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|
/*
* Copyright © 2018 Valve Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*
*/
#ifndef ACO_IR_H
#define ACO_IR_H
#include <vector>
#include <set>
#include <bitset>
#include <memory>
#include "nir.h"
#include "ac_binary.h"
#include "amd_family.h"
#include "aco_opcodes.h"
#include "aco_util.h"
struct radv_nir_compiler_options;
struct radv_shader_info;
namespace aco {
extern uint64_t debug_flags;
enum {
DEBUG_VALIDATE = 0x1,
DEBUG_VALIDATE_RA = 0x2,
DEBUG_PERFWARN = 0x4,
};
/**
* Representation of the instruction's microcode encoding format
* Note: Some Vector ALU Formats can be combined, such that:
* - VOP2* | VOP3A represents a VOP2 instruction in VOP3A encoding
* - VOP2* | DPP represents a VOP2 instruction with data parallel primitive.
* - VOP2* | SDWA represents a VOP2 instruction with sub-dword addressing.
*
* (*) The same is applicable for VOP1 and VOPC instructions.
*/
enum class Format : std::uint16_t {
/* Pseudo Instruction Format */
PSEUDO = 0,
/* Scalar ALU & Control Formats */
SOP1 = 1,
SOP2 = 2,
SOPK = 3,
SOPP = 4,
SOPC = 5,
/* Scalar Memory Format */
SMEM = 6,
/* LDS/GDS Format */
DS = 8,
/* Vector Memory Buffer Formats */
MTBUF = 9,
MUBUF = 10,
/* Vector Memory Image Format */
MIMG = 11,
/* Export Format */
EXP = 12,
/* Flat Formats */
FLAT = 13,
GLOBAL = 14,
SCRATCH = 15,
PSEUDO_BRANCH = 16,
PSEUDO_BARRIER = 17,
PSEUDO_REDUCTION = 18,
/* Vector ALU Formats */
VOP1 = 1 << 8,
VOP2 = 1 << 9,
VOPC = 1 << 10,
VOP3 = 1 << 11,
VOP3A = 1 << 11,
VOP3B = 1 << 11,
VOP3P = 1 << 12,
/* Vector Parameter Interpolation Format */
VINTRP = 1 << 13,
DPP = 1 << 14,
SDWA = 1 << 15,
};
enum barrier_interaction {
barrier_none = 0,
barrier_buffer = 0x1,
barrier_image = 0x2,
barrier_atomic = 0x4,
barrier_shared = 0x8,
barrier_count = 4,
};
constexpr Format asVOP3(Format format) {
return (Format) ((uint32_t) Format::VOP3 | (uint32_t) format);
};
enum class RegType {
none = 0,
sgpr,
vgpr,
linear_vgpr,
};
struct RegClass {
enum RC : uint8_t {
s1 = 1,
s2 = 2,
s3 = 3,
s4 = 4,
s6 = 6,
s8 = 8,
s16 = 16,
v1 = s1 | (1 << 5),
v2 = s2 | (1 << 5),
v3 = s3 | (1 << 5),
v4 = s4 | (1 << 5),
v5 = 5 | (1 << 5),
v6 = 6 | (1 << 5),
v7 = 7 | (1 << 5),
v8 = 8 | (1 << 5),
/* these are used for WWM and spills to vgpr */
v1_linear = v1 | (1 << 6),
v2_linear = v2 | (1 << 6),
};
RegClass() = default;
constexpr RegClass(RC rc)
: rc(rc) {}
constexpr RegClass(RegType type, unsigned size)
: rc((RC) ((type == RegType::vgpr ? 1 << 5 : 0) | size)) {}
constexpr operator RC() const { return rc; }
explicit operator bool() = delete;
constexpr RegType type() const { return rc <= RC::s16 ? RegType::sgpr : RegType::vgpr; }
constexpr unsigned size() const { return (unsigned) rc & 0x1F; }
constexpr bool is_linear() const { return rc <= RC::s16 || rc & (1 << 6); }
constexpr RegClass as_linear() const { return RegClass((RC) (rc | (1 << 6))); }
private:
RC rc;
};
/* transitional helper expressions */
static constexpr RegClass s1{RegClass::s1};
static constexpr RegClass s2{RegClass::s2};
static constexpr RegClass s3{RegClass::s3};
static constexpr RegClass s4{RegClass::s4};
static constexpr RegClass s8{RegClass::s8};
static constexpr RegClass s16{RegClass::s16};
static constexpr RegClass v1{RegClass::v1};
static constexpr RegClass v2{RegClass::v2};
static constexpr RegClass v3{RegClass::v3};
static constexpr RegClass v4{RegClass::v4};
static constexpr RegClass v5{RegClass::v5};
static constexpr RegClass v6{RegClass::v6};
static constexpr RegClass v7{RegClass::v7};
static constexpr RegClass v8{RegClass::v8};
/**
* Temp Class
* Each temporary virtual register has a
* register class (i.e. size and type)
* and SSA id.
