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|
// Copyright (c) 2007 The Hewlett-Packard Development Company
// Copyright (c) 2012-2013 Mark D. Hill and David A. Wood
// 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
// Nilay Vaish
//////////////////////////////////////////////////////////////////////////
//
// FpOp Microop templates
//
//////////////////////////////////////////////////////////////////////////
def template MicroFpOpExecute {{
Fault %(class_name)s::execute(%(CPU_exec_context)s *xc,
Trace::InstRecord *traceData) const
{
Fault fault = NoFault;
DPRINTF(X86, "The data size is %d\n", dataSize);
%(op_decl)s;
%(op_rd)s;
if(%(cond_check)s)
{
%(code)s;
%(flag_code)s;
%(tag_code)s;
%(top_code)s;
}
else
{
%(else_code)s;
}
//Write the resulting state to the execution context
if(fault == NoFault)
{
%(op_wb)s;
}
return fault;
}
}};
def template MicroFpOpDeclare {{
class %(class_name)s : public %(base_class)s
{
public:
%(class_name)s(ExtMachInst _machInst,
const char * instMnem, uint64_t setFlags,
InstRegIndex _src1, InstRegIndex _src2, InstRegIndex _dest,
uint8_t _dataSize, int8_t _spm);
%(BasicExecDeclare)s
};
}};
def template MicroFpOpConstructor {{
inline %(class_name)s::%(class_name)s(
ExtMachInst machInst, const char * instMnem, uint64_t setFlags,
InstRegIndex _src1, InstRegIndex _src2, InstRegIndex _dest,
uint8_t _dataSize, int8_t _spm) :
%(base_class)s(machInst, "%(mnemonic)s", instMnem, setFlags,
_src1, _src2, _dest, _dataSize, _spm,
%(op_class)s)
{
%(constructor)s;
}
}};
let {{
# Make these empty strings so that concatenating onto
# them will always work.
header_output = ""
decoder_output = ""
exec_output = ""
class FpOpMeta(type):
def buildCppClasses(self, name, Name, suffix, \
code, flag_code, cond_check, else_code, op_class):
# Globals to stick the output in
global header_output
global decoder_output
global exec_output
# Stick all the code together so it can be searched at once
allCode = "|".join((code, flag_code, cond_check, else_code))
# If there's something optional to do with flags, generate
# a version without it and fix up this version to use it.
if flag_code is not "" or cond_check is not "true":
self.buildCppClasses(name, Name, suffix,
code, "", "true", else_code, op_class)
suffix = "Flags" + suffix
base = "X86ISA::FpOp"
# Get everything ready for the substitution
iop_tag = InstObjParams(name, Name + suffix + "TopTag", base,
{"code" : code,
"flag_code" : flag_code,
"cond_check" : cond_check,
"else_code" : else_code,
"tag_code" : "FTW = genX87Tags(FTW, TOP, spm);",
"top_code" : "TOP = (TOP + spm + 8) % 8;",
"op_class" : op_class})
iop_top = InstObjParams(name, Name + suffix + "Top", base,
{"code" : code,
"flag_code" : flag_code,
"cond_check" : cond_check,
"else_code" : else_code,
"tag_code" : ";",
"top_code" : "TOP = (TOP + spm + 8) % 8;",
"op_class" : op_class})
iop = InstObjParams(name, Name + suffix, base,
{"code" : code,
"flag_code" : flag_code,
"cond_check" : cond_check,
"else_code" : else_code,
"tag_code" : ";",
"top_code" : ";",
"op_class" : op_class})
