| // -*- mode:c++ -*- |
| |
| // Copyright (c) 2018 Metempsy Technology Consulting |
| // All rights reserved |
| // |
| // The license below extends only to copyright in the software and shall |
| // not be construed as granting a license to any other intellectual |
| // property including but not limited to intellectual property relating |
| // to a hardware implementation of the functionality of the software |
| // licensed hereunder. You may use the software subject to the license |
| // terms below provided that you ensure that this notice is replicated |
| // unmodified and in its entirety in all distributions of the software, |
| // modified or unmodified, in source code or in binary form. |
| // |
| // Redistribution and use in source and binary forms, with or without |
| // modification, are permitted provided that the following conditions are |
| // met: redistributions of source code must retain the above copyright |
| // notice, this list of conditions and the following disclaimer; |
| // redistributions in binary form must reproduce the above copyright |
| // notice, this list of conditions and the following disclaimer in the |
| // documentation and/or other materials provided with the distribution; |
| // neither the name of the copyright holders nor the names of its |
| // contributors may be used to endorse or promote products derived from |
| // this software without specific prior written permission. |
| // |
| // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS |
| // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT |
| // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR |
| // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT |
| // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
| // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT |
| // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
| // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY |
| // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT |
| // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE |
| // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
| // |
| // Authors: Jordi Vaquero |
| |
| let {{ |
| |
| import math |
| |
| OP_DICT = { "CAS" : 'if (a == *b){*b = c;}', |
| "SWP" : '*b = c;', |
| "ADD" : '*b += c;', |
| "EOR" : '*b ^= c;', |
| "CLR" : '*b &= ~c;', |
| "SET" : '*b |= c;', |
| "MAX" : '*b = std::max(*b, c);', |
| "MIN" : '*b = std::min(*b, c);', } |
| |
| MASKS = { 1: 0xFF, |
| 2: 0xFFFF, |
| 4: 0xFFFFFFFF, |
| 8: 0xFFFFFFFFFFFFFFFF, |
| } |
| |
| header_output = "" |
| decoder_output = "" |
| exec_output = "" |
| |
| class AtomicInst64(LoadStoreInst): |
| execBase = 'AtomicInst64' |
| micro = False |
| |
| def __init__(self, mnem, Name, size=4, user=False, flavor="normal", |
| unsign=True, top = False, paired=False, ret_op=True): |
| super(AtomicInst64, self).__init__() |
| |
| self.name= mnem |
| self.Name = Name |
| self.size = size |
| self.user = user |
| self.flavor = flavor |
| self.unsign = unsign |
| self.top = top |
| self.paired = paired |
| |
| self.memFlags = ["ArmISA::TLB::MustBeOne"] |
| self.instFlags = ["IsAtomic"] |
| self.codeBlobs = { "postacc_code" : "" } |
| self.codeBlobs['usrDecl'] = "" |
| |
| # Add memory request flags where necessary |
| if self.user: |
| self.memFlags.append("ArmISA::TLB::UserMode") |
| |
| sz = self.size*2 if paired else self.size |
| self.memFlags.append("%d" % int(math.log(sz, 2))) |
| |
| if self.micro: |
| self.instFlags.append("IsMicroop") |
| |
| if self.flavor in ("release", "acquire_release", "acquire"): |
| self.instFlags.append("IsMemBarrier") |
| if self.flavor in ("release", "acquire_release"): |
| self.instFlags.append("IsWriteBarrier") |
| if self.flavor in ("acquire_release", "acquire"): |
| self.instFlags.append("IsReadBarrier") |
| if ret_op: |
| self.memFlags.append('Request::ATOMIC_RETURN_OP') |
| else: |
| self.memFlags.append('Request::ATOMIC_NO_RETURN_OP') |
| |
| def emitHelper(self, base = 'Memory64', wbDecl = None, ): |
| global header_output, decoder_output, exec_output |
| |
| # If this is a microop itself, don't allow anything that would |
| # require further microcoding. |
| if self.micro: |
| assert not wbDecl |
| |
| sas_code = "3" |
| if self.size == 1 : |
| sas_code = "0" |
| elif self.size == 2: |
| sas_code = "1" |
| elif self.size == 4: |
| sas_code = "2" |
| |
| if self.paired and sas_code == "3": |
| sas_code = "4" |
| if self.paired and sas_code == "2": |
| sas_code = "3" |
| |
| |
| fa_code = ''' |
| fault->annotate(ArmFault::SAS, %s); |
| fault->annotate(ArmFault::SSE, %s); |
