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// -*- mode:c++ -*-
let {{
def LoadStoreBase(name, Name, ea_code, memacc_code, mem_flags, inst_flags,
postacc_code = '', base_class = 'Memory',
decode_template = BasicDecode, exec_template_base = ''):
# Make sure flags are in lists (convert to lists if not).
mem_flags = makeList(mem_flags)
inst_flags = makeList(inst_flags)
# add hook to get effective addresses into execution trace output.
ea_code += '\nif (traceData) { traceData->setAddr(EA); }\n'
# generate code block objects
ea_cblk = CodeBlock(ea_code)
memacc_cblk = CodeBlock(memacc_code)
postacc_cblk = CodeBlock(postacc_code)
# Some CPU models execute the memory operation as an atomic unit,
# while others want to separate them into an effective address
# computation and a memory access operation. As a result, we need
# to generate three StaticInst objects. Note that the latter two
# are nested inside the larger "atomic" one.
# generate InstObjParams for EAComp object
ea_iop = InstObjParams(name, Name, base_class, ea_cblk, inst_flags)
# generate InstObjParams for MemAcc object
memacc_iop = InstObjParams(name, Name, base_class, memacc_cblk, inst_flags)
# in the split execution model, the MemAcc portion is responsible
# for the post-access code.
memacc_iop.postacc_code = postacc_cblk.code
# generate InstObjParams for InitiateAcc, CompleteAcc object
# The code used depends on the template being used
if (exec_template_base == 'Load'):
initiateacc_cblk = CodeBlock(ea_code + memacc_code)
completeacc_cblk = CodeBlock(memacc_code + postacc_code)
elif (exec_template_base == 'Store'):
initiateacc_cblk = CodeBlock(ea_code + memacc_code)
completeacc_cblk = CodeBlock(postacc_code)
else:
initiateacc_cblk = ''
completeacc_cblk = ''
initiateacc_iop = InstObjParams(name, Name, base_class, initiateacc_cblk,
inst_flags)
completeacc_iop = InstObjParams(name, Name, base_class, completeacc_cblk,
inst_flags)
if (exec_template_base == 'Load'):
initiateacc_iop.ea_code = ea_cblk.code
initiateacc_iop.memacc_code = memacc_cblk.code
completeacc_iop.memacc_code = memacc_cblk.code
completeacc_iop.postacc_code = postacc_cblk.code
elif (exec_template_base == 'Store'):
initiateacc_iop.ea_code = ea_cblk.code
initiateacc_iop.memacc_code = memacc_cblk.code
completeacc_iop.postacc_code = postacc_cblk.code
# generate InstObjParams for unified execution
cblk = CodeBlock(ea_code + memacc_code + postacc_code)
iop = InstObjParams(name, Name, base_class, cblk, inst_flags)
iop.ea_constructor = ea_cblk.constructor
iop.ea_code = ea_cblk.code
iop.memacc_constructor = memacc_cblk.constructor
iop.memacc_code = memacc_cblk.code
iop.postacc_code = postacc_cblk.code
if mem_flags:
s = '\n\tmemAccessFlags = ' + string.join(mem_flags, '|') + ';'
iop.constructor += s
memacc_iop.constructor += s
# select templates
memAccExecTemplate = eval(exec_template_base + 'MemAccExecute')
fullExecTemplate = eval(exec_template_base + 'Execute')
initiateAccTemplate = eval(exec_template_base + 'InitiateAcc')
completeAccTemplate = eval(exec_template_base + 'CompleteAcc')
# (header_output, decoder_output, decode_block, exec_output)
return (LoadStoreDeclare.subst(iop), LoadStoreConstructor.subst(iop),
decode_template.subst(iop),
EACompExecute.subst(ea_iop)
+ memAccExecTemplate.subst(memacc_iop)
+ fullExecTemplate.subst(iop)
+ initiateAccTemplate.subst(initiateacc_iop)
+ completeAccTemplate.subst(completeacc_iop))
}};
output exec {{
using namespace MipsISA;
/// CLEAR ALL CPU INST/EXE HAZARDS
inline void
clear_exe_inst_hazards()
{
//CODE HERE
}
/// Check "FP enabled" machine status bit. Called when executing any FP
/// instruction in full-system mode.
/// @retval Full-system mode: NoFault if FP is enabled, FenFault
/// if not. Non-full-system mode: always returns NoFault.
#if FULL_SYSTEM
inline Fault checkFpEnableFault(%(CPU_exec_context)s *xc)
{
Fault fault = NoFault; // dummy... this ipr access should not fault
if (!Mips34k::ICSR_FPE(xc->readIpr(MipsISA::IPR_ICSR, fault))) {
fault = FloatEnableFault;
}
return fault;
}
#else
inline Fault checkFpEnableFault(%(CPU_exec_context)s *xc)
{
return NoFault;
}
#endif
}};
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