llvm/lib/Target/CellSPU/SPUInstrFormats.td
Scott Michel f0569be4a9 - Remove Tilmann's custom truncate lowering: it completely hosed over
DAGcombine's ability to find reasons to remove truncates when they were not
  needed. Consequently, the CellSPU backend would produce correct, but _really
  slow and horrible_, code.

  Replaced with instruction sequences that do the equivalent truncation in
  SPUInstrInfo.td.

- Re-examine how unaligned loads and stores work. Generated unaligned
  load code has been tested on the CellSPU hardware; see the i32operations.c
  and i64operations.c in CodeGen/CellSPU/useful-harnesses.  (While they may be
  toy test code, it does prove that some real world code does compile
  correctly.)

- Fix truncating stores in bug 3193 (note: unpack_df.ll will still make llc
  fault because i64 ult is not yet implemented.)

- Added i64 eq and neq for setcc and select/setcc; started new instruction
  information file for them in SPU64InstrInfo.td. Additional i64 operations
  should be added to this file and not to SPUInstrInfo.td.


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@61447 91177308-0d34-0410-b5e6-96231b3b80d8
2008-12-27 04:51:36 +00:00

296 lines
9.0 KiB
TableGen

//==== SPUInstrFormats.td - Cell SPU Instruction Formats ---*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//===----------------------------------------------------------------------===//
//
// Cell SPU instruction formats. Note that these are notationally similar to
// PowerPC, like "A-Form". But the sizes of operands and fields differ.
// This was kiped from the PPC instruction formats (seemed like a good idea...)
class SPUInstr<dag OOL, dag IOL, string asmstr, InstrItinClass itin>
: Instruction {
field bits<32> Inst;
let Namespace = "SPU";
let OutOperandList = OOL;
let InOperandList = IOL;
let AsmString = asmstr;
let Itinerary = itin;
}
// RR Format
class RRForm<bits<11> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin> {
bits<7> RA;
bits<7> RB;
bits<7> RT;
let Pattern = pattern;
let Inst{0-10} = opcode;
let Inst{11-17} = RB;
let Inst{18-24} = RA;
let Inst{25-31} = RT;
}
let RB = 0 in {
// RR Format, where RB is zeroed (dont care):
class RRForm_1<bits<11> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: RRForm<opcode, OOL, IOL, asmstr, itin, pattern>
{ }
let RA = 0 in {
// RR Format, where RA and RB are zeroed (dont care):
// Used for reads from status control registers (see FPSCRRr32)
class RRForm_2<bits<11> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: RRForm<opcode, OOL, IOL, asmstr, itin, pattern>
{ }
}
}
let RT = 0 in {
// RR Format, where RT is zeroed (don't care), or as the instruction handbook
// says, "RT is a false target." Used in "Halt if" instructions
class RRForm_3<bits<11> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: RRForm<opcode, OOL, IOL, asmstr, itin, pattern>
{ }
}
// RRR Format
class RRRForm<bits<4> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin>
{
bits<7> RA;
bits<7> RB;
bits<7> RC;
bits<7> RT;
let Pattern = pattern;
let Inst{0-3} = opcode;
let Inst{4-10} = RT;
let Inst{11-17} = RB;
let Inst{18-24} = RA;
let Inst{25-31} = RC;
}
// RI7 Format
class RI7Form<bits<11> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin>
{
bits<7> i7;
bits<7> RA;
bits<7> RT;
let Pattern = pattern;
let Inst{0-10} = opcode;
let Inst{11-17} = i7;
let Inst{18-24} = RA;
let Inst{25-31} = RT;
}
// CVTIntFp Format
class CVTIntFPForm<bits<10> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin>
{
bits<7> RA;
bits<7> RT;
let Pattern = pattern;
let Inst{0-9} = opcode;
let Inst{10-17} = 0;
let Inst{18-24} = RA;
let Inst{25-31} = RT;
}
let RA = 0 in {
class BICondForm<bits<11> opcode, dag OOL, dag IOL, string asmstr, list<dag> pattern>
: RRForm<opcode, OOL, IOL, asmstr, BranchResolv, pattern>
{ }
let RT = 0 in {
// Branch instruction format (without D/E flag settings)
class BRForm<bits<11> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: RRForm<opcode, OOL, IOL, asmstr, itin, pattern>
{ }
class BIForm<bits<11> opcode, string asmstr, list<dag> pattern>
: RRForm<opcode, (outs), (ins R32C:$func), asmstr, BranchResolv,
pattern>
{ }
let RB = 0 in {
// Return instruction (bi, branch indirect), RA is zero (LR):
class RETForm<string asmstr, list<dag> pattern>