*/
struct Temp {
Temp() = default;
constexpr Temp(uint32_t id, RegClass cls) noexcept
: id_(id), reg_class(cls) {}
constexpr uint32_t id() const noexcept { return id_; }
constexpr RegClass regClass() const noexcept { return reg_class; }
constexpr unsigned size() const noexcept { return reg_class.size(); }
constexpr RegType type() const noexcept { return reg_class.type(); }
constexpr bool is_linear() const noexcept { return reg_class.is_linear(); }
constexpr bool operator <(Temp other) const noexcept { return id() < other.id(); }
constexpr bool operator==(Temp other) const noexcept { return id() == other.id(); }
constexpr bool operator!=(Temp other) const noexcept { return id() != other.id(); }
private:
uint32_t id_:24;
RegClass reg_class;
};
/**
* PhysReg
* Represents the physical register for each
* Operand and Definition.
*/
struct PhysReg {
constexpr PhysReg() = default;
explicit constexpr PhysReg(unsigned r) : reg(r) {}
constexpr operator unsigned() const { return reg; }
uint16_t reg = 0;
};
/* helper expressions for special registers */
static constexpr PhysReg m0{124};
static constexpr PhysReg vcc{106};
static constexpr PhysReg sgpr_null{125}; /* GFX10+ */
static constexpr PhysReg exec{126};
static constexpr PhysReg exec_lo{126};
static constexpr PhysReg exec_hi{127};
static constexpr PhysReg scc{253};
/**
* Operand Class
* Initially, each Operand refers to either
* a temporary virtual register
* or to a constant value
* Temporary registers get mapped to physical register during RA
* Constant values are inlined into the instruction sequence.
*/
class Operand final
{
public:
constexpr Operand()
: reg_(PhysReg{128}), isTemp_(false), isFixed_(true), isConstant_(false),
isKill_(false), isUndef_(true), isFirstKill_(false), is64BitConst_(false) {}
explicit Operand(Temp r) noexcept
{
data_.temp = r;
if (r.id()) {
isTemp_ = true;
} else {
isUndef_ = true;
setFixed(PhysReg{128});
}
};
explicit Operand(uint32_t v) noexcept
{
data_.i = v;
isConstant_ = true;
if (v <= 64)
setFixed(PhysReg{128 + v});
else if (v >= 0xFFFFFFF0) /* [-16 .. -1] */
setFixed(PhysReg{192 - v});
else if (v == 0x3f000000) /* 0.5 */
setFixed(PhysReg{240});
else if (v == 0xbf000000) /* -0.5 */
setFixed(PhysReg{241});
else if (v == 0x3f800000) /* 1.0 */
setFixed(PhysReg{242});
else if (v == 0xbf800000) /* -1.0 */
setFixed(PhysReg{243});
else if (v == 0x40000000) /* 2.0 */
setFixed(PhysReg{244});
else if (v == 0xc0000000) /* -2.0 */
setFixed(PhysReg{245});
else if (v == 0x40800000) /* 4.0 */
setFixed(PhysReg{246});
else if (v == 0xc0800000) /* -4.0 */
setFixed(PhysReg{247});
else if (v == 0x3e22f983) /* 1/(2*PI) */
setFixed(PhysReg{248});
else /* Literal Constant */
setFixed(PhysReg{255});
};
explicit Operand(uint64_t v) noexcept
{
isConstant_ = true;
is64BitConst_ = true;
if (v <= 64)
setFixed(PhysReg{128 + (uint32_t) v});
else if (v >= 0xFFFFFFFFFFFFFFF0) /* [-16 .. -1] */
setFixed(PhysReg{192 - (uint32_t) v});
else if (v == 0x3FE0000000000000) /* 0.5 */
setFixed(PhysReg{240});
else if (v == 0xBFE0000000000000) /* -0.5 */
setFixed(PhysReg{241});
else if (v == 0x3FF0000000000000) /* 1.0 */
setFixed(PhysReg{242});
else if (v == 0xBFF0000000000000) /* -1.0 */
setFixed(PhysReg{243});
else if (v == 0x4000000000000000) /* 2.0 */
setFixed(PhysReg{244});
else if (v == 0xC000000000000000) /* -2.0 */
setFixed(PhysReg{245});
else if (v == 0x4010000000000000) /* 4.0 */
setFixed(PhysReg{246});
else if (v == 0xC010000000000000) /* -4.0 */
setFixed(PhysReg{247});
else if (v == 0x3fc45f306dc9c882) /* 1/(2*PI) */
setFixed(PhysReg{248});
else { /* Literal Constant: we don't know if it is a long or double.*/
isConstant_ = 0;
assert(false && "attempt to create a 64-bit literal constant");