# Generate the actual code (finally!)
header_output += MicroFpOpDeclare.subst(iop_tag)
decoder_output += MicroFpOpConstructor.subst(iop_tag)
exec_output += MicroFpOpExecute.subst(iop_tag)
header_output += MicroFpOpDeclare.subst(iop_top)
decoder_output += MicroFpOpConstructor.subst(iop_top)
exec_output += MicroFpOpExecute.subst(iop_top)
header_output += MicroFpOpDeclare.subst(iop)
decoder_output += MicroFpOpConstructor.subst(iop)
exec_output += MicroFpOpExecute.subst(iop)
def __new__(mcls, Name, bases, dict):
abstract = False
name = Name.lower()
if "abstract" in dict:
abstract = dict['abstract']
del dict['abstract']
cls = super(FpOpMeta, mcls).__new__(mcls, Name, bases, dict)
if not abstract:
cls.className = Name
cls.mnemonic = name
code = cls.code
flag_code = cls.flag_code
cond_check = cls.cond_check
else_code = cls.else_code
op_class = cls.op_class
# Set up the C++ classes
mcls.buildCppClasses(cls, name, Name, "",
code, flag_code, cond_check, else_code, op_class)
# Hook into the microassembler dict
global microopClasses
microopClasses[name] = cls
return cls
class FpUnaryOp(X86Microop):
__metaclass__ = FpOpMeta
# This class itself doesn't act as a microop
abstract = True
# Default template parameter values
flag_code = ""
cond_check = "true"
else_code = ";"
op_class = "FloatAddOp"
def __init__(self, dest, src1, spm=0, \
SetStatus=False, UpdateFTW=True, dataSize="env.dataSize"):
self.dest = dest
self.src1 = src1
self.src2 = "InstRegIndex(0)"
self.spm = spm
self.dataSize = dataSize
if SetStatus:
self.className += "Flags"
if spm:
self.className += "Top"
if spm and UpdateFTW:
self.className += "Tag"
def getAllocator(self, microFlags):
return '''new %(class_name)s(machInst, macrocodeBlock,
%(flags)s, %(src1)s, %(src2)s, %(dest)s,
%(dataSize)s, %(spm)d)''' % {
"class_name" : self.className,
"flags" : self.microFlagsText(microFlags),
"src1" : self.src1, "src2" : self.src2,
"dest" : self.dest,
"dataSize" : self.dataSize,
"spm" : self.spm}
class FpBinaryOp(X86Microop):
__metaclass__ = FpOpMeta
# This class itself doesn't act as a microop
abstract = True
# Default template parameter values
flag_code = ""
cond_check = "true"
else_code = ";"
op_class = "FloatAddOp"
def __init__(self, dest, src1, src2, spm=0, \
SetStatus=False, UpdateFTW=True, dataSize="env.dataSize"):
self.dest = dest
self.src1 = src1
self.src2 = src2
self.spm = spm
self.dataSize = dataSize
if SetStatus:
self.className += "Flags"
if spm:
self.className += "Top"
if spm and UpdateFTW:
self.className += "Tag"
def getAllocator(self, microFlags):
return '''new %(class_name)s(machInst, macrocodeBlock,
%(flags)s, %(src1)s, %(src2)s, %(dest)s,
%(dataSize)s, %(spm)d)''' % {
"class_name" : self.className,
"flags" : self.microFlagsText(microFlags),
"src1" : self.src1, "src2" : self.src2,
"dest" : self.dest,
"dataSize" : self.dataSize,
"spm" : self.spm}
class Movfp(FpUnaryOp):
code = 'FpDestReg_uqw = FpSrcReg1_uqw;'
else_code = 'FpDestReg_uqw = FpDestReg_uqw;'
cond_check = "checkCondition(ccFlagBits | cfofBits | dfBit | \
ecfBit | ezfBit, src2)"
class Xorfp(FpBinaryOp):
code = 'FpDestReg_uqw = FpSrcReg1_uqw ^ FpSrcReg2_uqw;'
class Sqrtfp(FpBinaryOp):
code = 'FpDestReg = sqrt(FpSrcReg2);'
op_class = 'FloatSqrtOp'
class Cosfp(FpUnaryOp):
code = 'FpDestReg = cos(FpSrcReg1);'
op_class = 'FloatSqrtOp'
class Sinfp(FpUnaryOp):
code = 'FpDestReg = sin(FpSrcReg1);'
op_class = 'FloatSqrtOp'
class Tanfp(FpUnaryOp):
code = 'FpDestReg = tan(FpSrcReg1);'
op_class = 'FloatSqrtOp'
# Conversion microops
class ConvOp(FpBinaryOp):
abstract = True
op_class = 'FloatCvtOp'
def __init__(self, dest, src1):
super(ConvOp, self).__init__(dest, src1, \
"InstRegIndex(FLOATREG_MICROFP0)")
