUDO!",
[(atomic_store_32 addr:$dst, (i32 imm:$src))]>;
def RELEASE_MOV64mi32 : I<0, Pseudo, (outs), (ins i64mem:$dst, i64i32imm:$src),
"#RELEASE_MOV64mi32 PSEUDO!",
[(atomic_store_64 addr:$dst, i64immSExt32:$src)]>;
def RELEASE_MOV8mr : I<0, Pseudo, (outs), (ins i8mem :$dst, GR8 :$src),
"#RELEASE_MOV8mr PSEUDO!",
[(atomic_store_8 addr:$dst, GR8 :$src)]>;
def RELEASE_MOV16mr : I<0, Pseudo, (outs), (ins i16mem:$dst, GR16:$src),
"#RELEASE_MOV16mr PSEUDO!",
[(atomic_store_16 addr:$dst, GR16:$src)]>;
def RELEASE_MOV32mr : I<0, Pseudo, (outs), (ins i32mem:$dst, GR32:$src),
"#RELEASE_MOV32mr PSEUDO!",
[(atomic_store_32 addr:$dst, GR32:$src)]>;
def RELEASE_MOV64mr : I<0, Pseudo, (outs), (ins i64mem:$dst, GR64:$src),
"#RELEASE_MOV64mr PSEUDO!",
[(atomic_store_64 addr:$dst, GR64:$src)]>;
def ACQUIRE_MOV8rm : I<0, Pseudo, (outs GR8 :$dst), (ins i8mem :$src),
"#ACQUIRE_MOV8rm PSEUDO!",
[(set GR8:$dst, (atomic_load_8 addr:$src))]>;
def ACQUIRE_MOV16rm : I<0, Pseudo, (outs GR16:$dst), (ins i16mem:$src),
"#ACQUIRE_MOV16rm PSEUDO!",
[(set GR16:$dst, (atomic_load_16 addr:$src))]>;
def ACQUIRE_MOV32rm : I<0, Pseudo, (outs GR32:$dst), (ins i32mem:$src),
"#ACQUIRE_MOV32rm PSEUDO!",
[(set GR32:$dst, (atomic_load_32 addr:$src))]>;
def ACQUIRE_MOV64rm : I<0, Pseudo, (outs GR64:$dst), (ins i64mem:$src),
"#ACQUIRE_MOV64rm PSEUDO!",
[(set GR64:$dst, (atomic_load_64 addr:$src))]>;
} // SchedRW
//===----------------------------------------------------------------------===//
// DAG Pattern Matching Rules
//===----------------------------------------------------------------------===//
// Use AND/OR to store 0/-1 in memory when optimizing for minsize. This saves
// binary size compared to a regular MOV, but it introduces an unnecessary
// load, so is not suitable for regular or optsize functions.
let Predicates = [OptForMinSize] in {
def : Pat<(store (i16 0), addr:$dst), (AND16mi8 addr:$dst, 0)>;
def : Pat<(store (i32 0), addr:$dst), (AND32mi8 addr:$dst, 0)>;
def : Pat<(store (i64 0), addr:$dst), (AND64mi8 addr:$dst, 0)>;
def : Pat<(store (i16 -1), addr:$dst), (OR16mi8 addr:$dst, -1)>;
def : Pat<(store (i32 -1), addr:$dst), (OR32mi8 addr:$dst, -1)>;
def : Pat<(store (i64 -1), addr:$dst), (OR64mi8 addr:$dst, -1)>;
}
// In kernel code model, we can get the address of a label
// into a register with 'movq'. FIXME: This is a hack, the 'imm' predicate of
// the MOV64ri32 should accept these.
def : Pat<(i64 (X86Wrapper tconstpool :$dst)),
(MOV64ri32 tconstpool :$dst)>, Requires<[KernelCode]>;
def : Pat<(i64 (X86Wrapper tjumptable :$dst)),
(MOV64ri32 tjumptable :$dst)>, Requires<[KernelCode]>;
def : Pat<(i64 (X86Wrapper tglobaladdr :$dst)),
(MOV64ri32 tglobaladdr :$dst)>, Requires<[KernelCode]>;
def : Pat<(i64 (X86Wrapper texternalsym:$dst)),
(MOV64ri32 texternalsym:$dst)>, Requires<[KernelCode]>;
def : Pat<(i64 (X86Wrapper mcsym:$dst)),
(MOV64ri32 mcsym:$dst)>, Requires<[KernelCode]>;
def : Pat<(i64 (X86Wrapper tblockaddress:$dst)),
(MOV64ri32 tblockaddress:$dst)>, Requires<[KernelCode]>;
// If we have small model and -static mode, it is safe to store global addresses
// directly as immediates. FIXME: This is really a hack, the 'imm' predicate
// for MOV64mi32 should handle this sort of thing.
def : Pat<(store (i64 (X86Wrapper tconstpool:$src)), addr:$dst),
(MOV64mi32 addr:$dst, tconstpool:$src)>,
Requires<[NearData, IsNotPIC]>;
def : Pat<(store (i64 (X86Wrapper tjumptable:$src)), addr:$dst),
(MOV64mi32 addr:$dst, tjumptable:$src)>,
Requires<[NearData, IsNotPIC]>;
def : Pat<(store (i64 (X86Wrapper tglobaladdr:$src)), addr:$dst),
(MOV64mi32 addr:$dst, tglobaladdr:$src)>,
Requires<[NearData, IsNotPIC]>;
def : Pat<(store (i64 (X86Wrapper texternalsym:$src)), addr:$dst),
(MOV64mi32 addr:$dst, texternalsym:$src)>,
Requires<[NearData, IsNotPIC]>;
def : Pat<(store (i64 (X86Wrapper mcsym:$src)), addr:$dst),
(MOV64mi32 addr:$dst, mcsym:$src)>,
Requires<[NearData, IsNotPIC]>;
def : Pat<(store (i64 (X86Wrapper tblockaddress:$src)), addr:$dst),
(MOV64mi32 addr:$dst, tblockaddress:$src)>,
Requires<[NearData, IsNotPIC]>;
def : Pat<(i32 (X86RecoverFrameAlloc mcsym:$dst)), (MOV32ri mcsym:$dst)>;
def : Pat<(i64 (X86RecoverFrameAlloc mcsym:$dst)), (MOV64ri mcsym:$dst)>;
// Calls
// tls has some funny stuff here...
// This corresponds to movabs $foo@tpoff, %rax
def : Pat<(i64 (X86Wrapper tglobaltlsaddr :$dst)),
(MOV64ri32 tglobaltlsaddr :$dst)>;
// This corresponds to add $foo@tpoff, %rax
def : Pat<(add GR64:$src1, (X86Wrapper tglobaltlsaddr :$dst)),
(ADD64ri32 GR64:$src1, tglobaltlsaddr :$dst)>;
// Direct PC relative function call for small code model. 32-bit displacement
// sign extended to 64-bit.
def : Pat<(X86call (i64 tglobaladdr:$dst)),
(CALL64pcrel32 tglobaladdr:$dst)>;
def : Pat<(X86call (i64 texternalsym:$dst)),
(CALL64pcrel32 texternalsym:$dst)>;
// Tailcall stuff. The TCRETURN instructions execute after the epilog, so they
// can never use callee-saved registers. That is the purpose of the GR64_TC
// register classes.
//
// The only volatile register that is never used by the calling convention is
// %r11. This happens when calling a vararg function with 6 arguments.