}
};
explicit Operand(RegClass type) noexcept
{
isUndef_ = true;
data_.temp = Temp(0, type);
setFixed(PhysReg{128});
};
explicit Operand(PhysReg reg, RegClass type) noexcept
{
data_.temp = Temp(0, type);
setFixed(reg);
}
constexpr bool isTemp() const noexcept
{
return isTemp_;
}
constexpr void setTemp(Temp t) noexcept {
assert(!isConstant_);
isTemp_ = true;
data_.temp = t;
}
constexpr Temp getTemp() const noexcept
{
return data_.temp;
}
constexpr uint32_t tempId() const noexcept
{
return data_.temp.id();
}
constexpr bool hasRegClass() const noexcept
{
return isTemp() || isUndefined();
}
constexpr RegClass regClass() const noexcept
{
return data_.temp.regClass();
}
constexpr unsigned size() const noexcept
{
if (isConstant())
return is64BitConst_ ? 2 : 1;
else
return data_.temp.size();
}
constexpr bool isFixed() const noexcept
{
return isFixed_;
}
constexpr PhysReg physReg() const noexcept
{
return reg_;
}
constexpr void setFixed(PhysReg reg) noexcept
{
isFixed_ = reg != unsigned(-1);
reg_ = reg;
}
constexpr bool isConstant() const noexcept
{
return isConstant_;
}
constexpr bool isLiteral() const noexcept
{
return isConstant() && reg_ == 255;
}
constexpr bool isUndefined() const noexcept
{
return isUndef_;
}
constexpr uint32_t constantValue() const noexcept
{
return data_.i;
}
constexpr bool constantEquals(uint32_t cmp) const noexcept
{
return isConstant() && constantValue() == cmp;
}
constexpr void setKill(bool flag) noexcept
{
isKill_ = flag;
if (!flag)
setFirstKill(false);
}
constexpr bool isKill() const noexcept
{
return isKill_ || isFirstKill();
}
constexpr void setFirstKill(bool flag) noexcept
{
isFirstKill_ = flag;
if (flag)
setKill(flag);
}
/* When there are multiple operands killing the same temporary,
* isFirstKill() is only returns true for the first one. */
constexpr bool isFirstKill() const noexcept
{
return isFirstKill_;
}
private:
union {
uint32_t i;
float f;
Temp temp = Temp(0, s1);
} data_;
PhysReg reg_;
union {
struct {
uint8_t isTemp_:1;
uint8_t isFixed_:1;
uint8_t isConstant_:1;
uint8_t isKill_:1;
uint8_t isUndef_:1;
uint8_t isFirstKill_:1;
uint8_t is64BitConst_:1;
};
/* can't initialize bit-fields in c++11, so work around using a union */
uint8_t control_ = 0;
};
};
/**
* Definition Class
* Definitions are the results of Instructions
* and refer to temporary virtual registers
* which are later mapped to physical registers
*/
class Definition final
{
public:
constexpr Definition() : temp(Temp(0, s1)), reg_(0), isFixed_(0), hasHint_(0), isKill_(0) {}
Definition(uint32_t index, RegClass type) noexcept
: temp(index, type) {}
explicit Definition(Temp tmp) noexcept
: temp(tmp) {}
Definition(PhysReg reg, RegClass type) noexcept
: temp(Temp(0, type))
{
setFixed(reg);
}
Definition(uint32_t tmpId, PhysReg reg, RegClass type) noexcept
: temp(Temp(tmpId, type))
{
setFixed(reg);
}
constexpr bool isTemp() const noexcept
{
return tempId() > 0;
}
constexpr Temp getTemp() const noexcept
{
return temp;
}
constexpr uint32_t tempId() const noexcept
{
return temp.id();
}
constexpr void setTemp(Temp t) noexcept {
temp = t;
}
constexpr RegClass regClass() const noexcept
{
return temp.regClass();
}
constexpr unsigned size() const noexcept
{
return temp.size();
}
constexpr bool isFixed() const noexcept
{
return isFixed_;
}
constexpr PhysReg physReg() const noexcept
{
return reg_;
}
constexpr void setFixed(PhysReg reg) noexcept
{
isFixed_ = 1;
reg_ = reg;
}
constexpr void setHint(PhysReg reg) noexcept
{
hasHint_ = 1;
reg_ = reg;
}
constexpr bool hasHint() const noexcept
{
return hasHint_;
}
constexpr void setKill(bool flag) noexcept
{
isKill_ = flag;
}
constexpr bool isKill() const noexcept
{
return isKill_;
