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// -*- 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.
//
// Copyright (c) 2007-2008 The Florida State University
// 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: Stephen Hines
def operand_types {{
'sb' : ('signed int', 8),
'ub' : ('unsigned int', 8),
'sh' : ('signed int', 16),
'uh' : ('unsigned int', 16),
'sw' : ('signed int', 32),
'uw' : ('unsigned int', 32),
'ud' : ('unsigned int', 64),
'tud' : ('twin64 int', 64),
'sf' : ('float', 32),
'df' : ('float', 64)
}};
let {{
maybePCRead = '''
((%(reg_idx)s == PCReg) ? readPC(xc) : xc->%(func)s(this, %(op_idx)s))
'''
maybeAlignedPCRead = '''
((%(reg_idx)s == PCReg) ? (roundDown(readPC(xc), 4)) :
xc->%(func)s(this, %(op_idx)s))
'''
maybePCWrite = '''
((%(reg_idx)s == PCReg) ? setNextPC(xc, %(final_val)s) :
xc->%(func)s(this, %(op_idx)s, %(final_val)s))
'''
maybeIWPCWrite = '''
((%(reg_idx)s == PCReg) ? setIWNextPC(xc, %(final_val)s) :
xc->%(func)s(this, %(op_idx)s, %(final_val)s))
'''
maybeAIWPCWrite = '''
if (%(reg_idx)s == PCReg) {
bool thumb = THUMB;
if (thumb) {
setNextPC(xc, %(final_val)s);
} else {
setIWNextPC(xc, %(final_val)s);
}
} else {
xc->%(func)s(this, %(op_idx)s, %(final_val)s);
}
'''
#PCState operands need to have a sorting index (the number at the end)
#less than all the integer registers which might update the PC. That way
#if the flag bits of the pc state are updated and a branch happens through
#R15, the updates are layered properly and the R15 update isn't lost.
srtNormal = 5
srtCpsr = 4
srtBase = 3
srtPC = 2
srtMode = 1
srtEPC = 0
def floatReg(idx):
return ('FloatReg', 'sf', idx, 'IsFloating', srtNormal)
def intReg(idx):
return ('IntReg', 'uw', idx, 'IsInteger', srtNormal,
maybePCRead, maybePCWrite)
def intRegNPC(idx):
return ('IntReg', 'uw', idx, 'IsInteger', srtNormal)
def intRegAPC(idx, id = srtNormal):
return ('IntReg', 'uw', idx, 'IsInteger', id,
maybeAlignedPCRead, maybePCWrite)
def intRegIWPC(idx):
return ('IntReg', 'uw', idx, 'IsInteger', srtNormal,
maybePCRead, maybeIWPCWrite)
def intRegAIWPC(idx):
return ('IntReg', 'uw', idx, 'IsInteger', srtNormal,
maybePCRead, maybeAIWPCWrite)
def intRegCC(idx):
return ('IntReg', 'uw', idx, None, srtNormal)
def cntrlReg(idx, id = srtNormal, type = 'uw'):
return ('ControlReg', type, idx, (None, None, 'IsControl'), id)
def cntrlRegNC(idx, id = srtNormal, type = 'uw'):
return ('ControlReg', type, idx, None, id)
def pcStateReg(idx, id):
return ('PCState', 'uw', idx, (None, None, 'IsControl'), id)
}};
def operands {{
#Abstracted integer reg operands
'Dest': intReg('dest'),
'IWDest': intRegIWPC('dest'),
'AIWDest': intRegAIWPC('dest'),
'Dest2': intReg('dest2'),
'Result': intReg('result'),
'Base': intRegAPC('base', id = srtBase),
'Index': intReg('index'),
'Shift': intReg('shift'),
'Op1': intReg('op1'),
'Op2': intReg('op2'),
'Op3': intReg('op3'),
'Reg0': intReg('reg0'),
'Reg1': intReg('reg1'),
'Reg2': intReg('reg2'),
'Reg3': intReg('reg3'),
#Fixed index integer reg operands
'SpMode': intRegNPC('intRegInMode((OperatingMode)regMode, INTREG_SP)'),
'LR': intRegNPC('INTREG_LR'),
'R7': intRegNPC('7'),
# First four arguments are passed in registers
'R0': intRegNPC('0'),
'R1': intRegNPC('1'),
'R2': intRegNPC('2'),
'R3': intRegNPC('3'),
#Pseudo integer condition code registers
'CondCodesF': intRegCC('INTREG_CONDCODES_F'),
'CondCodesGE': intRegCC('INTREG_CONDCODES_GE'),
'OptCondCodesF': intRegCC(
'''(condCode == COND_AL || condCode == COND_UC) ?