| fault->annotate(ArmFault::SRT, dest); |
| fault->annotate(ArmFault::SF, %s); |
| fault->annotate(ArmFault::AR, %s); |
| ''' % (sas_code, |
| "true" if not self.unsign else "false", |
| "true" if self.size == 8 else "false", |
| "true" if self.flavor != "normal" else "false") |
| |
| (newHeader, newDecoder, newExec) = \ |
| self.fillTemplates(self.name, self.Name, self.codeBlobs, |
| self.memFlags, self.instFlags, |
| base, wbDecl, faCode=fa_code) |
| |
| header_output += newHeader |
| decoder_output += newDecoder |
| exec_output += newExec |
| |
| def buildEACode(self): |
| # Address computation |
| eaCode = SPAlignmentCheckCode + "EA = XBase" |
| if self.size == 16: |
| if self.top: |
| eaCode += " + (isBigEndian64(xc->tcBase()) ? 0 : 8)" |
| else: |
| eaCode += " + (isBigEndian64(xc->tcBase()) ? 8 : 0)" |
| if not self.post: |
| eaCode += self.offset |
| eaCode += ";" |
| self.codeBlobs["ea_code"] = eaCode |
| |
| |
| class AtomicSingleOp(AtomicInst64): |
| decConstBase = 'AmoOp' |
| base = 'ArmISA::MemoryEx64' |
| writeback = True |
| post = False |
| execBase = 'AmoOp' |
| |
| def __init__(self, *args, **kargs): |
| super(AtomicSingleOp, self).__init__(*args, **kargs) |
| self.suffix = buildMemSuffix(not self.unsign, self.size) |
| if self.size == 8: |
| self.res = 'XResult_ud' #if self.unsign else 'XResult_sd' |
| self.des = 'XDest_ud' #if self.unsign else 'XDest_sd' |
| self.tp = 'uint64_t' if self.unsign else 'int64_t' |
| self.utp = 'uint64_t' |
| self.suffix = '_sd' if not self.unsign else '_ud' |
| elif self.size == 4: |
| self.res = 'XResult_uw' #if self.unsign else 'XResult_sw' |
| self.des = 'XDest_uw' #if self.unsign else 'XDest_sw' |
| self.tp = 'uint32_t' if self.unsign else 'int32_t' |
| self.utp = 'uint32_t' |
| elif self.size == 2: |
| self.res = 'XResult_uh' #if self.unsign else 'XResult_sh' |
| self.des = 'XDest_uh' #if self.unsign else 'XDest_sh' |
| self.tp = 'uint16_t' if self.unsign else 'int16_t' |
| self.utp = 'uint16_t' |
| elif self.size == 1: |
| self.res = 'XResult_ub' #if self.unsign else 'XResult_sb' |
| self.des = 'XDest_ub' #if self.unsign else 'XDest_sb' |
| self.tp = 'uint8_t' if self.unsign else 'int8_t' |
| self.utp = 'uint8_t' |
| self.offset = "" |
| store_res = ''' |
| %(result)s = cSwap(Mem%(suffix)s, |
| isBigEndian64(xc->tcBase())); |
| ''' |
| store_res = store_res % {"result":self.res, "suffix":self.suffix} |
| self.codeBlobs["postacc_code"] = \ |
| store_res + " SevMailbox = 1; LLSCLock = 0;" |
| |
| def emit(self, op): |
| self.buildEACode() |
| usrDecl = "%(type)s valRs;\n" % {'type': self.tp} |
| self.codeBlobs['usrDecl'] = usrDecl |
| |
| opcode = "valRs = cSwap(%(dest)s,"\ |
| " isBigEndian64(xc->tcBase()));\n" |
| opcode += "TypedAtomicOpFunctor<%(type)s> *amo_op = "\ |
| "new AtomicGeneric3Op<%(type)s>(Mem%(suffix)s,"\ |
| " valRs, [](%(type)s* b, %(type)s a,"\ |
| " %(type)s c){ %(op)s });\n" |
| |
| opcode = opcode % {"suffix": self.suffix, |
| "type": self.tp , |
| "dest": self.des, |
| "op": op} |
| self.codeBlobs['amo_code'] = opcode |
| accCode = "Mem%(suffix)s = cSwap(%(result)s,"\ |
| " isBigEndian64(xc->tcBase()));" |
| accCode = accCode % { "result": self.res, "type":self.tp, |
| "suffix": self.suffix} |
| self.codeBlobs["memacc_code"] = accCode |
| self.emitHelper(self.base) |
| |
| |
| AtomicSingleOp("cas", "CAS64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casa", "CASA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casal", "CASAL64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casl", "CASL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['CAS']) |
| |
| AtomicSingleOp("casb", "CASB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casab", "CASAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casalb", "CASALB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CAS']) |
| AtomicSingleOp("caslb", "CASLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['CAS']) |
| |
| AtomicSingleOp("cash", "CASH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casah", "CASAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casalh", "CASALH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CAS']) |
| AtomicSingleOp("caslh", "CASLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['CAS']) |
| |
| AtomicSingleOp("cas", "CAS32", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casa", "CASA32", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casal", "CASAL32", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CAS']) |
| AtomicSingleOp("casl", "CASL32", 4, unsign=True, |
| flavor="release").emit(OP_DICT['CAS']) |
| |