//
// Match an X86tcret that uses less than 7 volatile registers.
def X86tcret_6regs : PatFrag<(ops node:$ptr, node:$off),
(X86tcret node:$ptr, node:$off), [{
// X86tcret args: (*chain, ptr, imm, regs..., glue)
unsigned NumRegs = 0;
for (unsigned i = 3, e = N->getNumOperands(); i != e; ++i)
if (isa<RegisterSDNode>(N->getOperand(i)) && ++NumRegs > 6)
return false;
return true;
}]>;
def : Pat<(X86tcret ptr_rc_tailcall:$dst, imm:$off),
(TCRETURNri ptr_rc_tailcall:$dst, imm:$off)>,
Requires<[Not64BitMode, NotUseRetpoline]>;
// FIXME: This is disabled for 32-bit PIC mode because the global base
// register which is part of the address mode may be assigned a
// callee-saved register.
def : Pat<(X86tcret (load addr:$dst), imm:$off),
(TCRETURNmi addr:$dst, imm:$off)>,
Requires<[Not64BitMode, IsNotPIC, NotUseRetpoline]>;
def : Pat<(X86tcret (i32 tglobaladdr:$dst), imm:$off),
(TCRETURNdi tglobaladdr:$dst, imm:$off)>,
Requires<[NotLP64]>;
def : Pat<(X86tcret (i32 texternalsym:$dst), imm:$off),
(TCRETURNdi texternalsym:$dst, imm:$off)>,
Requires<[NotLP64]>;
def : Pat<(X86tcret ptr_rc_tailcall:$dst, imm:$off),
(TCRETURNri64 ptr_rc_tailcall:$dst, imm:$off)>,
Requires<[In64BitMode, NotUseRetpoline]>;
// Don't fold loads into X86tcret requiring more than 6 regs.
// There wouldn't be enough scratch registers for base+index.
def : Pat<(X86tcret_6regs (load addr:$dst), imm:$off),
(TCRETURNmi64 addr:$dst, imm:$off)>,
Requires<[In64BitMode, NotUseRetpoline]>;
def : Pat<(X86tcret ptr_rc_tailcall:$dst, imm:$off),
(RETPOLINE_TCRETURN64 ptr_rc_tailcall:$dst, imm:$off)>,
Requires<[In64BitMode, UseRetpoline]>;
def : Pat<(X86tcret ptr_rc_tailcall:$dst, imm:$off),
(RETPOLINE_TCRETURN32 ptr_rc_tailcall:$dst, imm:$off)>,
Requires<[Not64BitMode, UseRetpoline]>;
def : Pat<(X86tcret (i64 tglobaladdr:$dst), imm:$off),
(TCRETURNdi64 tglobaladdr:$dst, imm:$off)>,
Requires<[IsLP64]>;
def : Pat<(X86tcret (i64 texternalsym:$dst), imm:$off),
(TCRETURNdi64 texternalsym:$dst, imm:$off)>,
Requires<[IsLP64]>;
// Normal calls, with various flavors of addresses.
def : Pat<(X86call (i32 tglobaladdr:$dst)),
(CALLpcrel32 tglobaladdr:$dst)>;
def : Pat<(X86call (i32 texternalsym:$dst)),
(CALLpcrel32 texternalsym:$dst)>;
def : Pat<(X86call (i32 imm:$dst)),
(CALLpcrel32 imm:$dst)>, Requires<[CallImmAddr]>;
// Comparisons.
// TEST R,R is smaller than CMP R,0
def : Pat<(X86cmp GR8:$src1, 0),
(TEST8rr GR8:$src1, GR8:$src1)>;
def : Pat<(X86cmp GR16:$src1, 0),
(TEST16rr GR16:$src1, GR16:$src1)>;
def : Pat<(X86cmp GR32:$src1, 0),
(TEST32rr GR32:$src1, GR32:$src1)>;
def : Pat<(X86cmp GR64:$src1, 0),
(TEST64rr GR64:$src1, GR64:$src1)>;
// Conditional moves with folded loads with operands swapped and conditions
// inverted.
multiclass CMOVmr<PatLeaf InvertedCond, Instruction Inst16, Instruction Inst32,
Instruction Inst64> {
let Predicates = [HasCMov] in {
def : Pat<(X86cmov (loadi16 addr:$src1), GR16:$src2, InvertedCond, EFLAGS),
(Inst16 GR16:$src2, addr:$src1)>;
def : Pat<(X86cmov (loadi32 addr:$src1), GR32:$src2, InvertedCond, EFLAGS),
(Inst32 GR32:$src2, addr:$src1)>;
def : Pat<(X86cmov (loadi64 addr:$src1), GR64:$src2, InvertedCond, EFLAGS),
(Inst64 GR64:$src2, addr:$src1)>;
}
}
defm : CMOVmr<X86_COND_B , CMOVAE16rm, CMOVAE32rm, CMOVAE64rm>;
defm : CMOVmr<X86_COND_AE, CMOVB16rm , CMOVB32rm , CMOVB64rm>;
defm : CMOVmr<X86_COND_E , CMOVNE16rm, CMOVNE32rm, CMOVNE64rm>;
defm : CMOVmr<X86_COND_NE, CMOVE16rm , CMOVE32rm , CMOVE64rm>;
defm : CMOVmr<X86_COND_BE, CMOVA16rm , CMOVA32rm , CMOVA64rm>;
defm : CMOVmr<X86_COND_A , CMOVBE16rm, CMOVBE32rm, CMOVBE64rm>;
defm : CMOVmr<X86_COND_L , CMOVGE16rm, CMOVGE32rm, CMOVGE64rm>;
defm : CMOVmr<X86_COND_GE, CMOVL16rm , CMOVL32rm , CMOVL64rm>;
defm : CMOVmr<X86_COND_LE, CMOVG16rm , CMOVG32rm , CMOVG64rm>;
defm : CMOVmr<X86_COND_G , CMOVLE16rm, CMOVLE32rm, CMOVLE64rm>;
defm : CMOVmr<X86_COND_P , CMOVNP16rm, CMOVNP32rm, CMOVNP64rm>;
defm : CMOVmr<X86_COND_NP, CMOVP16rm , CMOVP32rm , CMOVP64rm>;
defm : CMOVmr<X86_COND_S , CMOVNS16rm, CMOVNS32rm, CMOVNS64rm>;
defm : CMOVmr<X86_COND_NS, CMOVS16rm , CMOVS32rm , CMOVS64rm>;
defm : CMOVmr<X86_COND_O , CMOVNO16rm, CMOVNO32rm, CMOVNO64rm>;
defm : CMOVmr<X86_COND_NO, CMOVO16rm , CMOVO32rm , CMOVO64rm>;
// zextload bool -> zextload byte
// i1 stored in one byte in zero-extended form.
// Upper bits cleanup should be executed before Store.
def : Pat<(zextloadi8i1 addr:$src), (MOV8rm addr:$src)>;
def : Pat<(zextloadi16i1 addr:$src), (MOVZX16rm8 addr:$src)>;
def : Pat<(zextloadi32i1 addr:$src), (MOVZX32rm8 addr:$src)>;
def : Pat<(zextloadi64i1 addr:$src),
(SUBREG_TO_REG (i64 0), (MOVZX32rm8 addr:$src), sub_32bit)>;
// extload bool -> extload byte
// When extloading from 16-bit and smaller memory locations into 64-bit
// registers, use zero-extending loads so that the entire 64-bit register is
// defined, avoiding partial-register updates.
def : Pat<(extloadi8i1 addr:$src), (MOV8rm addr:$src)>;
def : Pat<(extloadi16i1 addr:$src), (MOVZX16rm8 addr:$src)>;
def : Pat<(extloadi32i1 addr:$src), (MOVZX32rm8 addr:$src)>;
def : Pat<(extloadi16i8 addr:$src), (MOVZX16rm8 addr:$src)>;
def : Pat<(extloadi32i8 addr:$src), (MOVZX32rm8 addr:$src)>;
def : Pat<(extloadi32i16 addr:$src), (MOVZX32rm16 addr:$src)>;
// For other extloads, use subregs, since the high contents of the register are
// defined after an extload.
