llvm/lib/Target/R600/R600InstrFormats.td
2013-09-04 19:53:30 +00:00

493 lines
11 KiB
TableGen

//===-- R600InstrFormats.td - R600 Instruction Encodings ------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// R600 Instruction format definitions.
//
//===----------------------------------------------------------------------===//
class InstR600 <dag outs, dag ins, string asm, list<dag> pattern,
InstrItinClass itin>
: AMDGPUInst <outs, ins, asm, pattern> {
field bits<64> Inst;
bit Trig = 0;
bit Op3 = 0;
bit isVector = 0;
bits<2> FlagOperandIdx = 0;
bit Op1 = 0;
bit Op2 = 0;
bit LDS_1A = 0;
bit LDS_1A1D = 0;
bit HasNativeOperands = 0;
bit VTXInst = 0;
bit TEXInst = 0;
bit ALUInst = 0;
bit IsExport = 0;
bit LDS_1A2D = 0;
let Namespace = "AMDGPU";
let OutOperandList = outs;
let InOperandList = ins;
let AsmString = asm;
let Pattern = pattern;
let Itinerary = itin;
let TSFlags{4} = Trig;
let TSFlags{5} = Op3;
// Vector instructions are instructions that must fill all slots in an
// instruction group
let TSFlags{6} = isVector;
let TSFlags{8-7} = FlagOperandIdx;
let TSFlags{9} = HasNativeOperands;
let TSFlags{10} = Op1;
let TSFlags{11} = Op2;
let TSFlags{12} = VTXInst;
let TSFlags{13} = TEXInst;
let TSFlags{14} = ALUInst;
let TSFlags{15} = LDS_1A;
let TSFlags{16} = LDS_1A1D;
let TSFlags{17} = IsExport;
let TSFlags{18} = LDS_1A2D;
}
//===----------------------------------------------------------------------===//
// ALU instructions
//===----------------------------------------------------------------------===//
class R600_ALU_LDS_Word0 {
field bits<32> Word0;
bits<11> src0;
bits<1> src0_rel;
bits<11> src1;
bits<1> src1_rel;
bits<3> index_mode = 0;
bits<2> pred_sel;
bits<1> last;
bits<9> src0_sel = src0{8-0};
bits<2> src0_chan = src0{10-9};
bits<9> src1_sel = src1{8-0};
bits<2> src1_chan = src1{10-9};
let Word0{8-0} = src0_sel;
let Word0{9} = src0_rel;
let Word0{11-10} = src0_chan;
let Word0{21-13} = src1_sel;
let Word0{22} = src1_rel;
let Word0{24-23} = src1_chan;
let Word0{28-26} = index_mode;
let Word0{30-29} = pred_sel;
let Word0{31} = last;
}
class R600ALU_Word0 : R600_ALU_LDS_Word0 {
bits<1> src0_neg;
bits<1> src1_neg;
let Word0{12} = src0_neg;
let Word0{25} = src1_neg;
}
class R600ALU_Word1 {
field bits<32> Word1;
bits<11> dst;
bits<3> bank_swizzle;
bits<1> dst_rel;
bits<1> clamp;
bits<7> dst_sel = dst{6-0};
bits<2> dst_chan = dst{10-9};
let Word1{20-18} = bank_swizzle;
let Word1{27-21} = dst_sel;
let Word1{28} = dst_rel;
let Word1{30-29} = dst_chan;
let Word1{31} = clamp;
}
class R600ALU_Word1_OP2 <bits<11> alu_inst> : R600ALU_Word1{
bits<1> src0_abs;
bits<1> src1_abs;
bits<1> update_exec_mask;
bits<1> update_pred;
bits<1> write;
bits<2> omod;
let Word1{0} = src0_abs;
let Word1{1} = src1_abs;
let Word1{2} = update_exec_mask;
let Word1{3} = update_pred;
let Word1{4} = write;
let Word1{6-5} = omod;
let Word1{17-7} = alu_inst;
}
class R600ALU_Word1_OP3 <bits<5> alu_inst> : R600ALU_Word1{
bits<11> src2;
bits<1> src2_rel;
bits<1> src2_neg;
bits<9> src2_sel = src2{8-0};
bits<2> src2_chan = src2{10-9};
let Word1{8-0} = src2_sel;
let Word1{9} = src2_rel;
let Word1{11-10} = src2_chan;
let Word1{12} = src2_neg;
let Word1{17-13} = alu_inst;
}
class R600LDS_Word1 {
field bits<32> Word1;
bits<11> src2;
bits<9> src2_sel = src2{8-0};
bits<2> src2_chan = src2{10-9};
bits<1> src2_rel;
// offset specifies the stride offset to the second set of data to be read
// from. This is a dword offset.