: BRForm<0b00010101100, (outs), (ins), asmstr, BranchResolv,
pattern>
{ }
}
}
}
// Branch indirect external data forms:
class BISLEDForm<bits<2> DE_flag, string asmstr, list<dag> pattern>
: SPUInstr<(outs), (ins indcalltarget:$func), asmstr, BranchResolv>
{
bits<7> Rcalldest;
let Pattern = pattern;
let Inst{0-10} = 0b11010101100;
let Inst{11} = 0;
let Inst{12-13} = DE_flag;
let Inst{14-17} = 0b0000;
let Inst{18-24} = Rcalldest;
let Inst{25-31} = 0b0000000;
}
// RI10 Format
class RI10Form<bits<8> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin>
{
bits<10> i10;
bits<7> RA;
bits<7> RT;
let Pattern = pattern;
let Inst{0-7} = opcode;
let Inst{8-17} = i10;
let Inst{18-24} = RA;
let Inst{25-31} = RT;
}
// RI10 Format, where the constant is zero (or effectively ignored by the
// SPU)
let i10 = 0 in {
class RI10Form_1<bits<8> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: RI10Form<opcode, OOL, IOL, asmstr, itin, pattern>
{ }
}
// RI10 Format, where RT is ignored.
// This format is used primarily by the Halt If ... Immediate set of
// instructions
let RT = 0 in {
class RI10Form_2<bits<8> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: RI10Form<opcode, OOL, IOL, asmstr, itin, pattern>
{ }
}
// RI16 Format
class RI16Form<bits<9> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin>
{
bits<16> i16;
bits<7> RT;
let Pattern = pattern;
let Inst{0-8} = opcode;
let Inst{9-24} = i16;
let Inst{25-31} = RT;
}
// Specialized version of the RI16 Format for unconditional branch relative and
// branch absolute, branch and set link. Note that for branch and set link, the
// link register doesn't have to be $lr, but this is actually hard coded into
// the instruction pattern.
let RT = 0 in {
class UncondBranch<bits<9> opcode, dag OOL, dag IOL, string asmstr,
list<dag> pattern>
: RI16Form<opcode, OOL, IOL, asmstr, BranchResolv, pattern>
{ }
class BranchSetLink<bits<9> opcode, dag OOL, dag IOL, string asmstr,
list<dag> pattern>
: RI16Form<opcode, OOL, IOL, asmstr, BranchResolv, pattern>
{ }
}
//===----------------------------------------------------------------------===//
// Specialized versions of RI16:
//===----------------------------------------------------------------------===//
// RI18 Format
class RI18Form<bits<7> opcode, dag OOL, dag IOL, string asmstr,
InstrItinClass itin, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, itin>
{
bits<18> i18;
bits<7> RT;
let Pattern = pattern;
let Inst{0-6} = opcode;
let Inst{7-24} = i18;
let Inst{25-31} = RT;
}
//===----------------------------------------------------------------------===//
// Instruction formats for intrinsics:
//===----------------------------------------------------------------------===//
// RI10 Format for v8i16 intrinsics
class RI10_Int_v8i16<bits<8> opcode, string opc, InstrItinClass itin,
Intrinsic IntID> :
RI10Form<opcode, (outs VECREG:$rT), (ins s10imm:$val, VECREG:$rA),
!strconcat(opc, " $rT, $rA, $val"), itin,
[(set (v8i16 VECREG:$rT), (IntID (v8i16 VECREG:$rA),
i16ImmSExt10:$val))] >;
class RI10_Int_v4i32<bits<8> opcode, string opc, InstrItinClass itin,
Intrinsic IntID> :
RI10Form<opcode, (outs VECREG:$rT), (ins s10imm:$val, VECREG:$rA),
!strconcat(opc, " $rT, $rA, $val"), itin,
[(set (v4i32 VECREG:$rT), (IntID (v4i32 VECREG:$rA),
i32ImmSExt10:$val))] >;
// RR Format for v8i16 intrinsics
class RR_Int_v8i16<bits<11> opcode, string opc, InstrItinClass itin,
Intrinsic IntID> :
RRForm<opcode, (outs VECREG:$rT), (ins VECREG:$rA, VECREG:$rB),
!strconcat(opc, " $rT, $rA, $rB"), itin,
[(set (v8i16 VECREG:$rT), (IntID (v8i16 VECREG:$rA),
(v8i16 VECREG:$rB)))] >;
// RR Format for v4i32 intrinsics
class RR_Int_v4i32<bits<11> opcode, string opc, InstrItinClass itin,
Intrinsic IntID> :
RRForm<opcode, (outs VECREG:$rT), (ins VECREG:$rA, VECREG:$rB),
!strconcat(opc, " $rT, $rA, $rB"), itin,
[(set (v4i32 VECREG:$rT), (IntID (v4i32 VECREG:$rA),
(v4i32 VECREG:$rB)))] >;
//===----------------------------------------------------------------------===//
// Pseudo instructions, like call frames:
//===----------------------------------------------------------------------===//
class Pseudo<dag OOL, dag IOL, string asmstr, list<dag> pattern>
: SPUInstr<OOL, IOL, asmstr, NoItinerary> {
let Pattern = pattern;
let Inst{31-0} = 0;
}