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// -*- mode:c++ -*-
// Copyright N) 2007 MIPS Technologies, Inc. All Rights Reserved
// This software is part of the M5 simulator.
// THIS IS A LEGAL AGREEMENT. BY DOWNLOADING, USING, COPYING, CREATING
// DERIVATIVE WORKS, AND/OR DISTRIBUTING THIS SOFTWARE YOU ARE AGREEING
// TO THESE TERMS AND CONDITIONS.
// Permission is granted to use, copy, create derivative works and
// distribute this software and such derivative works for any purpose,
// so long as (1) the copyright notice above, this grant of permission,
// and the disclaimer below appear in all copies and derivative works
// made, (2) the copyright notice above is augmented as appropriate to
// reflect the addition of any new copyrightable work in a derivative
// work (e.g., Copyright N) <Publication Year> Copyright Owner), and (3)
// the name of MIPS Technologies, Inc. ($(B!H(BMIPS$(B!I(B) is not used in any
// advertising or publicity pertaining to the use or distribution of
// this software without specific, written prior authorization.
// THIS SOFTWARE IS PROVIDED $(B!H(BAS IS.$(B!I(B MIPS MAKES NO WARRANTIES AND
// DISCLAIMS ALL WARRANTIES, WHETHER EXPRESS, STATUTORY, IMPLIED OR
// OTHERWISE, INCLUDING BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, AND
// NON-INFRINGEMENT OF THIRD PARTY RIGHTS, REGARDING THIS SOFTWARE.
// IN NO EVENT SHALL MIPS BE LIABLE FOR ANY DAMAGES, INCLUDING DIRECT,
// INDIRECT, INCIDENTAL, CONSEQUENTIAL, SPECIAL, OR PUNITIVE DAMAGES OF
// ANY KIND OR NATURE, ARISING OUT OF OR IN CONNECTION WITH THIS AGREEMENT,
// THIS SOFTWARE AND/OR THE USE OF THIS SOFTWARE, WHETHER SUCH LIABILITY
// IS ASSERTED ON THE BASIS OF CONTRACT, TORT (INCLUDING NEGLIGENCE OR
// STRICT LIABILITY), OR OTHERWISE, EVEN IF MIPS HAS BEEN WARNED OF THE
// POSSIBILITY OF ANY SUCH LOSS OR DAMAGE IN ADVANCE.
//Authors: Korey L. Sewell
////////////////////////////////////////////////////////////////////
//
// Floating Point operate instructions
//
output header {{
/**
* Base class for FP operations.
*/
class FPOp : public MipsStaticInst
{
protected:
/// Constructor
FPOp(const char *mnem, MachInst _machInst, OpClass __opClass) : MipsStaticInst(mnem, _machInst, __opClass)
{
}
//std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
//needs function to check for fpEnable or not
};
class FPCompareOp : public FPOp
{
protected:
FPCompareOp(const char *mnem, MachInst _machInst, OpClass __opClass) : FPOp(mnem, _machInst, __opClass)
{
}
std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
};
}};
output decoder {{
std::string FPCompareOp::generateDisassembly(Addr pc, const SymbolTable *symtab) const
{
std::stringstream ss;
ccprintf(ss, "%-10s ", mnemonic);
ccprintf(ss,"%d",CC);
if(_numSrcRegs > 0) {
ss << ", ";
printReg(ss, _srcRegIdx[0]);
}
if(_numSrcRegs > 1) {
ss << ", ";
printReg(ss, _srcRegIdx[1]);
}
return ss.str();
}
}};
output exec {{
inline Fault checkFpEnableFault(%(CPU_exec_context)s *xc)
{
//@TODO: Implement correct CP0 checks to see if the CP1
// unit is enable or not
if (!isCoprocessorEnabled(xc, 1))
return new CoprocessorUnusableFault(1);
return NoFault;
}
//If any operand is Nan return the appropriate QNaN
template <class T>
bool
fpNanOperands(FPOp *inst, %(CPU_exec_context)s *xc, const T &src_type,
Trace::InstRecord *traceData)
{
uint64_t mips_nan = 0;
T src_op = 0;
int size = sizeof(src_op) * 8;
for (int i = 0; i < inst->numSrcRegs(); i++) {
uint64_t src_bits = xc->readFloatRegOperandBits(inst, 0, size);
if (isNan(&src_bits, size) ) {
if (isSnan(&src_bits, size)) {