INTREG_ZERO : INTREG_CONDCODES_F'''),
'FpCondCodes': intRegCC('INTREG_FPCONDCODES'),
#Abstracted floating point reg operands
'FpDest': floatReg('(dest + 0)'),
'FpDestP0': floatReg('(dest + 0)'),
'FpDestP1': floatReg('(dest + 1)'),
'FpDestP2': floatReg('(dest + 2)'),
'FpDestP3': floatReg('(dest + 3)'),
'FpDestP4': floatReg('(dest + 4)'),
'FpDestP5': floatReg('(dest + 5)'),
'FpDestP6': floatReg('(dest + 6)'),
'FpDestP7': floatReg('(dest + 7)'),
'FpDestS0P0': floatReg('(dest + step * 0 + 0)'),
'FpDestS0P1': floatReg('(dest + step * 0 + 1)'),
'FpDestS1P0': floatReg('(dest + step * 1 + 0)'),
'FpDestS1P1': floatReg('(dest + step * 1 + 1)'),
'FpDestS2P0': floatReg('(dest + step * 2 + 0)'),
'FpDestS2P1': floatReg('(dest + step * 2 + 1)'),
'FpDestS3P0': floatReg('(dest + step * 3 + 0)'),
'FpDestS3P1': floatReg('(dest + step * 3 + 1)'),
'FpDest2': floatReg('(dest2 + 0)'),
'FpDest2P0': floatReg('(dest2 + 0)'),
'FpDest2P1': floatReg('(dest2 + 1)'),
'FpDest2P2': floatReg('(dest2 + 2)'),
'FpDest2P3': floatReg('(dest2 + 3)'),
'FpOp1': floatReg('(op1 + 0)'),
'FpOp1P0': floatReg('(op1 + 0)'),
'FpOp1P1': floatReg('(op1 + 1)'),
'FpOp1P2': floatReg('(op1 + 2)'),
'FpOp1P3': floatReg('(op1 + 3)'),
'FpOp1P4': floatReg('(op1 + 4)'),
'FpOp1P5': floatReg('(op1 + 5)'),
'FpOp1P6': floatReg('(op1 + 6)'),
'FpOp1P7': floatReg('(op1 + 7)'),
'FpOp1S0P0': floatReg('(op1 + step * 0 + 0)'),
'FpOp1S0P1': floatReg('(op1 + step * 0 + 1)'),
'FpOp1S1P0': floatReg('(op1 + step * 1 + 0)'),
'FpOp1S1P1': floatReg('(op1 + step * 1 + 1)'),
'FpOp1S2P0': floatReg('(op1 + step * 2 + 0)'),
'FpOp1S2P1': floatReg('(op1 + step * 2 + 1)'),
'FpOp1S3P0': floatReg('(op1 + step * 3 + 0)'),
'FpOp1S3P1': floatReg('(op1 + step * 3 + 1)'),
'FpOp2': floatReg('(op2 + 0)'),
'FpOp2P0': floatReg('(op2 + 0)'),
'FpOp2P1': floatReg('(op2 + 1)'),
'FpOp2P2': floatReg('(op2 + 2)'),
'FpOp2P3': floatReg('(op2 + 3)'),
#Abstracted control reg operands
'MiscDest': cntrlReg('dest'),
'MiscOp1': cntrlReg('op1'),
#Fixed index control regs
'Cpsr': cntrlReg('MISCREG_CPSR', srtCpsr),
'CpsrQ': cntrlReg('MISCREG_CPSR_Q', srtCpsr),
'Spsr': cntrlRegNC('MISCREG_SPSR'),
'Fpsr': cntrlRegNC('MISCREG_FPSR'),
'Fpsid': cntrlRegNC('MISCREG_FPSID'),
'Fpscr': cntrlRegNC('MISCREG_FPSCR'),
'FpscrQc': cntrlRegNC('MISCREG_FPSCR_QC'),
'FpscrExc': cntrlRegNC('MISCREG_FPSCR_EXC'),
'Cpacr': cntrlReg('MISCREG_CPACR'),
'Fpexc': cntrlRegNC('MISCREG_FPEXC'),
'Sctlr': cntrlRegNC('MISCREG_SCTLR'),
'SevMailbox': cntrlRegNC('MISCREG_SEV_MAILBOX'),
'LLSCLock': cntrlRegNC('MISCREG_LOCKFLAG'),
#Register fields for microops
'URa' : intReg('ura'),
'IWRa' : intRegIWPC('ura'),
'Fa' : floatReg('ura'),
'URb' : intReg('urb'),
'URc' : intReg('urc'),
#Memory Operand
'Mem': ('Mem', 'uw', None, ('IsMemRef', 'IsLoad', 'IsStore'), srtNormal),
#PCState fields
'PC': pcStateReg('instPC', srtPC),
'NPC': pcStateReg('instNPC', srtPC),
'pNPC': pcStateReg('instNPC', srtEPC),
'IWNPC': pcStateReg('instIWNPC', srtPC),
'Thumb': pcStateReg('thumb', srtPC),
'NextThumb': pcStateReg('nextThumb', srtMode),
'NextJazelle': pcStateReg('nextJazelle', srtMode),
'NextItState': pcStateReg('nextItstate', srtMode),
'Itstate': pcStateReg('itstate', srtMode),
#Register operands depending on a field in the instruction encoding. These
#should be avoided since they may not be portable across different
#encodings of the same instruction.
'Rd': intReg('RD'),
'Rm': intReg('RM'),
'Rs': intReg('RS'),
'Rn': intReg('RN'),
'Rt': intReg('RT')
}};
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