def : Pat<(extloadi64i1 addr:$src),
(SUBREG_TO_REG (i64 0), (MOVZX32rm8 addr:$src), sub_32bit)>;
def : Pat<(extloadi64i8 addr:$src),
(SUBREG_TO_REG (i64 0), (MOVZX32rm8 addr:$src), sub_32bit)>;
def : Pat<(extloadi64i16 addr:$src),
(SUBREG_TO_REG (i64 0), (MOVZX32rm16 addr:$src), sub_32bit)>;
def : Pat<(extloadi64i32 addr:$src),
(SUBREG_TO_REG (i64 0), (MOV32rm addr:$src), sub_32bit)>;
// anyext. Define these to do an explicit zero-extend to
// avoid partial-register updates.
def : Pat<(i16 (anyext GR8 :$src)), (EXTRACT_SUBREG
(MOVZX32rr8 GR8 :$src), sub_16bit)>;
def : Pat<(i32 (anyext GR8 :$src)), (MOVZX32rr8 GR8 :$src)>;
// Except for i16 -> i32 since isel expect i16 ops to be promoted to i32.
def : Pat<(i32 (anyext GR16:$src)),
(INSERT_SUBREG (i32 (IMPLICIT_DEF)), GR16:$src, sub_16bit)>;
def : Pat<(i64 (anyext GR8 :$src)),
(SUBREG_TO_REG (i64 0), (MOVZX32rr8 GR8 :$src), sub_32bit)>;
def : Pat<(i64 (anyext GR16:$src)),
(SUBREG_TO_REG (i64 0), (MOVZX32rr16 GR16 :$src), sub_32bit)>;
def : Pat<(i64 (anyext GR32:$src)),
(INSERT_SUBREG (i64 (IMPLICIT_DEF)), GR32:$src, sub_32bit)>;
// Any instruction that defines a 32-bit result leaves the high half of the
// register. Truncate can be lowered to EXTRACT_SUBREG. CopyFromReg may
// be copying from a truncate. Any other 32-bit operation will zero-extend
// up to 64 bits. AssertSext/AssertZext aren't saying anything about the upper
// 32 bits, they're probably just qualifying a CopyFromReg.
def def32 : PatLeaf<(i32 GR32:$src), [{
return N->getOpcode() != ISD::TRUNCATE &&
N->getOpcode() != TargetOpcode::EXTRACT_SUBREG &&
N->getOpcode() != ISD::CopyFromReg &&
N->getOpcode() != ISD::AssertSext &&
N->getOpcode() != ISD::AssertZext;
}]>;
// In the case of a 32-bit def that is known to implicitly zero-extend,
// we can use a SUBREG_TO_REG.
def : Pat<(i64 (zext def32:$src)),
(SUBREG_TO_REG (i64 0), GR32:$src, sub_32bit)>;
//===----------------------------------------------------------------------===//
// Pattern match OR as ADD
//===----------------------------------------------------------------------===//
// If safe, we prefer to pattern match OR as ADD at isel time. ADD can be
// 3-addressified into an LEA instruction to avoid copies. However, we also
// want to finally emit these instructions as an or at the end of the code
// generator to make the generated code easier to read. To do this, we select
// into "disjoint bits" pseudo ops.
// Treat an 'or' node is as an 'add' if the or'ed bits are known to be zero.
def or_is_add : PatFrag<(ops node:$lhs, node:$rhs), (or node:$lhs, node:$rhs),[{
if (ConstantSDNode *CN = dyn_cast<ConstantSDNode>(N->getOperand(1)))
return CurDAG->MaskedValueIsZero(N->getOperand(0), CN->getAPIntValue());
KnownBits Known0;
CurDAG->computeKnownBits(N->getOperand(0), Known0, 0);
KnownBits Known1;
CurDAG->computeKnownBits(N->getOperand(1), Known1, 0);
return (~Known0.Zero & ~Known1.Zero) == 0;
}]>;
// (or x1, x2) -> (add x1, x2) if two operands are known not to share bits.
// Try this before the selecting to OR.
let AddedComplexity = 5, SchedRW = [WriteALU] in {
let isConvertibleToThreeAddress = 1,
Constraints = "$src1 = $dst", Defs = [EFLAGS] in {
let isCommutable = 1 in {
def ADD16rr_DB : I<0, Pseudo, (outs GR16:$dst), (ins GR16:$src1, GR16:$src2),
"", // orw/addw REG, REG
[(set GR16:$dst, (or_is_add GR16:$src1, GR16:$src2))]>;
def ADD32rr_DB : I<0, Pseudo, (outs GR32:$dst), (ins GR32:$src1, GR32:$src2),
"", // orl/addl REG, REG
[(set GR32:$dst, (or_is_add GR32:$src1, GR32:$src2))]>;
def ADD64rr_DB : I<0, Pseudo, (outs GR64:$dst), (ins GR64:$src1, GR64:$src2),
"", // orq/addq REG, REG
[(set GR64:$dst, (or_is_add GR64:$src1, GR64:$src2))]>;
} // isCommutable
// NOTE: These are order specific, we want the ri8 forms to be listed
// first so that they are slightly preferred to the ri forms.
def ADD16ri8_DB : I<0, Pseudo,
(outs GR16:$dst), (ins GR16:$src1, i16i8imm:$src2),
"", // orw/addw REG, imm8
[(set GR16:$dst,(or_is_add GR16:$src1,i16immSExt8:$src2))]>;
def ADD16ri_DB : I<0, Pseudo, (outs GR16:$dst), (ins GR16:$src1, i16imm:$src2),
"", // orw/addw REG, imm
[(set GR16:$dst, (or_is_add GR16:$src1, imm:$src2))]>;
def ADD32ri8_DB : I<0, Pseudo,
(outs GR32:$dst), (ins GR32:$src1, i32i8imm:$src2),
"", // orl/addl REG, imm8
[(set GR32:$dst,(or_is_add GR32:$src1,i32immSExt8:$src2))]>;
def ADD32ri_DB : I<0, Pseudo, (outs GR32:$dst), (ins GR32:$src1, i32imm:$src2),
"", // orl/addl REG, imm
[(set GR32:$dst, (or_is_add GR32:$src1, imm:$src2))]>;
def ADD64ri8_DB : I<0, Pseudo,
(outs GR64:$dst), (ins GR64:$src1, i64i8imm:$src2),
"", // orq/addq REG, imm8
[(set GR64:$dst, (or_is_add GR64:$src1,
i64immSExt8:$src2))]>;
def ADD64ri32_DB : I<0, Pseudo,
(outs GR64:$dst), (ins GR64:$src1, i64i32imm:$src2),
"", // orq/addq REG, imm
[(set GR64:$dst, (or_is_add GR64:$src1,
i64immSExt32:$src2))]>;
}
} // AddedComplexity, SchedRW
//===----------------------------------------------------------------------===//
// Some peepholes
//===----------------------------------------------------------------------===//
// Odd encoding trick: -128 fits into an 8-bit immediate field while
// +128 doesn't, so in this special case use a sub instead of an add.
def : Pat<(add GR16:$src1, 128),
(SUB16ri8 GR16:$src1, -128)>;
def : Pat<(store (add (loadi16 addr:$dst), 128), addr:$dst),
(SUB16mi8 addr:$dst, -128)>;
def : Pat<(add GR32:$src1, 128),
(SUB32ri8 GR32:$src1, -128)>;
def : Pat<(store (add (loadi32 addr:$dst), 128), addr:$dst),
(SUB32mi8 addr:$dst, -128)>;
def : Pat<(add GR64:$src1, 128),
(SUB64ri8 GR64:$src1, -128)>;
def : Pat<(store (add (loadi64 addr:$dst), 128), addr:$dst),
(SUB64mi8 addr:$dst, -128)>;
// The same trick applies for 32-bit immediate fields in 64-bit
// instructions.
def : Pat<(add GR64:$src1, 0x0000000080000000),
(SUB64ri32 GR64:$src1, 0xffffffff80000000)>;
def : Pat<(store (add (loadi64 addr:$dst), 0x0000000080000000), addr:$dst),
(SUB64mi32 addr:$dst, 0xffffffff80000000)>;
// To avoid needing to materialize an immediate in a register, use a 32-bit and
// with implicit zero-extension instead of a 64-bit and if the immediate has at
// least 32 bits of leading zeros. If in addition the last 32 bits can be
// represented with a sign extension of a 8 bit constant, use that.