switch (size)
{
case 32: mips_nan = MIPS32_QNAN; break;
case 64: mips_nan = MIPS64_QNAN; break;
default: panic("Unsupported Floating Point Size (%d)", size);
}
} else {
mips_nan = src_bits;
}
xc->setFloatRegOperandBits(inst, 0, mips_nan, size);
if (traceData) { traceData->setData(mips_nan); }
return true;
}
}
return false;
}
template <class T>
bool
fpInvalidOp(FPOp *inst, %(CPU_exec_context)s *cpu, const T dest_val,
Trace::InstRecord *traceData)
{
uint64_t mips_nan = 0;
T src_op = dest_val;
int size = sizeof(src_op) * 8;
if (isNan(&src_op, size)) {
switch (size)
{
case 32: mips_nan = MIPS32_QNAN; break;
case 64: mips_nan = MIPS64_QNAN; break;
default: panic("Unsupported Floating Point Size (%d)", size);
}
//Set value to QNAN
cpu->setFloatRegOperandBits(inst, 0, mips_nan, size);
//Read FCSR from FloatRegFile
uint32_t fcsr_bits = cpu->tcBase()->readFloatRegBits(FCSR);
uint32_t new_fcsr = genInvalidVector(fcsr_bits);
//Write FCSR from FloatRegFile
cpu->tcBase()->setFloatRegBits(FCSR, new_fcsr);
if (traceData) { traceData->setData(mips_nan); }
return true;
}
return false;
}
void
fpResetCauseBits(%(CPU_exec_context)s *cpu)
{
//Read FCSR from FloatRegFile
uint32_t fcsr = cpu->tcBase()->readFloatRegBits(FCSR);
// TODO: Use utility function here
fcsr = bits(fcsr, 31, 18) << 18 | bits(fcsr, 11, 0);
//Write FCSR from FloatRegFile
cpu->tcBase()->setFloatRegBits(FCSR, fcsr);
}
}};
def template FloatingPointExecute {{
Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
{
Fault fault = NoFault;
%(fp_enable_check)s;
//When is the right time to reset cause bits?
//start of every instruction or every cycle?
#if FULL_SYSTEM
fpResetCauseBits(xc);
#endif
%(op_decl)s;
%(op_rd)s;
//Check if any FP operand is a NaN value
if (!fpNanOperands((FPOp*)this, xc, Fd, traceData)) {
%(code)s;
//Change this code for Full-System/Sycall Emulation
//separation
//----
//Should Full System-Mode throw a fault here?
//----
//Check for IEEE 754 FP Exceptions
//fault = fpNanOperands((FPOp*)this, xc, Fd, traceData);
if (
#if FULL_SYSTEM
!fpInvalidOp((FPOp*)this, xc, Fd, traceData) &&
#endif
fault == NoFault)
{
%(op_wb)s;
}
}
return fault;
}
}};
// Primary format for float point operate instructions:
def format FloatOp(code, *flags) {{
iop = InstObjParams(name, Name, 'FPOp', code, flags)
header_output = BasicDeclare.subst(iop)
decoder_output = BasicConstructor.subst(iop)
decode_block = BasicDecode.subst(iop)
exec_output = FloatingPointExecute.subst(iop)
}};
def format FloatCompareOp(cond_code, *flags) {{
import sys
code = 'bool cond;\n'
if '.sf' in cond_code or 'SinglePrecision' in flags:
if 'QnanException' in flags:
code += 'if (isQnan(&Fs.sf, 32) || isQnan(&Ft.sf, 32)) {\n'
code += '\tFCSR = genInvalidVector(FCSR);\n'
code += '\treturn NoFault;'
code += '}\n else '
code += 'if (isNan(&Fs.sf, 32) || isNan(&Ft.sf, 32)) {\n'
elif '.df' in cond_code or 'DoublePrecision' in flags:
if 'QnanException' in flags:
code += 'if (isQnan(&Fs.df, 64) || isQnan(&Ft.df, 64)) {\n'
code += '\tFCSR = genInvalidVector(FCSR);\n'
code += '\treturn NoFault;'
code += '}\n else '
code += 'if (isNan(&Fs.df, 64) || isNan(&Ft.df, 64)) {\n'
else:
sys.exit('Decoder Failed: Can\'t Determine Operand Type\n')
if 'UnorderedTrue' in flags:
code += 'cond = 1;\n'
elif 'UnorderedFalse' in flags:
code += 'cond = 0;\n'
else:
sys.exit('Decoder Failed: Float Compare Instruction Needs A Unordered Flag\n')
code += '} else {\n'
code += cond_code + '}'
code += 'FCSR = genCCVector(FCSR, CC, cond);\n'
iop = InstObjParams(name, Name, 'FPCompareOp', code)