| class CasPair64(AtomicInst64): |
| decConstBase = 'AmoPairOp' |
| base = 'ArmISA::MemoryEx64' |
| writeback = True |
| post = False |
| execBase = 'AmoOp' |
| |
| def __init__(self, *args, **kargs): |
| super(CasPair64, self).__init__(*args, **kargs) |
| self.paired = True |
| self.offset = "" |
| if self.size == 8: |
| self.res = 'XResult_ud' |
| self.des = 'XDest_ud' |
| self.tp = 'std::array<uint64_t, 2>' |
| self.suffix = "_tud" |
| store_res = ''' |
| %(result)s = cSwap(Mem%(suffix)s[0], |
| isBigEndian64(xc->tcBase())); |
| uint64_t result2 = cSwap(Mem%(suffix)s[1], |
| isBigEndian64(xc->tcBase())); |
| xc->setIntRegOperand(this, r2_dst, (result2) |
| & mask(aarch64 ? 64 : 32)); |
| ''' |
| elif self.size == 4: |
| self.res = 'Result_uw' |
| self.des = 'WDest_uw' |
| self.tp = 'uint64_t' |
| self.suffix = "_ud" |
| store_res = ''' |
| uint64_t data = cSwap(Mem%(suffix)s, |
| isBigEndian64(xc->tcBase())); |
| %(result)s = isBigEndian64(xc->tcBase()) |
| ? (data >> 32) |
| : (uint32_t)data; |
| uint32_t result2 = isBigEndian64(xc->tcBase()) |
| ? (uint32_t)data |
| : (data >> 32); |
| xc->setIntRegOperand(this, r2_dst, (result2) & |
| mask(aarch64 ? 64 : 32)); |
| ''' |
| |
| store_res = store_res % {"result":self.res, "suffix":self.suffix} |
| usrDecl = "%(type)s valRs;\n" % {'type': self.tp} |
| self.codeBlobs['usrDecl'] = usrDecl |
| self.codeBlobs["postacc_code"] = \ |
| store_res + " SevMailbox = 1; LLSCLock = 0;" |
| |
| def emit(self): |
| self.buildEACode() |
| |
| # Code that actually handles the access |
| |
| if self.size == 4: |
| accCode = \ |
| "uint32_t result2 = ((xc->readIntRegOperand(this, r2_src))"\ |
| " & mask(aarch64 ? 64 : 32)) ;\n"\ |
| " uint32_t dest2 = ((xc->readIntRegOperand(this, d2_src)) "\ |
| " & mask(aarch64 ? 64 : 32)) ;" |
| accCode += ''' |
| uint64_t data = dest2; |
| data = isBigEndian64(xc->tcBase()) |
| ? ((uint64_t(WDest_uw) << 32) | data) |
| : ((data << 32) | WDest_uw); |
| valRs = cSwap(data, isBigEndian64(xc->tcBase())); |
| uint64_t data2 = result2 ; |
| data2 = isBigEndian64(xc->tcBase()) |
| ? ((uint64_t(Result_uw) << 32) | data2) |
| : ((data2 << 32) | Result_uw); |
| Mem_ud = cSwap(data2, isBigEndian64(xc->tcBase())); |
| ''' |
| |
| opcode = "TypedAtomicOpFunctor<%(type)s> *amo_op = "\ |
| "new AtomicGeneric3Op<%(type)s>(Mem%(suffix)s,"\ |
| " valRs, [](%(type)s* b, %(type)s a,"\ |
| " %(type)s c){ %(op)s });\n" |
| |
| elif self.size == 8: |
| accCode = ""\ |
| "uint64_t result2 = ((xc->readIntRegOperand(this, r2_src))"\ |
| " & mask(aarch64 ? 64 : 32)) ;\n"\ |
| " uint64_t dest2 = ((xc->readIntRegOperand(this, d2_src)) "\ |
| " & mask(aarch64 ? 64 : 32)) ;" |
| accCode += ''' |
| // This temporary needs to be here so that the parser |
| // will correctly identify this instruction as a store. |
| std::array<uint64_t, 2> temp; |
| temp[0] = cSwap(XDest_ud,isBigEndian64(xc->tcBase())); |
| temp[1] = cSwap(dest2,isBigEndian64(xc->tcBase())); |
| valRs = temp; |
| std::array<uint64_t, 2> temp2; |
| temp2[0] = cSwap(XResult_ud,isBigEndian64(xc->tcBase())); |
| temp2[1] = cSwap(result2,isBigEndian64(xc->tcBase())); |
| Mem_tud = temp2; |
| ''' |
| |
| opcode = "TypedAtomicOpFunctor<uint64_t> *amo_op = "\ |
| "new AtomicGenericPair3Op<uint64_t>(Mem_tud, "\ |
| "valRs, [](uint64_t* b, std::array<uint64_t,2> a,"\ |
| ''' |
| std::array<uint64_t,2> c){ |
| if(a[0]==b[0] && a[1]==b[1]){ |
| b[0] = c[0]; b[1] = c[1]; |
| } |
| });''' |
| |
| opcode = opcode % { "suffix" : self.suffix, |
| "type": self.tp, |
| "op": OP_DICT['CAS']} |
| self.codeBlobs['amo_code'] = opcode |
| self.codeBlobs["memacc_code"] = accCode % {"type": self.tp} |
| |
| # Push it out to the output files |
| self.emitHelper(self.base) |
| |
| CasPair64("casp", "CASP64", 8, flavor="normal", paired=True).emit() |
| CasPair64("caspa", "CASPA64", 8, flavor="acquire", paired=True).emit() |
| CasPair64("caspal", "CASPAL64", 8, flavor="acquire_release", |
| paired=True).emit() |
| CasPair64("caspl", "CASPL64", 8, flavor="release", paired=True).emit() |
| |
| CasPair64("casp", "CASP32", 4, flavor="normal", paired=True).emit() |
| CasPair64("caspa", "CASPA32", 4, flavor="acquire", paired=True).emit() |
| CasPair64("caspal", "CASPAL32", 4, flavor="acquire_release", |
| paired=True).emit() |
| CasPair64("caspl", "CASPL32", 4, flavor="release", paired=True).emit() |
| |
| #Set of LD<OP> atomic instructions |
| |
| class AtomicArithmeticSingleOp(AtomicSingleOp): |
| decConstBase = 'AmoArithmeticOp' |
| base = 'ArmISA::MemoryEx64' |
| writeback = True |
| post = False |
| execBase = 'AmoOp' |
| |
| def __init__(self, *args, **kargs): |