// This can also reduce instruction size by eliminating the need for the REX
// prefix.
// AddedComplexity is needed to give priority over i64immSExt8 and i64immSExt32.
let AddedComplexity = 1 in {
def : Pat<(and GR64:$src, i64immZExt32SExt8:$imm),
(SUBREG_TO_REG
(i64 0),
(AND32ri8
(EXTRACT_SUBREG GR64:$src, sub_32bit),
(i32 (GetLo8XForm imm:$imm))),
sub_32bit)>;
def : Pat<(and GR64:$src, i64immZExt32:$imm),
(SUBREG_TO_REG
(i64 0),
(AND32ri
(EXTRACT_SUBREG GR64:$src, sub_32bit),
(i32 (GetLo32XForm imm:$imm))),
sub_32bit)>;
} // AddedComplexity = 1
// AddedComplexity is needed due to the increased complexity on the
// i64immZExt32SExt8 and i64immZExt32 patterns above. Applying this to all
// the MOVZX patterns keeps thems together in DAGIsel tables.
let AddedComplexity = 1 in {
// r & (2^16-1) ==> movz
def : Pat<(and GR32:$src1, 0xffff),
(MOVZX32rr16 (EXTRACT_SUBREG GR32:$src1, sub_16bit))>;
// r & (2^8-1) ==> movz
def : Pat<(and GR32:$src1, 0xff),
(MOVZX32rr8 (EXTRACT_SUBREG GR32:$src1, sub_8bit))>;
// r & (2^8-1) ==> movz
def : Pat<(and GR16:$src1, 0xff),
(EXTRACT_SUBREG (MOVZX32rr8 (EXTRACT_SUBREG GR16:$src1, sub_8bit)),
sub_16bit)>;
// r & (2^32-1) ==> movz
def : Pat<(and GR64:$src, 0x00000000FFFFFFFF),
(SUBREG_TO_REG (i64 0),
(MOV32rr (EXTRACT_SUBREG GR64:$src, sub_32bit)),
sub_32bit)>;
// r & (2^16-1) ==> movz
def : Pat<(and GR64:$src, 0xffff),
(SUBREG_TO_REG (i64 0),
(MOVZX32rr16 (i16 (EXTRACT_SUBREG GR64:$src, sub_16bit))),
sub_32bit)>;
// r & (2^8-1) ==> movz
def : Pat<(and GR64:$src, 0xff),
(SUBREG_TO_REG (i64 0),
(MOVZX32rr8 (i8 (EXTRACT_SUBREG GR64:$src, sub_8bit))),
sub_32bit)>;
} // AddedComplexity = 1
// Try to use BTS/BTR/BTC for single bit operations on the upper 32-bits.
def BTRXForm : SDNodeXForm<imm, [{
// Transformation function: Find the lowest 0.
return getI64Imm((uint8_t)N->getAPIntValue().countTrailingOnes(), SDLoc(N));
}]>;
def BTCBTSXForm : SDNodeXForm<imm, [{
// Transformation function: Find the lowest 1.
return getI64Imm((uint8_t)N->getAPIntValue().countTrailingZeros(), SDLoc(N));
}]>;
def BTRMask64 : ImmLeaf<i64, [{
return !isUInt<32>(Imm) && !isInt<32>(Imm) && isPowerOf2_64(~Imm);
}]>;
def BTCBTSMask64 : ImmLeaf<i64, [{
return !isInt<32>(Imm) && isPowerOf2_64(Imm);
}]>;
// For now only do this for optsize.
let AddedComplexity = 1, Predicates=[OptForSize] in {
def : Pat<(and GR64:$src1, BTRMask64:$mask),
(BTR64ri8 GR64:$src1, (BTRXForm imm:$mask))>;
def : Pat<(or GR64:$src1, BTCBTSMask64:$mask),
(BTS64ri8 GR64:$src1, (BTCBTSXForm imm:$mask))>;
def : Pat<(xor GR64:$src1, BTCBTSMask64:$mask),
(BTC64ri8 GR64:$src1, (BTCBTSXForm imm:$mask))>;
}
// sext_inreg patterns
def : Pat<(sext_inreg GR32:$src, i16),
(MOVSX32rr16 (EXTRACT_SUBREG GR32:$src, sub_16bit))>;
def : Pat<(sext_inreg GR32:$src, i8),
(MOVSX32rr8 (EXTRACT_SUBREG GR32:$src, sub_8bit))>;
def : Pat<(sext_inreg GR16:$src, i8),
(EXTRACT_SUBREG (MOVSX32rr8 (EXTRACT_SUBREG GR16:$src, sub_8bit)),
sub_16bit)>;
def : Pat<(sext_inreg GR64:$src, i32),
(MOVSX64rr32 (EXTRACT_SUBREG GR64:$src, sub_32bit))>;
def : Pat<(sext_inreg GR64:$src, i16),
(MOVSX64rr16 (EXTRACT_SUBREG GR64:$src, sub_16bit))>;
def : Pat<(sext_inreg GR64:$src, i8),
(MOVSX64rr8 (EXTRACT_SUBREG GR64:$src, sub_8bit))>;
// sext, sext_load, zext, zext_load
def: Pat<(i16 (sext GR8:$src)),
(EXTRACT_SUBREG (MOVSX32rr8 GR8:$src), sub_16bit)>;
def: Pat<(sextloadi16i8 addr:$src),
(EXTRACT_SUBREG (MOVSX32rm8 addr:$src), sub_16bit)>;
def: Pat<(i16 (zext GR8:$src)),
(EXTRACT_SUBREG (MOVZX32rr8 GR8:$src), sub_16bit)>;
def: Pat<(zextloadi16i8 addr:$src),
(EXTRACT_SUBREG (MOVZX32rm8 addr:$src), sub_16bit)>;
// trunc patterns
def : Pat<(i16 (trunc GR32:$src)),
(EXTRACT_SUBREG GR32:$src, sub_16bit)>;
def : Pat<(i8 (trunc GR32:$src)),
(EXTRACT_SUBREG (i32 (COPY_TO_REGCLASS GR32:$src, GR32_ABCD)),
sub_8bit)>,
Requires<[Not64BitMode]>;
def : Pat<(i8 (trunc GR16:$src)),
(EXTRACT_SUBREG (i16 (COPY_TO_REGCLASS GR16:$src, GR16_ABCD)),
sub_8bit)>,
Requires<[Not64BitMode]>;
def : Pat<(i32 (trunc GR64:$src)),
(EXTRACT_SUBREG GR64:$src, sub_32bit)>;
def : Pat<(i16 (trunc GR64:$src)),
(EXTRACT_SUBREG GR64:$src, sub_16bit)>;
def : Pat<(i8 (trunc GR64:$src)),
(EXTRACT_SUBREG GR64:$src, sub_8bit)>;
def : Pat<(i8 (trunc GR32:$src)),
(EXTRACT_SUBREG GR32:$src, sub_8bit)>,
Requires<[In64BitMode]>;
def : Pat<(i8 (trunc GR16:$src)),
(EXTRACT_SUBREG GR16:$src, sub_8bit)>,
Requires<[In64BitMode]>;
def immff00_ffff : ImmLeaf<i32, [{
return Imm >= 0xff00 && Imm <= 0xffff;
}]>;
// h-register tricks
def : Pat<(i8 (trunc (srl_su GR16:$src, (i8 8)))),
(EXTRACT_SUBREG GR16:$src, sub_8bit_hi)>,
Requires<[Not64BitMode]>;
def : Pat<(i8 (trunc (srl_su (i32 (anyext GR16:$src)), (i8 8)))),
(EXTRACT_SUBREG GR16:$src, sub_8bit_hi)>,
Requires<[Not64BitMode]>;
def : Pat<(i8 (trunc (srl_su GR32:$src, (i8 8)))),
(EXTRACT_SUBREG GR32:$src, sub_8bit_hi)>,
Requires<[Not64BitMode]>;
def : Pat<(srl GR16:$src, (i8 8)),
(EXTRACT_SUBREG
(MOVZX32_NOREXrr8 (EXTRACT_SUBREG GR16:$src, sub_8bit_hi)),
sub_16bit)>;
def : Pat<(i32 (zext (srl_su GR16:$src, (i8 8)))),
(MOVZX32_NOREXrr8 (EXTRACT_SUBREG GR16:$src, sub_8bit_hi))>;
def : Pat<(i32 (anyext (srl_su GR16:$src, (i8 8)))),
(MOVZX32_NOREXrr8 (EXTRACT_SUBREG GR16:$src, sub_8bit_hi))>;
def : Pat<(and (srl_su GR32:$src, (i8 8)), (i32 255)),
(MOVZX32_NOREXrr8 (EXTRACT_SUBREG GR32:$src, sub_8bit_hi))>;
def : Pat<(srl (and_su GR32:$src, immff00_ffff), (i8 8)),
(MOVZX32_NOREXrr8 (EXTRACT_SUBREG GR32:$src, sub_8bit_hi))>;
// h-register tricks.