header_output = BasicDeclare.subst(iop)
decoder_output = BasicConstructor.subst(iop)
decode_block = BasicDecode.subst(iop)
exec_output = BasicExecute.subst(iop)
}};
def format FloatConvertOp(code, *flags) {{
import sys
#Determine Source Type
convert = 'fpConvert('
if '.sf' in code:
code = 'float ' + code + '\n'
convert += 'SINGLE_TO_'
elif '.df' in code:
code = 'double ' + code + '\n'
convert += 'DOUBLE_TO_'
elif '.uw' in code:
code = 'uint32_t ' + code + '\n'
convert += 'WORD_TO_'
elif '.ud' in code:
code = 'uint64_t ' + code + '\n'
convert += 'LONG_TO_'
else:
sys.exit("Error Determining Source Type for Conversion")
#Determine Destination Type
if 'ToSingle' in flags:
code += 'Fd.uw = ' + convert + 'SINGLE, '
elif 'ToDouble' in flags:
code += 'Fd.ud = ' + convert + 'DOUBLE, '
elif 'ToWord' in flags:
code += 'Fd.uw = ' + convert + 'WORD, '
elif 'ToLong' in flags:
code += 'Fd.ud = ' + convert + 'LONG, '
else:
sys.exit("Error Determining Destination Type for Conversion")
#Figure out how to round value
if 'Ceil' in flags:
code += 'ceil(val)); '
elif 'Floor' in flags:
code += 'floor(val)); '
elif 'Round' in flags:
code += 'roundFP(val, 0)); '
elif 'Trunc' in flags:
code += 'truncFP(val));'
else:
code += 'val); '
iop = InstObjParams(name, Name, 'FPOp', code)
header_output = BasicDeclare.subst(iop)
decoder_output = BasicConstructor.subst(iop)
decode_block = BasicDecode.subst(iop)
exec_output = BasicExecute.subst(iop)
}};
def format FloatAccOp(code, *flags) {{
iop = InstObjParams(name, Name, 'FPOp', code, flags)
header_output = BasicDeclare.subst(iop)
decoder_output = BasicConstructor.subst(iop)
decode_block = BasicDecode.subst(iop)
exec_output = BasicExecute.subst(iop)
}};
// Primary format for float64 operate instructions:
def format Float64Op(code, *flags) {{
iop = InstObjParams(name, Name, 'MipsStaticInst', code, flags)
header_output = BasicDeclare.subst(iop)
decoder_output = BasicConstructor.subst(iop)
decode_block = BasicDecode.subst(iop)
exec_output = BasicExecute.subst(iop)
}};
def format FloatPSCompareOp(cond_code1, cond_code2, *flags) {{
import sys
code = 'bool cond1, cond2;\n'
code += 'bool code_block1, code_block2;\n'
code += 'code_block1 = code_block2 = true;\n'
if 'QnanException' in flags:
code += 'if (isQnan(&Fs1.sf, 32) || isQnan(&Ft1.sf, 32)) {\n'
code += '\tFCSR = genInvalidVector(FCSR);\n'
code += 'code_block1 = false;'
code += '}\n'
code += 'if (isQnan(&Fs2.sf, 32) || isQnan(&Ft2.sf, 32)) {\n'
code += '\tFCSR = genInvalidVector(FCSR);\n'
code += 'code_block2 = false;'
code += '}\n'
code += 'if (code_block1) {'
code += '\tif (isNan(&Fs1.sf, 32) || isNan(&Ft1.sf, 32)) {\n'
if 'UnorderedTrue' in flags:
code += 'cond1 = 1;\n'
elif 'UnorderedFalse' in flags:
code += 'cond1 = 0;\n'
else:
sys.exit('Decoder Failed: Float Compare Instruction Needs A Unordered Flag\n')
code += '} else {\n'
code += cond_code1
code += 'FCSR = genCCVector(FCSR, CC, cond1);}\n}\n'
code += 'if (code_block2) {'
code += '\tif (isNan(&Fs2.sf, 32) || isNan(&Ft2.sf, 32)) {\n'
if 'UnorderedTrue' in flags:
code += 'cond2 = 1;\n'
elif 'UnorderedFalse' in flags:
code += 'cond2 = 0;\n'
else:
sys.exit('Decoder Failed: Float Compare Instruction Needs A Unordered Flag\n')
code += '} else {\n'
code += cond_code2
code += 'FCSR = genCCVector(FCSR, CC, cond2);}\n}'
iop = InstObjParams(name, Name, 'FPCompareOp', code)
header_output = BasicDeclare.subst(iop)
decoder_output = BasicConstructor.subst(iop)
decode_block = BasicDecode.subst(iop)
exec_output = BasicExecute.subst(iop)
}};
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