// -*- mode:c++ -*-
// Copyright (c) 2010 ARM Limited
// 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: Gabe Black
let {{
header_output = ""
decoder_output = ""
exec_output = ""
class LoadInst(LoadStoreInst):
execBase = 'Load'
def __init__(self, mnem, post, add, writeback,
size=4, sign=False, user=False, flavor="normal"):
super(LoadInst, self).__init__()
self.name = mnem
self.post = post
self.add = add
self.writeback = writeback
self.size = size
self.sign = sign
self.user = user
self.flavor = flavor
self.rasPop = False
if self.add:
self.op = " +"
else:
self.op = " -"
self.memFlags = ["ArmISA::TLB::MustBeOne"]
self.codeBlobs = {"postacc_code" : ""}
def emitHelper(self, base = 'Memory', wbDecl = None, instFlags = [], pcDecl = None):
global header_output, decoder_output, exec_output
codeBlobs = self.codeBlobs
codeBlobs["predicate_test"] = pickPredicate(codeBlobs)
(newHeader,
newDecoder,
newExec) = self.fillTemplates(self.name, self.Name, codeBlobs,
self.memFlags, instFlags, base,
wbDecl, pcDecl, self.rasPop)
header_output += newHeader
decoder_output += newDecoder
exec_output += newExec
class RfeInst(LoadInst):
decConstBase = 'Rfe'
def __init__(self, mnem, post, add, writeback):
super(RfeInst, self).__init__(mnem, post, add, writeback)
self.Name = "RFE_" + loadImmClassName(post, add, writeback, 8)
self.memFlags.append("ArmISA::TLB::AlignWord")
def emit(self):
offset = 0
if self.post != self.add:
offset += 4
if not self.add:
offset -= 8
self.codeBlobs["ea_code"] = "EA = Base + %d;" % offset
wbDiff = -8
if self.add:
wbDiff = 8
accCode = '''
CPSR cpsr = Cpsr;
cpsr.nz = CondCodesNZ;
cpsr.c = CondCodesC;
cpsr.v = CondCodesV;
cpsr.ge = CondCodesGE;
URc = cpsr;
URa = cSwap<uint32_t>(Mem_ud, cpsr.e);
URb = cSwap<uint32_t>(Mem_ud >> 32, cpsr.e);
'''
self.codeBlobs["memacc_code"] = accCode
wbDecl = None
pcDecl = "MicroUopSetPCCPSR(machInst, INTREG_UREG0, INTREG_UREG1, INTREG_UREG2);"
if self.writeback:
wbDecl = "MicroAddiUop(machInst, base, base, %d);" % wbDiff
self.emitHelper('RfeOp', wbDecl, ["IsSerializeAfter", "IsNonSpeculative"], pcDecl)
class LoadImmInst(LoadInst):
def __init__(self, *args, **kargs):
super(LoadImmInst, self).__init__(*args, **kargs)
self.offset = self.op + " imm"
if self.add:
self.wbDecl = "MicroAddiUop(machInst, base, base, imm);"
else:
self.wbDecl = "MicroSubiUop(machInst, base, base, imm);"
if self.add and self.post and self.writeback and not self.sign and \
not self.user and self.size == 4:
self.rasPop = True
class LoadRegInst(LoadInst):
def __init__(self, *args, **kargs):
super(LoadRegInst, self).__init__(*args, **kargs)
self.offset = self.op + " shift_rm_imm(Index, shiftAmt," + \
" shiftType, OptShiftRmCondCodesC)"
if self.add:
self.wbDecl = '''
MicroAddUop(machInst, base, base, wbIndexReg, shiftAmt, shiftType);
'''
else:
self.wbDecl = '''
MicroSubUop(machInst, base, base, wbIndexReg, shiftAmt, shiftType);
'''
class LoadSingle(LoadInst):
def __init__(self, *args, **kargs):
super(LoadSingle, self).__init__(*args, **kargs)
# Build the default class name
self.Name = self.nameFunc(self.post, self.add, self.writeback,
self.size, self.sign, self.user)
# Add memory request flags where necessary
self.memFlags.append("%d" % (self.size - 1))
if self.user:
self.memFlags.append("ArmISA::TLB::UserMode")
self.instFlags = []
if self.flavor == "dprefetch":
self.memFlags.append("Request::PREFETCH")