// For now, be conservative on x86-64 and use an h-register extract only if the
// value is immediately zero-extended or stored, which are somewhat common
// cases. This uses a bunch of code to prevent a register requiring a REX prefix
// from being allocated in the same instruction as the h register, as there's
// currently no way to describe this requirement to the register allocator.
// h-register extract and zero-extend.
def : Pat<(and (srl_su GR64:$src, (i8 8)), (i64 255)),
(SUBREG_TO_REG
(i64 0),
(MOVZX32_NOREXrr8
(EXTRACT_SUBREG GR64:$src, sub_8bit_hi)),
sub_32bit)>;
def : Pat<(i64 (zext (srl_su GR16:$src, (i8 8)))),
(SUBREG_TO_REG
(i64 0),
(MOVZX32_NOREXrr8
(EXTRACT_SUBREG GR16:$src, sub_8bit_hi)),
sub_32bit)>;
def : Pat<(i64 (anyext (srl_su GR16:$src, (i8 8)))),
(SUBREG_TO_REG
(i64 0),
(MOVZX32_NOREXrr8
(EXTRACT_SUBREG GR16:$src, sub_8bit_hi)),
sub_32bit)>;
// h-register extract and store.
def : Pat<(store (i8 (trunc_su (srl_su GR64:$src, (i8 8)))), addr:$dst),
(MOV8mr_NOREX
addr:$dst,
(EXTRACT_SUBREG GR64:$src, sub_8bit_hi))>;
def : Pat<(store (i8 (trunc_su (srl_su GR32:$src, (i8 8)))), addr:$dst),
(MOV8mr_NOREX
addr:$dst,
(EXTRACT_SUBREG GR32:$src, sub_8bit_hi))>,
Requires<[In64BitMode]>;
def : Pat<(store (i8 (trunc_su (srl_su GR16:$src, (i8 8)))), addr:$dst),
(MOV8mr_NOREX
addr:$dst,
(EXTRACT_SUBREG GR16:$src, sub_8bit_hi))>,
Requires<[In64BitMode]>;
// (shl x, 1) ==> (add x, x)
// Note that if x is undef (immediate or otherwise), we could theoretically
// end up with the two uses of x getting different values, producing a result
// where the least significant bit is not 0. However, the probability of this
// happening is considered low enough that this is officially not a
// "real problem".
def : Pat<(shl GR8 :$src1, (i8 1)), (ADD8rr GR8 :$src1, GR8 :$src1)>;
def : Pat<(shl GR16:$src1, (i8 1)), (ADD16rr GR16:$src1, GR16:$src1)>;
def : Pat<(shl GR32:$src1, (i8 1)), (ADD32rr GR32:$src1, GR32:$src1)>;
def : Pat<(shl GR64:$src1, (i8 1)), (ADD64rr GR64:$src1, GR64:$src1)>;
// Helper imms to check if a mask doesn't change significant shift/rotate bits.
def immShift8 : ImmLeaf<i8, [{
return countTrailingOnes<uint64_t>(Imm) >= 3;
}]>;
def immShift16 : ImmLeaf<i8, [{
return countTrailingOnes<uint64_t>(Imm) >= 4;
}]>;
def immShift32 : ImmLeaf<i8, [{
return countTrailingOnes<uint64_t>(Imm) >= 5;
}]>;
def immShift64 : ImmLeaf<i8, [{
return countTrailingOnes<uint64_t>(Imm) >= 6;
}]>;
// Shift amount is implicitly masked.
multiclass MaskedShiftAmountPats<SDNode frag, string name> {
// (shift x (and y, 31)) ==> (shift x, y)
def : Pat<(frag GR8:$src1, (and CL, immShift32)),
(!cast<Instruction>(name # "8rCL") GR8:$src1)>;
def : Pat<(frag GR16:$src1, (and CL, immShift32)),
(!cast<Instruction>(name # "16rCL") GR16:$src1)>;
def : Pat<(frag GR32:$src1, (and CL, immShift32)),
(!cast<Instruction>(name # "32rCL") GR32:$src1)>;
def : Pat<(store (frag (loadi8 addr:$dst), (and CL, immShift32)), addr:$dst),
(!cast<Instruction>(name # "8mCL") addr:$dst)>;
def : Pat<(store (frag (loadi16 addr:$dst), (and CL, immShift32)), addr:$dst),
(!cast<Instruction>(name # "16mCL") addr:$dst)>;
def : Pat<(store (frag (loadi32 addr:$dst), (and CL, immShift32)), addr:$dst),
(!cast<Instruction>(name # "32mCL") addr:$dst)>;
// (shift x (and y, 63)) ==> (shift x, y)
def : Pat<(frag GR64:$src1, (and CL, immShift64)),
(!cast<Instruction>(name # "64rCL") GR64:$src1)>;
def : Pat<(store (frag (loadi64 addr:$dst), (and CL, immShift64)), addr:$dst),
(!cast<Instruction>(name # "64mCL") addr:$dst)>;
}
defm : MaskedShiftAmountPats<shl, "SHL">;
defm : MaskedShiftAmountPats<srl, "SHR">;
defm : MaskedShiftAmountPats<sra, "SAR">;
// ROL/ROR instructions allow a stronger mask optimization than shift for 8- and
// 16-bit. We can remove a mask of any (bitwidth - 1) on the rotation amount
// because over-rotating produces the same result. This is noted in the Intel
// docs with: "tempCOUNT <- (COUNT & COUNTMASK) MOD SIZE". Masking the rotation
// amount could affect EFLAGS results, but that does not matter because we are
// not tracking flags for these nodes.
