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// Copyright (c) 2006-2007 The Regents of The University of Michigan
// All rights reserved.
//
// 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: Ali Saidi
// Gabe Black
// Steve Reinhardt
////////////////////////////////////////////////////////////////////
//
// Mem utility templates and functions
//
output header {{
/**
* Base class for memory operations.
*/
class Mem : public SparcStaticInst
{
protected:
// Constructor
Mem(const char *mnem, ExtMachInst _machInst, OpClass __opClass) :
SparcStaticInst(mnem, _machInst, __opClass)
{
}
std::string generateDisassembly(Addr pc,
const SymbolTable *symtab) const;
};
/**
* Class for memory operations which use an immediate offset.
*/
class MemImm : public Mem
{
protected:
// Constructor
MemImm(const char *mnem, ExtMachInst _machInst, OpClass __opClass) :
Mem(mnem, _machInst, __opClass), imm(sext<13>(SIMM13))
{}
std::string generateDisassembly(Addr pc,
const SymbolTable *symtab) const;
const int32_t imm;
};
}};
output decoder {{
std::string Mem::generateDisassembly(Addr pc,
const SymbolTable *symtab) const
{
std::stringstream response;
bool load = flags[IsLoad];
bool store = flags[IsStore];
printMnemonic(response, mnemonic);
if (store) {
printReg(response, _srcRegIdx[0]);
ccprintf(response, ", ");
}
ccprintf(response, "[");
if (_srcRegIdx[!store ? 0 : 1] != 0) {
printSrcReg(response, !store ? 0 : 1);
ccprintf(response, " + ");
}
printSrcReg(response, !store ? 1 : 2);
ccprintf(response, "]");
if (load) {
ccprintf(response, ", ");
printReg(response, _destRegIdx[0]);
}
return response.str();
}
std::string MemImm::generateDisassembly(Addr pc,
const SymbolTable *symtab) const
{
std::stringstream response;
bool load = flags[IsLoad];
bool save = flags[IsStore];
printMnemonic(response, mnemonic);
if (save) {
printReg(response, _srcRegIdx[0]);
ccprintf(response, ", ");
}
ccprintf(response, "[");
if (_srcRegIdx[!save ? 0 : 1] != 0) {
printReg(response, _srcRegIdx[!save ? 0 : 1]);
ccprintf(response, " + ");
}
if (imm >= 0)
ccprintf(response, "0x%x]", imm);
else
ccprintf(response, "-0x%x]", -imm);
if (load) {
ccprintf(response, ", ");
printReg(response, _destRegIdx[0]);
}
return response.str();
}
}};
// This template provides the execute functions for a load
def template LoadExecute {{
Fault %(class_name)s::execute(%(CPU_exec_context)s *xc,
Trace::InstRecord *traceData) const
{
Fault fault = NoFault;
Addr EA;
%(fp_enable_check)s;
%(op_decl)s;
%(op_rd)s;
%(ea_code)s;
DPRINTF(Sparc, "%s: The address is 0x%x\n", mnemonic, EA);
%(fault_check)s;
if (fault == NoFault) {
%(EA_trunc)s
fault = readMemAtomic(xc, traceData, EA, Mem, %(asi_val)s);
}
if (fault == NoFault) {
%(code)s;
}
if (fault == NoFault) {
// Write the resulting state to the execution context
%(op_wb)s;
}
return fault;
}
}};
def template LoadInitiateAcc {{
Fault %(class_name)s::initiateAcc(%(CPU_exec_context)s * xc,
Trace::InstRecord * traceData) const
{
Fault fault = NoFault;
Addr EA;
%(fp_enable_check)s;
%(op_decl)s;
%(op_rd)s;
%(ea_code)s;
DPRINTF(Sparc, "%s: The address is 0x%x\n", mnemonic, EA);
%(fault_check)s;
if (fault == NoFault) {
%(EA_trunc)s
fault = readMemTiming(xc, traceData, EA, Mem, %(asi_val)s);
}
return fault;
}
}};
def template LoadCompleteAcc {{
Fault %(class_name)s::completeAcc(PacketPtr pkt, %(CPU_exec_context)s * xc,
Trace::InstRecord * traceData) const
{
Fault fault = NoFault;
%(op_decl)s;
%(op_rd)s;
getMem(pkt, Mem, traceData);
%(code)s;
if (fault == NoFault) {
%(op_wb)s;
}
return fault;
}
}};
// This template provides the execute functions for a store
def template StoreExecute {{
Fault %(class_name)s::execute(%(CPU_exec_context)s *xc,
Trace::InstRecord *traceData) const
{
Fault fault = NoFault;
// This is to support the conditional store in cas instructions.