| super(AtomicArithmeticSingleOp, self).__init__(*args, **kargs) |
| store_res = "%(utype)s unsMem = Mem%(suffix)s" |
| |
| if self.size != 8: |
| store_res += " & %(mask)s" |
| |
| store_res += ";\n" |
| store_res += ''' if (!isXZR) %(dest)s = cSwap(unsMem, |
| isBigEndian64(xc->tcBase())); |
| ''' |
| store_res = store_res % { "dest": self.des, "suffix":self.suffix, |
| "mask": MASKS[self.size], "utype": self.utp} |
| self.codeBlobs["postacc_code"] = \ |
| store_res + " SevMailbox = 1; LLSCLock = 0;" |
| |
| def emit(self, op): |
| self.buildEACode() |
| |
| opcode = "%(type)s val = cSwap(%(result)s,"\ |
| " isBigEndian64(xc->tcBase()));\n" |
| opcode += "TypedAtomicOpFunctor<%(type)s> *amo_op = "\ |
| "new AtomicGeneric3Op<%(type)s>(Mem%(suffix)s,"\ |
| " val, [](%(type)s* b, %(type)s a,"\ |
| " %(type)s c){ %(op)s });\n" |
| |
| opcode = opcode % { "suffix" : self.suffix, |
| "type": self.tp , "result": self.res, "op": op} |
| self.codeBlobs['amo_code'] = opcode |
| accCode = "Mem%(suffix)s = cSwap(%(dest)s,"\ |
| "isBigEndian64(xc->tcBase()));" |
| accCode = accCode % { "dest": self.des, "suffix":self.suffix} |
| self.codeBlobs["memacc_code"] = accCode |
| self.emitHelper(self.base) |
| |
| |
| AtomicArithmeticSingleOp("ldaddb", "LDADDB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddlb", "LDADDLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddab", "LDADDAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddlab", "LDADDLAB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddh", "LDADDH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddlh", "LDADDLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddah", "LDADDAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddlah", "LDADDLAH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldadd", "LDADD", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddl", "LDADDL", 4, unsign=True, |
| flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldadda", "LDADDA", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddla", "LDADDLA", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldadd64", "LDADD64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddl64", "LDADDL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldadda64", "LDADDA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("ldaddla64", "LDADDLA64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['ADD']) |
| |
| AtomicArithmeticSingleOp("ldclrb", "LDCLRB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrlb", "LDCLRLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrab", "LDCLRAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrlab", "LDCLRLAB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrh", "LDCLRH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrlh", "LDCLRLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrah", "LDCLRAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrlah", "LDCLRLAH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclr", "LDCLR", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrl", "LDCLRL", 4, unsign=True, |
| flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclra", "LDCLRA", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrla", "LDCLRLA", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclr64", "LDCLR64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrl64", "LDCLRL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclra64", "LDCLRA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("ldclrla64", "LDCLRLA64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['CLR']) |
| |
| AtomicArithmeticSingleOp("ldeorb", "LDEORB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorlb", "LDEORLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorab", "LDEORAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorlab", "LDEORLAB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorh", "LDEORH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorlh", "LDEORLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorah", "LDEORAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorlah", "LDEORLAH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeor", "LDEOR", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorl", "LDEORL", 4, unsign=True, |
| flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeora", "LDEORA", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorla", "LDEORLA", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeor64", "LDEOR64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorl64", "LDEORL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeora64", "LDEORA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("ldeorla64", "LDEORLA64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['EOR']) |