bits<5> alu_inst = 17; // OP3_INST_LDS_IDX_OP
bits<3> bank_swizzle;
bits<6> lds_op;
bits<2> dst_chan = 0;
let Word1{8-0} = src2_sel;
let Word1{9} = src2_rel;
let Word1{11-10} = src2_chan;
let Word1{17-13} = alu_inst;
let Word1{20-18} = bank_swizzle;
let Word1{26-21} = lds_op;
let Word1{30-29} = dst_chan;
}
/*
XXX: R600 subtarget uses a slightly different encoding than the other
subtargets. We currently handle this in R600MCCodeEmitter, but we may
want to use these instruction classes in the future.
class R600ALU_Word1_OP2_r600 : R600ALU_Word1_OP2 {
bits<1> fog_merge;
bits<10> alu_inst;
let Inst{37} = fog_merge;
let Inst{39-38} = omod;
let Inst{49-40} = alu_inst;
}
class R600ALU_Word1_OP2_r700 : R600ALU_Word1_OP2 {
bits<11> alu_inst;
let Inst{38-37} = omod;
let Inst{49-39} = alu_inst;
}
*/
//===----------------------------------------------------------------------===//
// Vertex Fetch instructions
//===----------------------------------------------------------------------===//
class VTX_WORD0 {
field bits<32> Word0;
bits<7> src_gpr;
bits<5> VC_INST;
bits<2> FETCH_TYPE;
bits<1> FETCH_WHOLE_QUAD;
bits<8> BUFFER_ID;
bits<1> SRC_REL;
bits<2> SRC_SEL_X;
let Word0{4-0} = VC_INST;
let Word0{6-5} = FETCH_TYPE;
let Word0{7} = FETCH_WHOLE_QUAD;
let Word0{15-8} = BUFFER_ID;
let Word0{22-16} = src_gpr;
let Word0{23} = SRC_REL;
let Word0{25-24} = SRC_SEL_X;
}
class VTX_WORD0_eg : VTX_WORD0 {
bits<6> MEGA_FETCH_COUNT;
let Word0{31-26} = MEGA_FETCH_COUNT;
}
class VTX_WORD0_cm : VTX_WORD0 {
bits<2> SRC_SEL_Y;
bits<2> STRUCTURED_READ;
bits<1> LDS_REQ;
bits<1> COALESCED_READ;
let Word0{27-26} = SRC_SEL_Y;
let Word0{29-28} = STRUCTURED_READ;
let Word0{30} = LDS_REQ;
let Word0{31} = COALESCED_READ;
}
class VTX_WORD1_GPR {
field bits<32> Word1;
bits<7> dst_gpr;
bits<1> DST_REL;
bits<3> DST_SEL_X;
bits<3> DST_SEL_Y;
bits<3> DST_SEL_Z;
bits<3> DST_SEL_W;
bits<1> USE_CONST_FIELDS;
bits<6> DATA_FORMAT;
bits<2> NUM_FORMAT_ALL;
bits<1> FORMAT_COMP_ALL;
bits<1> SRF_MODE_ALL;
let Word1{6-0} = dst_gpr;
let Word1{7} = DST_REL;
let Word1{8} = 0; // Reserved
let Word1{11-9} = DST_SEL_X;
let Word1{14-12} = DST_SEL_Y;
let Word1{17-15} = DST_SEL_Z;
let Word1{20-18} = DST_SEL_W;
let Word1{21} = USE_CONST_FIELDS;
let Word1{27-22} = DATA_FORMAT;
let Word1{29-28} = NUM_FORMAT_ALL;