multiclass MaskedRotateAmountPats<SDNode frag, string name> {
// (rot x (and y, BitWidth - 1)) ==> (rot x, y)
def : Pat<(frag GR8:$src1, (and CL, immShift8)),
(!cast<Instruction>(name # "8rCL") GR8:$src1)>;
def : Pat<(frag GR16:$src1, (and CL, immShift16)),
(!cast<Instruction>(name # "16rCL") GR16:$src1)>;
def : Pat<(frag GR32:$src1, (and CL, immShift32)),
(!cast<Instruction>(name # "32rCL") GR32:$src1)>;
def : Pat<(store (frag (loadi8 addr:$dst), (and CL, immShift8)), addr:$dst),
(!cast<Instruction>(name # "8mCL") addr:$dst)>;
def : Pat<(store (frag (loadi16 addr:$dst), (and CL, immShift16)), addr:$dst),
(!cast<Instruction>(name # "16mCL") addr:$dst)>;
def : Pat<(store (frag (loadi32 addr:$dst), (and CL, immShift32)), addr:$dst),
(!cast<Instruction>(name # "32mCL") addr:$dst)>;
// (rot x (and y, 63)) ==> (rot x, y)
def : Pat<(frag GR64:$src1, (and CL, immShift64)),
(!cast<Instruction>(name # "64rCL") GR64:$src1)>;
def : Pat<(store (frag (loadi64 addr:$dst), (and CL, immShift64)), addr:$dst),
(!cast<Instruction>(name # "64mCL") addr:$dst)>;
}
defm : MaskedRotateAmountPats<rotl, "ROL">;
defm : MaskedRotateAmountPats<rotr, "ROR">;
// Double shift amount is implicitly masked.
multiclass MaskedDoubleShiftAmountPats<SDNode frag, string name> {
// (shift x (and y, 31)) ==> (shift x, y)
def : Pat<(frag GR16:$src1, GR16:$src2, (and CL, immShift32)),
(!cast<Instruction>(name # "16rrCL") GR16:$src1, GR16:$src2)>;
def : Pat<(frag GR32:$src1, GR32:$src2, (and CL, immShift32)),
(!cast<Instruction>(name # "32rrCL") GR32:$src1, GR32:$src2)>;
// (shift x (and y, 63)) ==> (shift x, y)
def : Pat<(frag GR64:$src1, GR64:$src2, (and CL, immShift64)),
(!cast<Instruction>(name # "64rrCL") GR64:$src1, GR64:$src2)>;
}
defm : MaskedDoubleShiftAmountPats<X86shld, "SHLD">;
defm : MaskedDoubleShiftAmountPats<X86shrd, "SHRD">;
let Predicates = [HasBMI2] in {
let AddedComplexity = 1 in {
def : Pat<(sra GR32:$src1, (and GR8:$src2, immShift32)),
(SARX32rr GR32:$src1,
(INSERT_SUBREG
(i32 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(sra GR64:$src1, (and GR8:$src2, immShift64)),
(SARX64rr GR64:$src1,
(INSERT_SUBREG
(i64 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(srl GR32:$src1, (and GR8:$src2, immShift32)),
(SHRX32rr GR32:$src1,
(INSERT_SUBREG
(i32 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(srl GR64:$src1, (and GR8:$src2, immShift64)),
(SHRX64rr GR64:$src1,
(INSERT_SUBREG
(i64 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(shl GR32:$src1, (and GR8:$src2, immShift32)),
(SHLX32rr GR32:$src1,
(INSERT_SUBREG
(i32 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(shl GR64:$src1, (and GR8:$src2, immShift64)),
(SHLX64rr GR64:$src1,
(INSERT_SUBREG
(i64 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
}
let AddedComplexity = -20 in {
def : Pat<(sra (loadi32 addr:$src1), (and GR8:$src2, immShift32)),
(SARX32rm addr:$src1,
(INSERT_SUBREG
(i32 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(sra (loadi64 addr:$src1), (and GR8:$src2, immShift64)),
(SARX64rm addr:$src1,
(INSERT_SUBREG
(i64 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(srl (loadi32 addr:$src1), (and GR8:$src2, immShift32)),
(SHRX32rm addr:$src1,
(INSERT_SUBREG
(i32 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(srl (loadi64 addr:$src1), (and GR8:$src2, immShift64)),
(SHRX64rm addr:$src1,
(INSERT_SUBREG
(i64 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(shl (loadi32 addr:$src1), (and GR8:$src2, immShift32)),
(SHLX32rm addr:$src1,
(INSERT_SUBREG
(i32 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
def : Pat<(shl (loadi64 addr:$src1), (and GR8:$src2, immShift64)),
(SHLX64rm addr:$src1,
(INSERT_SUBREG
(i64 (IMPLICIT_DEF)), GR8:$src2, sub_8bit))>;
}
}
// (anyext (setcc_carry)) -> (setcc_carry)
def : Pat<(i16 (anyext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C16r)>;
def : Pat<(i32 (anyext (i8 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C32r)>;
def : Pat<(i32 (anyext (i16 (X86setcc_c X86_COND_B, EFLAGS)))),
(SETB_C32r)>;
//===----------------------------------------------------------------------===//
// EFLAGS-defining Patterns
//===----------------------------------------------------------------------===//
// add reg, reg
def : Pat<(add GR8 :$src1, GR8 :$src2), (ADD8rr GR8 :$src1, GR8 :$src2)>;
def : Pat<(add GR16:$src1, GR16:$src2), (ADD16rr GR16:$src1, GR16:$src2)>;
def : Pat<(add GR32:$src1, GR32:$src2), (ADD32rr GR32:$src1, GR32:$src2)>;
// add reg, mem
def : Pat<(add GR8:$src1, (loadi8 addr:$src2)),
(ADD8rm GR8:$src1, addr:$src2)>;
def : Pat<(add GR16:$src1, (loadi16 addr:$src2)),
(ADD16rm GR16:$src1, addr:$src2)>;
def : Pat<(add GR32:$src1, (loadi32 addr:$src2)),
(ADD32rm GR32:$src1, addr:$src2)>;
// add reg, imm
def : Pat<(add GR8 :$src1, imm:$src2), (ADD8ri GR8:$src1 , imm:$src2)>;