// It should be optomized out in all the others
bool storeCond = true;
Addr EA;
%(fp_enable_check)s;
%(op_decl)s;
%(op_rd)s;
%(ea_code)s;
DPRINTF(Sparc, "%s: The address is 0x%x\n", mnemonic, EA);
%(fault_check)s;
if (fault == NoFault) {
%(code)s;
}
if (storeCond && fault == NoFault) {
%(EA_trunc)s
fault = writeMemAtomic(xc, traceData, Mem, EA, %(asi_val)s, 0);
}
if (fault == NoFault) {
// Write the resulting state to the execution context
%(op_wb)s;
}
return fault;
}
}};
def template StoreInitiateAcc {{
Fault %(class_name)s::initiateAcc(%(CPU_exec_context)s * xc,
Trace::InstRecord * traceData) const
{
Fault fault = NoFault;
bool storeCond = true;
Addr EA;
%(fp_enable_check)s;
%(op_decl)s;
%(op_rd)s;
%(ea_code)s;
DPRINTF(Sparc, "%s: The address is 0x%x\n", mnemonic, EA);
%(fault_check)s;
if (fault == NoFault) {
%(code)s;
}
if (storeCond && fault == NoFault) {
%(EA_trunc)s
fault = writeMemTiming(xc, traceData, Mem, EA, %(asi_val)s, 0);
}
return fault;
}
}};
def template StoreCompleteAcc {{
Fault %(class_name)s::completeAcc(PacketPtr, %(CPU_exec_context)s * xc,
Trace::InstRecord * traceData) const
{
return NoFault;
}
}};
def template EACompExecute {{
Fault
%(class_name)s::eaComp(%(CPU_exec_context)s *xc,
Trace::InstRecord *traceData) const
{
Addr EA;
Fault fault = NoFault;
%(op_decl)s;
%(op_rd)s;
%(ea_code)s;
%(fault_check)s;
// NOTE: Trace Data is written using execute or completeAcc templates
if (fault == NoFault) {
%(EA_trunc)s
xc->setEA(EA);
}
return fault;
}
}};
def template EACompDeclare {{
Fault eaComp(%(CPU_exec_context)s *, Trace::InstRecord *) const;
}};
// This delcares the initiateAcc function in memory operations
def template InitiateAccDeclare {{
Fault initiateAcc(%(CPU_exec_context)s *, Trace::InstRecord *) const;
}};
// This declares the completeAcc function in memory operations
def template CompleteAccDeclare {{
Fault completeAcc(PacketPtr, %(CPU_exec_context)s *, Trace::InstRecord *) const;
}};
// Here are some code snippets which check for various fault conditions
let {{
LoadFuncs = [LoadExecute, LoadInitiateAcc, LoadCompleteAcc]
StoreFuncs = [StoreExecute, StoreInitiateAcc, StoreCompleteAcc]
# The LSB can be zero, since it's really the MSB in doubles and quads
# and we're dealing with doubles
BlockAlignmentFaultCheck = '''
if (RD & 0xe)
fault = new IllegalInstruction;
else if (EA & 0x3f)
fault = new MemAddressNotAligned;
'''
TwinAlignmentFaultCheck = '''
if (RD & 0x1)
fault = new IllegalInstruction;
else if (EA & 0xf)
fault = new MemAddressNotAligned;
'''
# XXX Need to take care of pstate.hpriv as well. The lower ASIs
# are split into ones that are available in priv and hpriv, and
# those that are only available in hpriv
AlternateASIPrivFaultCheck = '''
if ((!Pstate.priv && !Hpstate.hpriv &&
!asiIsUnPriv((ASI)EXT_ASI)) ||
(!Hpstate.hpriv && asiIsHPriv((ASI)EXT_ASI)))
fault = new PrivilegedAction;
else if (asiIsAsIfUser((ASI)EXT_ASI) && !Pstate.priv)
fault = new PrivilegedAction;
'''
TruncateEA = '''
if (!FullSystem)
EA = Pstate.am ? EA<31:0> : EA;
'''
}};
// A simple function to generate the name of the macro op of a certain
// instruction at a certain micropc
let {{
def makeMicroName(name, microPc):
return name + "::" + name + "_" + str(microPc)
}};
// This function properly generates the execute functions for one of the
// templates above. This is needed because in one case, ea computation,
// fault checks and the actual code all occur in the same function,
// and in the other they're distributed across two. Also note that for
// execute functions, the name of the base class doesn't matter.
let {{
def doSplitExecute(execute, name, Name, asi, opt_flags, microParam):
microParam["asi_val"] = asi;
iop = InstObjParams(name, Name, '', microParam, opt_flags)
(execf, initf, compf) = execute
return execf.subst(iop) + initf.subst(iop) + compf.subst(iop)
def doDualSplitExecute(code, postacc_code, eaRegCode, eaImmCode, execute,
faultCode, nameReg, nameImm, NameReg, NameImm, asi, opt_flags):
executeCode = ''
for (eaCode, name, Name) in (
(eaRegCode, nameReg, NameReg),
(eaImmCode, nameImm, NameImm)):
microParams = {"code": code, "postacc_code" : postacc_code,
"ea_code": eaCode, "fault_check": faultCode,
"EA_trunc" : TruncateEA}
executeCode += doSplitExecute(execute, name, Name,
asi, opt_flags, microParams)
return executeCode
}};
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