| |
| AtomicArithmeticSingleOp("ldsetb", "LDSETB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetlb", "LDSETLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetab", "LDSETAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetlab", "LDSETLAB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldseth", "LDSETH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetlh", "LDSETLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetah", "LDSETAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetlah", "LDSETLAH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldset", "LDSET", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetl", "LDSETL", 4, unsign=True, |
| flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldseta", "LDSETA", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetla", "LDSETLA", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldset64", "LDSET64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetl64", "LDSETL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldseta64", "LDSETA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("ldsetla64", "LDSETLA64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['SET']) |
| |
| AtomicArithmeticSingleOp("ldsmaxb", "LDSMAXB", 1, unsign=False, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxlb", "LDSMAXLB", 1, unsign=False, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxab", "LDSMAXAB", 1, unsign=False, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxlab", "LDSMAXLAB", 1, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxh", "LDSMAXH", 2, unsign=False, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxlh", "LDSMAXLH", 2, unsign=False, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxah", "LDSMAXAH", 2, unsign=False, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxlah", "LDSMAXLAH", 2, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmax", "LDSMAX", 4, unsign=False, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxl", "LDSMAXL", 4, unsign=False, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxa", "LDSMAXA", 4, unsign=False, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxla", "LDSMAXLA", 4, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmax64", "LDSMAX64", 8, unsign=False, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxl64", "LDSMAXL64", 8, unsign=False, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxa64", "LDSMAXA64", 8, unsign=False, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldsmaxla64", "LDSMAXLA64", 8, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| |
| AtomicArithmeticSingleOp("ldsminb", "LDSMINB", 1, unsign=False, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminlb", "LDSMINLB", 1, unsign=False, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminab", "LDSMINAB", 1, unsign=False, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminlab", "LDSMINLAB", 1, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminh", "LDSMINH", 2, unsign=False, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminlh", "LDSMINLH", 2, unsign=False, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminah", "LDSMINAH", 2, unsign=False, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminlah", "LDSMINLAH", 2, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsmin", "LDSMIN", 4, unsign=False, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminl", "LDSMINL", 4, unsign=False, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsmina", "LDSMINA", 4, unsign=False, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminla", "LDSMINLA", 4, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsmin64", "LDSMIN64", 8, unsign=False, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminl64", "LDSMINL64", 8, unsign=False, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsmina64", "LDSMINA64", 8, unsign=False, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldsminla64", "LDSMINLA64", 8, unsign=False, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| |