def : Pat<(add GR16:$src1, imm:$src2), (ADD16ri GR16:$src1, imm:$src2)>;
def : Pat<(add GR32:$src1, imm:$src2), (ADD32ri GR32:$src1, imm:$src2)>;
def : Pat<(add GR16:$src1, i16immSExt8:$src2),
(ADD16ri8 GR16:$src1, i16immSExt8:$src2)>;
def : Pat<(add GR32:$src1, i32immSExt8:$src2),
(ADD32ri8 GR32:$src1, i32immSExt8:$src2)>;
// sub reg, reg
def : Pat<(sub GR8 :$src1, GR8 :$src2), (SUB8rr GR8 :$src1, GR8 :$src2)>;
def : Pat<(sub GR16:$src1, GR16:$src2), (SUB16rr GR16:$src1, GR16:$src2)>;
def : Pat<(sub GR32:$src1, GR32:$src2), (SUB32rr GR32:$src1, GR32:$src2)>;
// sub reg, mem
def : Pat<(sub GR8:$src1, (loadi8 addr:$src2)),
(SUB8rm GR8:$src1, addr:$src2)>;
def : Pat<(sub GR16:$src1, (loadi16 addr:$src2)),
(SUB16rm GR16:$src1, addr:$src2)>;
def : Pat<(sub GR32:$src1, (loadi32 addr:$src2)),
(SUB32rm GR32:$src1, addr:$src2)>;
// sub reg, imm
def : Pat<(sub GR8:$src1, imm:$src2),
(SUB8ri GR8:$src1, imm:$src2)>;
def : Pat<(sub GR16:$src1, imm:$src2),
(SUB16ri GR16:$src1, imm:$src2)>;
def : Pat<(sub GR32:$src1, imm:$src2),
(SUB32ri GR32:$src1, imm:$src2)>;
def : Pat<(sub GR16:$src1, i16immSExt8:$src2),
(SUB16ri8 GR16:$src1, i16immSExt8:$src2)>;
def : Pat<(sub GR32:$src1, i32immSExt8:$src2),
(SUB32ri8 GR32:$src1, i32immSExt8:$src2)>;
// sub 0, reg
def : Pat<(X86sub_flag 0, GR8 :$src), (NEG8r GR8 :$src)>;
def : Pat<(X86sub_flag 0, GR16:$src), (NEG16r GR16:$src)>;
def : Pat<(X86sub_flag 0, GR32:$src), (NEG32r GR32:$src)>;
def : Pat<(X86sub_flag 0, GR64:$src), (NEG64r GR64:$src)>;
// sub reg, relocImm
def : Pat<(X86sub_flag GR64:$src1, i64relocImmSExt8_su:$src2),
(SUB64ri8 GR64:$src1, i64relocImmSExt8_su:$src2)>;
def : Pat<(X86sub_flag GR64:$src1, i64relocImmSExt32_su:$src2),
(SUB64ri32 GR64:$src1, i64relocImmSExt32_su:$src2)>;
// mul reg, reg
def : Pat<(mul GR16:$src1, GR16:$src2),
(IMUL16rr GR16:$src1, GR16:$src2)>;
def : Pat<(mul GR32:$src1, GR32:$src2),
(IMUL32rr GR32:$src1, GR32:$src2)>;
// mul reg, mem
def : Pat<(mul GR16:$src1, (loadi16 addr:$src2)),
(IMUL16rm GR16:$src1, addr:$src2)>;
def : Pat<(mul GR32:$src1, (loadi32 addr:$src2)),
(IMUL32rm GR32:$src1, addr:$src2)>;
// mul reg, imm
def : Pat<(mul GR16:$src1, imm:$src2),
(IMUL16rri GR16:$src1, imm:$src2)>;
def : Pat<(mul GR32:$src1, imm:$src2),
(IMUL32rri GR32:$src1, imm:$src2)>;
def : Pat<(mul GR16:$src1, i16immSExt8:$src2),
(IMUL16rri8 GR16:$src1, i16immSExt8:$src2)>;
def : Pat<(mul GR32:$src1, i32immSExt8:$src2),
(IMUL32rri8 GR32:$src1, i32immSExt8:$src2)>;
// reg = mul mem, imm
def : Pat<(mul (loadi16 addr:$src1), imm:$src2),
(IMUL16rmi addr:$src1, imm:$src2)>;
def : Pat<(mul (loadi32 addr:$src1), imm:$src2),
(IMUL32rmi addr:$src1, imm:$src2)>;
def : Pat<(mul (loadi16 addr:$src1), i16immSExt8:$src2),
(IMUL16rmi8 addr:$src1, i16immSExt8:$src2)>;
def : Pat<(mul (loadi32 addr:$src1), i32immSExt8:$src2),
(IMUL32rmi8 addr:$src1, i32immSExt8:$src2)>;
// Patterns for nodes that do not produce flags, for instructions that do.
// addition
def : Pat<(add GR64:$src1, GR64:$src2),
(ADD64rr GR64:$src1, GR64:$src2)>;
def : Pat<(add GR64:$src1, i64immSExt8:$src2),
(ADD64ri8 GR64:$src1, i64immSExt8:$src2)>;
def : Pat<(add GR64:$src1, i64immSExt32:$src2),
(ADD64ri32 GR64:$src1, i64immSExt32:$src2)>;
def : Pat<(add GR64:$src1, (loadi64 addr:$src2)),
(ADD64rm GR64:$src1, addr:$src2)>;
// subtraction
def : Pat<(sub GR64:$src1, GR64:$src2),
(SUB64rr GR64:$src1, GR64:$src2)>;
def : Pat<(sub GR64:$src1, (loadi64 addr:$src2)),
(SUB64rm GR64:$src1, addr:$src2)>;
def : Pat<(sub GR64:$src1, i64immSExt8:$src2),
(SUB64ri8 GR64:$src1, i64immSExt8:$src2)>;
def : Pat<(sub GR64:$src1, i64immSExt32:$src2),
(SUB64ri32 GR64:$src1, i64immSExt32:$src2)>;
// Multiply
def : Pat<(mul GR64:$src1, GR64:$src2),
(IMUL64rr GR64:$src1, GR64:$src2)>;
def : Pat<(mul GR64:$src1, (loadi64 addr:$src2)),
(IMUL64rm GR64:$src1, addr:$src2)>;
def : Pat<(mul GR64:$src1, i64immSExt8:$src2),
(IMUL64rri8 GR64:$src1, i64immSExt8:$src2)>;
def : Pat<(mul GR64:$src1, i64immSExt32:$src2),
(IMUL64rri32 GR64:$src1, i64immSExt32:$src2)>;
def : Pat<(mul (loadi64 addr:$src1), i64immSExt8:$src2),
(IMUL64rmi8 addr:$src1, i64immSExt8:$src2)>;
def : Pat<(mul (loadi64 addr:$src1), i64immSExt32:$src2),
(IMUL64rmi32 addr:$src1, i64immSExt32:$src2)>;
// Increment/Decrement reg.
// Do not make INC/DEC if it is slow
let Predicates = [UseIncDec] in {
def : Pat<(add GR8:$src, 1), (INC8r GR8:$src)>;
def : Pat<(add GR16:$src, 1), (INC16r GR16:$src)>;
def : Pat<(add GR32:$src, 1), (INC32r GR32:$src)>;
def : Pat<(add GR64:$src, 1), (INC64r GR64:$src)>;
def : Pat<(add GR8:$src, -1), (DEC8r GR8:$src)>;
def : Pat<(add GR16:$src, -1), (DEC16r GR16:$src)>;
def : Pat<(add GR32:$src, -1), (DEC32r GR32:$src)>;
def : Pat<(add GR64:$src, -1), (DEC64r GR64:$src)>;
}
// or reg/reg.