self.instFlags = ['IsDataPrefetch']
elif self.flavor == "iprefetch":
self.memFlags.append("Request::PREFETCH")
self.instFlags = ['IsInstPrefetch']
elif self.flavor == "exclusive":
self.memFlags.append("Request::LLSC")
elif self.flavor == "normal":
self.memFlags.append("ArmISA::TLB::AllowUnaligned")
# Disambiguate the class name for different flavors of loads
if self.flavor != "normal":
self.Name = "%s_%s" % (self.name.upper(), self.Name)
def emit(self):
# Address compuation code
eaCode = "EA = Base"
if not self.post:
eaCode += self.offset
eaCode += ";"
if self.flavor == "fp":
eaCode += vfpEnabledCheckCode
self.codeBlobs["ea_code"] = eaCode
# Code that actually handles the access
if self.flavor == "dprefetch" or self.flavor == "iprefetch":
accCode = 'uint64_t temp = Mem%s; temp = temp;'
elif self.flavor == "fp":
accCode = "FpDest_uw = cSwap(Mem%s, ((CPSR)Cpsr).e);\n"
else:
accCode = "IWDest = cSwap(Mem%s, ((CPSR)Cpsr).e);"
accCode = accCode % buildMemSuffix(self.sign, self.size)
self.codeBlobs["memacc_code"] = accCode
# Push it out to the output files
base = buildMemBase(self.basePrefix, self.post, self.writeback)
wbDecl = None
if self.writeback:
wbDecl = self.wbDecl
self.emitHelper(base, wbDecl, self.instFlags)
def loadImmClassName(post, add, writeback, size=4, sign=False, user=False):
return memClassName("LOAD_IMM", post, add, writeback, size, sign, user)
class LoadImm(LoadImmInst, LoadSingle):
decConstBase = 'LoadImm'
basePrefix = 'MemoryImm'
nameFunc = staticmethod(loadImmClassName)
def loadRegClassName(post, add, writeback, size=4, sign=False, user=False):
return memClassName("LOAD_REG", post, add, writeback, size, sign, user)
class LoadReg(LoadRegInst, LoadSingle):
decConstBase = 'LoadReg'
basePrefix = 'MemoryReg'
nameFunc = staticmethod(loadRegClassName)
class LoadDouble(LoadInst):
def __init__(self, *args, **kargs):
super(LoadDouble, self).__init__(*args, **kargs)
# Build the default class name
self.Name = self.nameFunc(self.post, self.add, self.writeback)
# Add memory request flags where necessary
if self.flavor == "exclusive":
self.memFlags.append("Request::LLSC")
self.memFlags.append("ArmISA::TLB::AlignDoubleWord")
else:
self.memFlags.append("ArmISA::TLB::AlignWord")
# Disambiguate the class name for different flavors of loads
if self.flavor != "normal":
self.Name = "%s_%s" % (self.name.upper(), self.Name)
def emit(self):
# Address computation code
eaCode = "EA = Base"
if not self.post:
eaCode += self.offset
eaCode += ";"
if self.flavor == "fp":
eaCode += vfpEnabledCheckCode
self.codeBlobs["ea_code"] = eaCode
# Code that actually handles the access
if self.flavor != "fp":
accCode = '''
CPSR cpsr = Cpsr;
Dest = cSwap<uint32_t>(Mem_ud, cpsr.e);
Dest2 = cSwap<uint32_t>(Mem_ud >> 32, cpsr.e);
'''
else:
accCode = '''
uint64_t swappedMem = cSwap(Mem_ud, ((CPSR)Cpsr).e);
FpDest_uw = (uint32_t)swappedMem;
FpDest2_uw = (uint32_t)(swappedMem >> 32);
'''
self.codeBlobs["memacc_code"] = accCode
# Push it out to the output files
base = buildMemBase(self.basePrefix, self.post, self.writeback)
wbDecl = None
if self.writeback:
wbDecl = self.wbDecl
self.emitHelper(base, wbDecl)
def loadDoubleImmClassName(post, add, writeback):
return memClassName("LOAD_IMMD", post, add, writeback, 4, False, False)
class LoadDoubleImm(LoadImmInst, LoadDouble):
decConstBase = 'LoadStoreDImm'
basePrefix = 'MemoryDImm'