| AtomicArithmeticSingleOp("ldumaxb", "LDUMAXB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxlb", "LDUMAXLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxab", "LDUMAXAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxlab", "LDUMAXLAB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxh", "LDUMAXH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxlh", "LDUMAXLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxah", "LDUMAXAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxlah", "LDUMAXLAH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumax", "LDUMAX", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxl", "LDUMAXL", 4, unsign=True, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxa", "LDUMAXA", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxla", "LDUMAXLA", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumax64", "LDUMAX64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxl64", "LDUMAXL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxa64", "LDUMAXA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("ldumaxla64", "LDUMAXLA64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MAX']) |
| |
| |
| AtomicArithmeticSingleOp("lduminb", "LDUMINB", 1, unsign=True, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminlb", "LDUMINLB", 1, unsign=True, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminab", "LDUMINAB", 1, unsign=True, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminlab", "LDUMINLAB", 1, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminh", "LDUMINH", 2, unsign=True, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminlh", "LDUMINLH", 2, unsign=True, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminah", "LDUMINAH", 2, unsign=True, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminlah", "LDUMINLAH", 2, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldumin", "LDUMIN", 4, unsign=True, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminl", "LDUMINL", 4, unsign=True, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldumina", "LDUMINA", 4, unsign=True, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminla", "LDUMINLA", 4, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldumin64", "LDUMIN64", 8, unsign=True, |
| flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminl64", "LDUMINL64", 8, unsign=True, |
| flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("ldumina64", "LDUMINA64", 8, unsign=True, |
| flavor="acquire").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("lduminla64", "LDUMINLA64", 8, unsign=True, |
| flavor="acquire_release").emit(OP_DICT['MIN']) |
| |
| AtomicArithmeticSingleOp("staddb", "STADDB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("staddlb", "STADDLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("staddh", "STADDH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("staddlh", "STADDLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("stadd", "STADD", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("staddl", "STADDL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("stadd64", "STADD64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['ADD']) |
| AtomicArithmeticSingleOp("staddl64", "STADDL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['ADD']) |
| |
| AtomicArithmeticSingleOp("stclrb", "STCLRB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclrlb", "STCLRLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclrh", "STCLRH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclrlh", "STCLRLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclr", "STCLR", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclrl", "STCLRL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclr64", "STCLR64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['CLR']) |
| AtomicArithmeticSingleOp("stclrl64", "STCLRL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['CLR']) |
| |
| AtomicArithmeticSingleOp("steorb", "STEORB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steorlb", "STEORLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steorh", "STEORH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steorlh", "STEORLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steor", "STEOR", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steorl", "STEORL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steor64", "STEOR64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['EOR']) |
| AtomicArithmeticSingleOp("steorl64", "STEORL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['EOR']) |
| |
| AtomicArithmeticSingleOp("stsetb", "STSETB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stsetlb", "STSETLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stsetab", "STSETAB", 1, unsign=True, |
| ret_op=False, flavor="acquire").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stsetlab", "STSETLAB", 1, unsign=True, |
