binutils-gdb/sim/mips/sb1.igen

244 lines
5.9 KiB
C

// -*- C -*-
// Simulator definition for the Broadcom SiByte SB-1 CPU extensions.
// Copyright (C) 2002, 2010 Free Software Foundation, Inc.
// Contributed by Ed Satterthwaite and Chris Demetriou, of Broadcom
// Corporation (SiByte).
//
// This file is part of GDB, the GNU debugger.
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
// Helper:
//
// Check that the SB-1 extension instruction can currently be used, and
// signal a ReservedInstruction exception if not.
//
:function:::void:check_sbx:instruction_word insn
*sb1:
{
if ((SR & status_SBX) == 0)
SignalException(ReservedInstruction, insn);
}
// MDMX ASE Instructions
// ---------------------
//
// The SB-1 implements the format OB subset of MDMX
// and has three additions (pavg, pabsdiff, pabsdifc).
// In addition, there are a couple of partial-decoding
// issues for the read/write accumulator instructions.
//
// This code is structured so that mdmx.igen can be used by
// selecting the allowed instructions either via model, or by
// using check_mdmx_fmtsel and check_mdmx_fmtop to cause an
// exception if the instruction is not allowed.
:function:::void:check_mdmx:instruction_word insn
*sb1:
{
if (!COP_Usable(1))
SignalExceptionCoProcessorUnusable(1);
if ((SR & status_MX) == 0)
SignalExceptionMDMX();
check_u64 (SD_, insn);
}
:function:::int:check_mdmx_fmtsel:instruction_word insn, int fmtsel
*sb1:
{
switch (fmtsel & 0x03)
{
case 0x00: /* ob */
case 0x02:
return 1;
case 0x01: /* qh */
case 0x03: /* UNPREDICTABLE */
SignalException (ReservedInstruction, insn);
return 0;
}
return 0;
}
:function:::int:check_mdmx_fmtop:instruction_word insn, int fmtop
*sb1:
{
switch (fmtop & 0x01)
{
case 0x00: /* ob */
return 1;
case 0x01: /* qh */
SignalException (ReservedInstruction, insn);
return 0;
}
return 0;
}
011110,10,2.X!0,1.FMTOP,00000,00000,5.VD,111111:MDMX:64::RACH.sb1.fmt
"rach.?<X>.%s<FMTOP> v<VD>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,00,2.X!0,1.FMTOP,00000,00000,5.VD,111111:MDMX:64::RACL.sb1.fmt
"racl.?<X>.%s<FMTOP> v<VD>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,01,2.X!0,1.FMTOP,00000,00000,5.VD,111111:MDMX:64::RACM.sb1.fmt
"racm.?<X>.%s<FMTOP> v<VD>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,2.X1!0!1!2,2.X2,1.FMTOP,00000,00000,5.VD,111111:MDMX:64::RAC.sb1.fmt
"rac?<X1>.?<X2> v<VD>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,10,2.X!0,1.FMTOP,00000,5.VS,00000,111110:MDMX:64::WACH.sb1.fmt
"wach.?<X>.%s<FMTOP> v<VS>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,00,2.X!0,1.FMTOP,5.VT,5.VS,00000,111110:MDMX:64::WACL.sb1.fmt
"wacl.?<X>.%s<FMTOP> v<VS>,v<VT>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,2.X1!0!2,2.X2,1.FMTOP,5.VT,5.VS,00000,111110:MDMX:64::WAC.sb1.fmt
"wacl?<X1>.?<X2>.%s<FMTOP> v<VS>,v<VT>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_mdmx_fmtop (SD_, instruction_0, FMTOP);
/* No op. */
}
011110,5.FMTSEL,5.VT,5.VS,5.VD,001001:MDMX:64::PABSDIFF.fmt
"pabsdiff.%s<FMTSEL> v<VD>,v<VS>,v<VT>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_sbx (SD_, instruction_0);
check_mdmx_fmtsel (SD_, instruction_0, FMTSEL);
StoreFPR(VD,fmt_mdmx,MX_AbsDiff(ValueFPR(VS,fmt_mdmx),VT,FMTSEL));
}
011110,5.FMTSEL,5.VT,5.VS,00000,110101:MDMX:64::PABSDIFC.fmt
"pabsdifc.%<FMTSEL> v<VS>,v<VT>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_sbx (SD_, instruction_0);
check_mdmx_fmtsel (SD_, instruction_0, FMTSEL);
MX_AbsDiffC(ValueFPR(VS,fmt_mdmx),VT,FMTSEL);
}
011110,5.FMTSEL,5.VT,5.VS,5.VD,001000:MDMX:64::PAVG.fmt
"pavg.%s<FMTSEL> v<VD>,v<VS>,v<VT>"
*sb1:
{
check_mdmx (SD_, instruction_0);
check_sbx (SD_, instruction_0);
check_mdmx_fmtsel (SD_, instruction_0, FMTSEL);
StoreFPR(VD,fmt_mdmx,MX_Avg(ValueFPR(VS,fmt_mdmx),VT,FMTSEL));
}
// Paired-Single Extension Instructions
// ------------------------------------
//
// The SB-1 implements several .PS format instructions that are
// extensions to the MIPS64 architecture.
010001,10,3.FMT=6,5.FT,5.FS,5.FD,000011:COP1:32,f::DIV.PS
"div.%s<FMT> f<FD>, f<FS>, f<FT>"
*sb1:
{
int fmt = FMT;
check_fpu (SD_);
check_sbx (SD_, instruction_0);
StoreFPR (FD, fmt, Divide (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt));
}
010001,10,3.FMT=6,00000,5.FS,5.FD,010101:COP1:32,f::RECIP.PS
"recip.%s<FMT> f<FD>, f<FS>"
*sb1:
{
int fmt = FMT;
check_fpu (SD_);
check_sbx (SD_, instruction_0);
StoreFPR (FD, fmt, Recip (ValueFPR (FS, fmt), fmt));
}
010001,10,3.FMT=6,00000,5.FS,5.FD,010110:COP1:32,f::RSQRT.PS
"rsqrt.%s<FMT> f<FD>, f<FS>"
*sb1:
{
int fmt = FMT;
check_fpu (SD_);
check_sbx (SD_, instruction_0);
StoreFPR (FD, fmt, RSquareRoot (ValueFPR (FS, fmt), fmt));
}
010001,10,3.FMT=6,00000,5.FS,5.FD,000100:COP1:32,f::SQRT.PS
"sqrt.%s<FMT> f<FD>, f<FS>"
*sb1:
{
int fmt = FMT;
check_fpu (SD_);
check_sbx (SD_, instruction_0);
StoreFPR (FD, fmt, (SquareRoot (ValueFPR (FS, fmt), fmt)));
}