def : Pat<(or GR8 :$src1, GR8 :$src2), (OR8rr GR8 :$src1, GR8 :$src2)>;
def : Pat<(or GR16:$src1, GR16:$src2), (OR16rr GR16:$src1, GR16:$src2)>;
def : Pat<(or GR32:$src1, GR32:$src2), (OR32rr GR32:$src1, GR32:$src2)>;
def : Pat<(or GR64:$src1, GR64:$src2), (OR64rr GR64:$src1, GR64:$src2)>;
// or reg/mem
def : Pat<(or GR8:$src1, (loadi8 addr:$src2)),
(OR8rm GR8:$src1, addr:$src2)>;
def : Pat<(or GR16:$src1, (loadi16 addr:$src2)),
(OR16rm GR16:$src1, addr:$src2)>;
def : Pat<(or GR32:$src1, (loadi32 addr:$src2)),
(OR32rm GR32:$src1, addr:$src2)>;
def : Pat<(or GR64:$src1, (loadi64 addr:$src2)),
(OR64rm GR64:$src1, addr:$src2)>;
// or reg/imm
def : Pat<(or GR8:$src1 , imm:$src2), (OR8ri GR8 :$src1, imm:$src2)>;
def : Pat<(or GR16:$src1, imm:$src2), (OR16ri GR16:$src1, imm:$src2)>;
def : Pat<(or GR32:$src1, imm:$src2), (OR32ri GR32:$src1, imm:$src2)>;
def : Pat<(or GR16:$src1, i16immSExt8:$src2),
(OR16ri8 GR16:$src1, i16immSExt8:$src2)>;
def : Pat<(or GR32:$src1, i32immSExt8:$src2),
(OR32ri8 GR32:$src1, i32immSExt8:$src2)>;
def : Pat<(or GR64:$src1, i64immSExt8:$src2),
(OR64ri8 GR64:$src1, i64immSExt8:$src2)>;
def : Pat<(or GR64:$src1, i64immSExt32:$src2),
(OR64ri32 GR64:$src1, i64immSExt32:$src2)>;
// xor reg/reg
def : Pat<(xor GR8 :$src1, GR8 :$src2), (XOR8rr GR8 :$src1, GR8 :$src2)>;
def : Pat<(xor GR16:$src1, GR16:$src2), (XOR16rr GR16:$src1, GR16:$src2)>;
def : Pat<(xor GR32:$src1, GR32:$src2), (XOR32rr GR32:$src1, GR32:$src2)>;
def : Pat<(xor GR64:$src1, GR64:$src2), (XOR64rr GR64:$src1, GR64:$src2)>;
// xor reg/mem
def : Pat<(xor GR8:$src1, (loadi8 addr:$src2)),
(XOR8rm GR8:$src1, addr:$src2)>;
def : Pat<(xor GR16:$src1, (loadi16 addr:$src2)),
(XOR16rm GR16:$src1, addr:$src2)>;
def : Pat<(xor GR32:$src1, (loadi32 addr:$src2)),
(XOR32rm GR32:$src1, addr:$src2)>;
def : Pat<(xor GR64:$src1, (loadi64 addr:$src2)),
(XOR64rm GR64:$src1, addr:$src2)>;
// xor reg/imm
def : Pat<(xor GR8:$src1, imm:$src2),
(XOR8ri GR8:$src1, imm:$src2)>;
def : Pat<(xor GR16:$src1, imm:$src2),
(XOR16ri GR16:$src1, imm:$src2)>;
def : Pat<(xor GR32:$src1, imm:$src2),
(XOR32ri GR32:$src1, imm:$src2)>;
def : Pat<(xor GR16:$src1, i16immSExt8:$src2),
(XOR16ri8 GR16:$src1, i16immSExt8:$src2)>;
def : Pat<(xor GR32:$src1, i32immSExt8:$src2),
(XOR32ri8 GR32:$src1, i32immSExt8:$src2)>;
def : Pat<(xor GR64:$src1, i64immSExt8:$src2),
(XOR64ri8 GR64:$src1, i64immSExt8:$src2)>;
def : Pat<(xor GR64:$src1, i64immSExt32:$src2),
(XOR64ri32 GR64:$src1, i64immSExt32:$src2)>;
// and reg/reg
def : Pat<(and GR8 :$src1, GR8 :$src2), (AND8rr GR8 :$src1, GR8 :$src2)>;
def : Pat<(and GR16:$src1, GR16:$src2), (AND16rr GR16:$src1, GR16:$src2)>;
def : Pat<(and GR32:$src1, GR32:$src2), (AND32rr GR32:$src1, GR32:$src2)>;
def : Pat<(and GR64:$src1, GR64:$src2), (AND64rr GR64:$src1, GR64:$src2)>;
// and reg/mem
def : Pat<(and GR8:$src1, (loadi8 addr:$src2)),
(AND8rm GR8:$src1, addr:$src2)>;
def : Pat<(and GR16:$src1, (loadi16 addr:$src2)),
(AND16rm GR16:$src1, addr:$src2)>;
def : Pat<(and GR32:$src1, (loadi32 addr:$src2)),
(AND32rm GR32:$src1, addr:$src2)>;
def : Pat<(and GR64:$src1, (loadi64 addr:$src2)),
(AND64rm GR64:$src1, addr:$src2)>;
// and reg/imm
def : Pat<(and GR8:$src1, imm:$src2),
(AND8ri GR8:$src1, imm:$src2)>;
def : Pat<(and GR16:$src1, imm:$src2),
(AND16ri GR16:$src1, imm:$src2)>;
def : Pat<(and GR32:$src1, imm:$src2),
(AND32ri GR32:$src1, imm:$src2)>;
def : Pat<(and GR16:$src1, i16immSExt8:$src2),
(AND16ri8 GR16:$src1, i16immSExt8:$src2)>;
def : Pat<(and GR32:$src1, i32immSExt8:$src2),
(AND32ri8 GR32:$src1, i32immSExt8:$src2)>;
def : Pat<(and GR64:$src1, i64immSExt8:$src2),
(AND64ri8 GR64:$src1, i64immSExt8:$src2)>;
def : Pat<(and GR64:$src1, i64immSExt32:$src2),
(AND64ri32 GR64:$src1, i64immSExt32:$src2)>;
// Bit scan instruction patterns to match explicit zero-undef behavior.
def : Pat<(cttz_zero_undef GR16:$src), (BSF16rr GR16:$src)>;
def : Pat<(cttz_zero_undef GR32:$src), (BSF32rr GR32:$src)>;
def : Pat<(cttz_zero_undef GR64:$src), (BSF64rr GR64:$src)>;
def : Pat<(cttz_zero_undef (loadi16 addr:$src)), (BSF16rm addr:$src)>;
def : Pat<(cttz_zero_undef (loadi32 addr:$src)), (BSF32rm addr:$src)>;
def : Pat<(cttz_zero_undef (loadi64 addr:$src)), (BSF64rm addr:$src)>;
// When HasMOVBE is enabled it is possible to get a non-legalized
// register-register 16 bit bswap. This maps it to a ROL instruction.
let Predicates = [HasMOVBE] in {
def : Pat<(bswap GR16:$src), (ROL16ri GR16:$src, (i8 8))>;
}
// These patterns are selected by some custom code in X86ISelDAGToDAG.cpp that
// custom combines and+srl into BEXTR. We use these patterns to avoid a bunch
// of manual code for folding loads.
let Predicates = [HasBMI, NoTBM] in {
def : Pat<(X86bextr GR32:$src1, (i32 imm:$src2)),
(BEXTR32rr GR32:$src1, (MOV32ri imm:$src2))>;
def : Pat<(X86bextr (loadi32 addr:$src1), (i32 imm:$src2)),
(BEXTR32rm addr:$src1, (MOV32ri imm:$src2))>;
def : Pat<(X86bextr GR64:$src1, mov64imm32:$src2),
(BEXTR64rr GR64:$src1,
(SUBREG_TO_REG (i64 0),
(MOV32ri64 mov64imm32:$src2),
sub_32bit))>;
def : Pat<(X86bextr (loadi64 addr:$src1), mov64imm32:$src2),
(BEXTR64rm addr:$src1,
(SUBREG_TO_REG (i64 0),
(MOV32ri64 mov64imm32:$src2),
sub_32bit))>;
} // HasBMI, NoTBM
let Predicates = [HasTBM] in {
def : Pat<(X86bextr GR32:$src1, (i32 imm:$src2)),
(BEXTRI32ri GR32:$src1, imm:$src2)>;
def : Pat<(X86bextr (loadi32 addr:$src1), (i32 imm:$src2)),
(BEXTRI32mi addr:$src1, imm:$src2)>;
def : Pat<(X86bextr GR64:$src1, i64immSExt32:$src2),
(BEXTRI64ri GR64:$src1, i64immSExt32:$src2)>;
def : Pat<(X86bextr (loadi64 addr:$src1), i64immSExt32:$src2),
(BEXTRI64mi addr:$src1, i64immSExt32:$src2)>;
}