| ret_op=False, flavor="acquire_release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stseth", "STSETH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stsetlh", "STSETLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stset", "STSET", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stsetl", "STSETL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stset64", "STSET64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SET']) |
| AtomicArithmeticSingleOp("stsetl64", "STSETL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SET']) |
| |
| AtomicArithmeticSingleOp("stsmaxb", "STSMAXB", 1, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmaxlb", "STSMAXLB", 1, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmaxh", "STSMAXH", 2, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmaxlh", "STSMAXLH", 2, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmax", "STSMAX", 4, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmaxl", "STSMAXL", 4, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmax64", "STSMAX64", 8, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stsmaxl64", "STSMAXL64", 8, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| |
| AtomicArithmeticSingleOp("stsminb", "STSMINB", 1, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsminlb", "STSMINLB", 1, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsminh", "STSMINH", 2, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsminlh", "STSMINLH", 2, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsmin", "STSMIN", 4, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsminl", "STSMINL", 4, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsmin64", "STSMIN64", 8, unsign=False, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stsminl64", "STSMINL64", 8, unsign=False, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| |
| AtomicArithmeticSingleOp("stumaxb", "STUMAXB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumaxlb", "STUMAXLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumaxh", "STUMAXH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumaxlh", "STUMAXLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumax", "STUMAX", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumaxl", "STUMAXL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumax64", "STUMAX64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MAX']) |
| AtomicArithmeticSingleOp("stumaxl64", "STUMAXL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MAX']) |
| |
| AtomicArithmeticSingleOp("stuminb", "STUMINB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stuminlb", "STUMINLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stuminh", "STUMINH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stuminlh", "STUMINLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stumin", "STUMIN", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stuminl", "STUMINL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stumin64", "STUMIN64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['MIN']) |
| AtomicArithmeticSingleOp("stuminl64", "STUMINL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['MIN']) |
| |
| AtomicArithmeticSingleOp("swpb", "SWPB", 1, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swplb", "SWPLB", 1, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpab", "SWPAB", 1, unsign=True, |
| ret_op=False, flavor="acquire").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swplab", "SWPLAB", 1, unsign=True, |
| ret_op=False, flavor="acquire_release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swph", "SWPH", 2, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swplh", "SWPLH", 2, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpah", "SWPAH", 2, unsign=True, |
| ret_op=False, flavor="acquire").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swplah", "SWPLAH", 2, unsign=True, |
| ret_op=False, flavor="acquire_release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swp", "SWP", 4, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpl", "SWPL", 4, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpa", "SWPA", 4, unsign=True, |
| ret_op=False, flavor="acquire").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpla", "SWPLA", 4, unsign=True, |
| ret_op=False, flavor="acquire_release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swp64", "SWP64", 8, unsign=True, |
| ret_op=False, flavor="normal").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpl64", "SWPL64", 8, unsign=True, |
| ret_op=False, flavor="release").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpa64", "SWPA64", 8, unsign=True, |
| ret_op=False, flavor="acquire").emit(OP_DICT['SWP']) |
| AtomicArithmeticSingleOp("swpla64", "SWPLA64", 8, unsign=True, |
| ret_op=False, flavor="acquire_release").emit(OP_DICT['SWP']) |
| }}; |