let Word1{30} = FORMAT_COMP_ALL;
let Word1{31} = SRF_MODE_ALL;
}
//===----------------------------------------------------------------------===//
// Texture fetch instructions
//===----------------------------------------------------------------------===//
class TEX_WORD0 {
field bits<32> Word0;
bits<5> TEX_INST;
bits<2> INST_MOD;
bits<1> FETCH_WHOLE_QUAD;
bits<8> RESOURCE_ID;
bits<7> SRC_GPR;
bits<1> SRC_REL;
bits<1> ALT_CONST;
bits<2> RESOURCE_INDEX_MODE;
bits<2> SAMPLER_INDEX_MODE;
let Word0{4-0} = TEX_INST;
let Word0{6-5} = INST_MOD;
let Word0{7} = FETCH_WHOLE_QUAD;
let Word0{15-8} = RESOURCE_ID;
let Word0{22-16} = SRC_GPR;
let Word0{23} = SRC_REL;
let Word0{24} = ALT_CONST;
let Word0{26-25} = RESOURCE_INDEX_MODE;
let Word0{28-27} = SAMPLER_INDEX_MODE;
}
class TEX_WORD1 {
field bits<32> Word1;
bits<7> DST_GPR;
bits<1> DST_REL;
bits<3> DST_SEL_X;
bits<3> DST_SEL_Y;
bits<3> DST_SEL_Z;
bits<3> DST_SEL_W;
bits<7> LOD_BIAS;
bits<1> COORD_TYPE_X;
bits<1> COORD_TYPE_Y;
bits<1> COORD_TYPE_Z;
bits<1> COORD_TYPE_W;
let Word1{6-0} = DST_GPR;
let Word1{7} = DST_REL;
let Word1{11-9} = DST_SEL_X;
let Word1{14-12} = DST_SEL_Y;
let Word1{17-15} = DST_SEL_Z;
let Word1{20-18} = DST_SEL_W;
let Word1{27-21} = LOD_BIAS;
let Word1{28} = COORD_TYPE_X;
let Word1{29} = COORD_TYPE_Y;
let Word1{30} = COORD_TYPE_Z;
let Word1{31} = COORD_TYPE_W;
}
class TEX_WORD2 {
field bits<32> Word2;
bits<5> OFFSET_X;
bits<5> OFFSET_Y;
bits<5> OFFSET_Z;
bits<5> SAMPLER_ID;
bits<3> SRC_SEL_X;
bits<3> SRC_SEL_Y;
bits<3> SRC_SEL_Z;
bits<3> SRC_SEL_W;
let Word2{4-0} = OFFSET_X;
let Word2{9-5} = OFFSET_Y;
let Word2{14-10} = OFFSET_Z;
let Word2{19-15} = SAMPLER_ID;
let Word2{22-20} = SRC_SEL_X;
let Word2{25-23} = SRC_SEL_Y;
let Word2{28-26} = SRC_SEL_Z;
let Word2{31-29} = SRC_SEL_W;
}
//===----------------------------------------------------------------------===//
// Control Flow Instructions
//===----------------------------------------------------------------------===//
class CF_WORD1_R600 {
field bits<32> Word1;
bits<3> POP_COUNT;
bits<5> CF_CONST;
bits<2> COND;
bits<3> COUNT;
bits<6> CALL_COUNT;
bits<1> COUNT_3;
bits<1> END_OF_PROGRAM;
bits<1> VALID_PIXEL_MODE;
bits<7> CF_INST;
bits<1> WHOLE_QUAD_MODE;
bits<1> BARRIER;
let Word1{2-0} = POP_COUNT;
let Word1{7-3} = CF_CONST;
let Word1{9-8} = COND;
let Word1{12-10} = COUNT;