# These probably shouldn't look at the ExtMachInst directly to figure
# out what size to use and should instead delegate that to the macroop's
# constructor. That would be more efficient, and it would make the
# microops a little more modular.
class cvtf_i2d(ConvOp):
code = '''
X86IntReg intReg = SSrcReg1;
if (REX_W)
FpDestReg = intReg.SR;
else
FpDestReg = intReg.SE;
'''
class cvtf_i2d_hi(ConvOp):
code = 'FpDestReg = bits(SSrcReg1, 63, 32);'
class cvtf_d2i(ConvOp):
code = '''
int64_t intSrcReg1 = static_cast<int64_t>(FpSrcReg1);
if (REX_W)
SDestReg = intSrcReg1;
else
SDestReg = merge(SDestReg, intSrcReg1, 4);
'''
# These need to consider size at some point. They'll always use doubles
# for the moment.
class addfp(FpBinaryOp):
code = 'FpDestReg = FpSrcReg1 + FpSrcReg2;'
class mulfp(FpBinaryOp):
code = 'FpDestReg = FpSrcReg1 * FpSrcReg2;'
op_class = 'FloatMultOp'
class divfp(FpBinaryOp):
code = 'FpDestReg = FpSrcReg1 / FpSrcReg2;'
op_class = 'FloatDivOp'
class subfp(FpBinaryOp):
code = 'FpDestReg = FpSrcReg1 - FpSrcReg2;'
class Yl2xFp(FpBinaryOp):
code = '''
FpDestReg = FpSrcReg2 * (log(FpSrcReg1) / log(2));
'''
op_class = 'FloatSqrtOp'
class PremFp(FpBinaryOp):
code = '''
MiscReg new_fsw(FSW);
int src1_exp;
int src2_exp;
std::frexp(FpSrcReg1, &src1_exp);
std::frexp(FpSrcReg2, &src2_exp);
const int d(src2_exp - src1_exp);
if (d < 64) {
const int64_t q(std::trunc(FpSrcReg2 / FpSrcReg1));
FpDestReg = FpSrcReg2 - FpSrcReg1 * q;
new_fsw &= ~(CC0Bit | CC1Bit | CC2Bit | CC2Bit);
new_fsw |= (q & 0x1) ? CC1Bit : 0;
new_fsw |= (q & 0x2) ? CC3Bit : 0;
new_fsw |= (q & 0x4) ? CC0Bit : 0;
} else {
const int n(42);
const int64_t qq(std::trunc(
FpSrcReg2 / std::ldexp(FpSrcReg1, d - n)));
FpDestReg = FpSrcReg2 - std::ldexp(FpSrcReg1 * qq, d - n);
new_fsw |= CC2Bit;
}
DPRINTF(X86, "src1: %lf, src2: %lf, dest: %lf, FSW: 0x%x\\n",
FpSrcReg1, FpSrcReg2, FpDestReg, new_fsw);
'''
op_class = 'FloatDivOp'
flag_code = 'FSW = new_fsw;'
class Compfp(FpBinaryOp):
def __init__(self, src1, src2, spm=0, setStatus=False, updateFTW=True, \
dataSize="env.dataSize"):
super(Compfp, self).__init__("InstRegIndex(FLOATREG_MICROFP0)", \
src1, src2, spm, setStatus, updateFTW, dataSize)
# This class sets the condition codes in rflags according to the
# rules for comparing floating point.
code = '''
// ZF PF CF
// Unordered 1 1 1
// Greater than 0 0 0
// Less than 0 0 1
// Equal 1 0 0
// OF = SF = AF = 0
ccFlagBits = ccFlagBits & ~(SFBit | AFBit | ZFBit | PFBit);
cfofBits = cfofBits & ~(OFBit | CFBit);
if (std::isnan(FpSrcReg1) || std::isnan(FpSrcReg2)) {
ccFlagBits = ccFlagBits | (ZFBit | PFBit);
cfofBits = cfofBits | CFBit;
}
else if(FpSrcReg1 < FpSrcReg2)
cfofBits = cfofBits | CFBit;
else if(FpSrcReg1 == FpSrcReg2)
ccFlagBits = ccFlagBits | ZFBit;
'''
op_class = 'FloatCmpOp'
class absfp(FpUnaryOp):
code = 'FpDestReg = fabs(FpSrcReg1);'
flag_code = 'FSW = FSW & (~CC1Bit);'
class chsfp(FpUnaryOp):
code = 'FpDestReg = (-1) * (FpSrcReg1);'
flag_code = 'FSW = FSW & (~CC1Bit);'
class Pop87(FpUnaryOp):
def __init__(self, spm=1, UpdateFTW=True):
super(Pop87, self).__init__( \
"InstRegIndex(FLOATREG_MICROFP0)", \
"InstRegIndex(FLOATREG_MICROFP0)", \
spm=spm, SetStatus=False, UpdateFTW=UpdateFTW)
code = ''
}};
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