nameFunc = staticmethod(loadDoubleImmClassName)
def loadDoubleRegClassName(post, add, writeback):
return memClassName("LOAD_REGD", post, add, writeback, 4, False, False)
class LoadDoubleReg(LoadRegInst, LoadDouble):
decConstBase = 'LoadDReg'
basePrefix = 'MemoryDReg'
nameFunc = staticmethod(loadDoubleRegClassName)
def buildLoads(mnem, size=4, sign=False, user=False):
LoadImm(mnem, True, True, True, size, sign, user).emit()
LoadReg(mnem, True, True, True, size, sign, user).emit()
LoadImm(mnem, True, False, True, size, sign, user).emit()
LoadReg(mnem, True, False, True, size, sign, user).emit()
LoadImm(mnem, False, True, True, size, sign, user).emit()
LoadReg(mnem, False, True, True, size, sign, user).emit()
LoadImm(mnem, False, False, True, size, sign, user).emit()
LoadReg(mnem, False, False, True, size, sign, user).emit()
LoadImm(mnem, False, True, False, size, sign, user).emit()
LoadReg(mnem, False, True, False, size, sign, user).emit()
LoadImm(mnem, False, False, False, size, sign, user).emit()
LoadReg(mnem, False, False, False, size, sign, user).emit()
def buildDoubleLoads(mnem):
LoadDoubleImm(mnem, True, True, True).emit()
LoadDoubleReg(mnem, True, True, True).emit()
LoadDoubleImm(mnem, True, False, True).emit()
LoadDoubleReg(mnem, True, False, True).emit()
LoadDoubleImm(mnem, False, True, True).emit()
LoadDoubleReg(mnem, False, True, True).emit()
LoadDoubleImm(mnem, False, False, True).emit()
LoadDoubleReg(mnem, False, False, True).emit()
LoadDoubleImm(mnem, False, True, False).emit()
LoadDoubleReg(mnem, False, True, False).emit()
LoadDoubleImm(mnem, False, False, False).emit()
LoadDoubleReg(mnem, False, False, False).emit()
def buildRfeLoads(mnem):
RfeInst(mnem, True, True, True).emit()
RfeInst(mnem, True, True, False).emit()
RfeInst(mnem, True, False, True).emit()
RfeInst(mnem, True, False, False).emit()
RfeInst(mnem, False, True, True).emit()
RfeInst(mnem, False, True, False).emit()
RfeInst(mnem, False, False, True).emit()
RfeInst(mnem, False, False, False).emit()
def buildPrefetches(mnem, type):
LoadReg(mnem, False, False, False, size=1, flavor=type).emit()
LoadImm(mnem, False, False, False, size=1, flavor=type).emit()
LoadReg(mnem, False, True, False, size=1, flavor=type).emit()
LoadImm(mnem, False, True, False, size=1, flavor=type).emit()
buildLoads("ldr")
buildLoads("ldrt", user=True)
buildLoads("ldrb", size=1)
buildLoads("ldrbt", size=1, user=True)
buildLoads("ldrsb", size=1, sign=True)
buildLoads("ldrsbt", size=1, sign=True, user=True)
buildLoads("ldrh", size=2)
buildLoads("ldrht", size=2, user=True)
buildLoads("hdrsh", size=2, sign=True)
buildLoads("ldrsht", size=2, sign=True, user=True)
buildDoubleLoads("ldrd")
buildRfeLoads("rfe")
buildPrefetches("pld", "dprefetch")
buildPrefetches("pldw", "dprefetch")
buildPrefetches("pli", "iprefetch")
LoadImm("ldrex", False, True, False, size=4, flavor="exclusive").emit()
LoadImm("ldrexh", False, True, False, size=2, flavor="exclusive").emit()
LoadImm("ldrexb", False, True, False, size=1, flavor="exclusive").emit()
LoadDoubleImm("ldrexd", False, True, False, flavor="exclusive").emit()
LoadImm("vldr", False, True, False, size=4, flavor="fp").emit()
LoadImm("vldr", False, False, False, size=4, flavor="fp").emit()
LoadDoubleImm("vldr", False, True, False, flavor="fp").emit()
LoadDoubleImm("vldr", False, False, False, flavor="fp").emit()
}};