let Word1{18-13} = CALL_COUNT;
let Word1{19} = COUNT_3;
let Word1{21} = END_OF_PROGRAM;
let Word1{22} = VALID_PIXEL_MODE;
let Word1{29-23} = CF_INST;
let Word1{30} = WHOLE_QUAD_MODE;
let Word1{31} = BARRIER;
}
class CF_WORD0_EG {
field bits<32> Word0;
bits<24> ADDR;
bits<3> JUMPTABLE_SEL;
let Word0{23-0} = ADDR;
let Word0{26-24} = JUMPTABLE_SEL;
}
class CF_WORD1_EG {
field bits<32> Word1;
bits<3> POP_COUNT;
bits<5> CF_CONST;
bits<2> COND;
bits<6> COUNT;
bits<1> VALID_PIXEL_MODE;
bits<1> END_OF_PROGRAM;
bits<8> CF_INST;
bits<1> BARRIER;
let Word1{2-0} = POP_COUNT;
let Word1{7-3} = CF_CONST;
let Word1{9-8} = COND;
let Word1{15-10} = COUNT;
let Word1{20} = VALID_PIXEL_MODE;
let Word1{21} = END_OF_PROGRAM;
let Word1{29-22} = CF_INST;
let Word1{31} = BARRIER;
}
class CF_ALU_WORD0 {
field bits<32> Word0;
bits<22> ADDR;
bits<4> KCACHE_BANK0;
bits<4> KCACHE_BANK1;
bits<2> KCACHE_MODE0;
let Word0{21-0} = ADDR;
let Word0{25-22} = KCACHE_BANK0;
let Word0{29-26} = KCACHE_BANK1;
let Word0{31-30} = KCACHE_MODE0;
}
class CF_ALU_WORD1 {
field bits<32> Word1;
bits<2> KCACHE_MODE1;
bits<8> KCACHE_ADDR0;
bits<8> KCACHE_ADDR1;
bits<7> COUNT;
bits<1> ALT_CONST;
bits<4> CF_INST;
bits<1> WHOLE_QUAD_MODE;
bits<1> BARRIER;
let Word1{1-0} = KCACHE_MODE1;
let Word1{9-2} = KCACHE_ADDR0;
let Word1{17-10} = KCACHE_ADDR1;
let Word1{24-18} = COUNT;
let Word1{25} = ALT_CONST;
let Word1{29-26} = CF_INST;
let Word1{30} = WHOLE_QUAD_MODE;
let Word1{31} = BARRIER;
}
class CF_ALLOC_EXPORT_WORD0_RAT {
field bits<32> Word0;
bits<4> rat_id;
bits<6> rat_inst;
bits<2> rim;
bits<2> type;
bits<7> rw_gpr;
bits<1> rw_rel;
bits<7> index_gpr;
bits<2> elem_size;
let Word0{3-0} = rat_id;
let Word0{9-4} = rat_inst;
let Word0{10} = 0; // Reserved
let Word0{12-11} = rim;
let Word0{14-13} = type;
let Word0{21-15} = rw_gpr;
let Word0{22} = rw_rel;
let Word0{29-23} = index_gpr;
let Word0{31-30} = elem_size;
}
class CF_ALLOC_EXPORT_WORD1_BUF {
field bits<32> Word1;
bits<12> array_size;
bits<4> comp_mask;
bits<4> burst_count;
bits<1> vpm;
bits<1> eop;
bits<8> cf_inst;
bits<1> mark;
bits<1> barrier;
let Word1{11-0} = array_size;
let Word1{15-12} = comp_mask;
let Word1{19-16} = burst_count;
let Word1{20} = vpm;
let Word1{21} = eop;
let Word1{29-22} = cf_inst;
let Word1{30} = mark;
let Word1{31} = barrier;
}