}
private:
Temp temp = Temp(0, s1);
PhysReg reg_;
union {
struct {
uint8_t isFixed_:1;
uint8_t hasHint_:1;
uint8_t isKill_:1;
};
/* can't initialize bit-fields in c++11, so work around using a union */
uint8_t control_ = 0;
};
};
class Block;
struct Instruction {
aco_opcode opcode;
Format format;
uint32_t pass_flags;
aco::span<Operand> operands;
aco::span<Definition> definitions;
constexpr bool isVALU() const noexcept
{
return ((uint16_t) format & (uint16_t) Format::VOP1) == (uint16_t) Format::VOP1
|| ((uint16_t) format & (uint16_t) Format::VOP2) == (uint16_t) Format::VOP2
|| ((uint16_t) format & (uint16_t) Format::VOPC) == (uint16_t) Format::VOPC
|| ((uint16_t) format & (uint16_t) Format::VOP3A) == (uint16_t) Format::VOP3A
|| ((uint16_t) format & (uint16_t) Format::VOP3B) == (uint16_t) Format::VOP3B
|| ((uint16_t) format & (uint16_t) Format::VOP3P) == (uint16_t) Format::VOP3P;
}
constexpr bool isSALU() const noexcept
{
return format == Format::SOP1 ||
format == Format::SOP2 ||
format == Format::SOPC ||
format == Format::SOPK ||
format == Format::SOPP;
}
constexpr bool isVMEM() const noexcept
{
return format == Format::MTBUF ||
format == Format::MUBUF ||
format == Format::MIMG;
}
constexpr bool isDPP() const noexcept
{
return (uint16_t) format & (uint16_t) Format::DPP;
}
constexpr bool isVOP3() const noexcept
{
return ((uint16_t) format & (uint16_t) Format::VOP3A) ||
((uint16_t) format & (uint16_t) Format::VOP3B) ||
format == Format::VOP3P;
}
constexpr bool isSDWA() const noexcept
{
return (uint16_t) format & (uint16_t) Format::SDWA;
}
constexpr bool isFlatOrGlobal() const noexcept
{
return format == Format::FLAT || format == Format::GLOBAL;
}
};
struct SOPK_instruction : public Instruction {
uint16_t imm;
};
struct SOPP_instruction : public Instruction {
uint32_t imm;
int block;
};
struct SOPC_instruction : public Instruction {
};
struct SOP1_instruction : public Instruction {
};
struct SOP2_instruction : public Instruction {
};
/**
* Scalar Memory Format:
* For s_(buffer_)load_dword*:
* Operand(0): SBASE - SGPR-pair which provides base address
* Operand(1): Offset - immediate (un)signed offset or SGPR
* Operand(2) / Definition(0): SDATA - SGPR for read / write result
* Operand(n-1): SOffset - SGPR offset (Vega only)
*
* Having no operands is also valid for instructions such as s_dcache_inv.
*
*/
struct SMEM_instruction : public Instruction {
bool glc; /* VI+: globally coherent */
bool dlc; /* NAVI: device level coherent */
bool nv; /* VEGA only: Non-volatile */
bool can_reorder;
bool disable_wqm;
barrier_interaction barrier;
};
struct VOP1_instruction : public Instruction {
};
struct VOP2_instruction : public Instruction {
};
struct VOPC_instruction : public Instruction {
};
struct VOP3A_instruction : public Instruction {
bool abs[3];
bool opsel[4];
bool clamp;
unsigned omod;
bool neg[3];
};
/**
* Data Parallel Primitives Format:
* This format can be used for VOP1, VOP2 or VOPC instructions.
* The swizzle applies to the src0 operand.
*
*/
struct DPP_instruction : public Instruction {
uint16_t dpp_ctrl;
uint8_t row_mask;
uint8_t bank_mask;
bool abs[2];
bool neg[2];
bool bound_ctrl;
};
struct Interp_instruction : public Instruction {
unsigned attribute;
unsigned component;
};
/**
* Local and Global Data Sharing instructions
* Operand(0): ADDR - VGPR which supplies the address.
* Operand(1): DATA0 - First data VGPR.
* Operand(2): DATA1 - Second data VGPR.
* Operand(n-1): M0 - LDS size.
* Definition(0): VDST - Destination VGPR when results returned to VGPRs.
*
*/
struct DS_instruction : public Instruction {
int16_t offset0;
int8_t offset1;
bool gds;
};
/**
* Vector Memory Untyped-buffer Instructions
* Operand(0): VADDR - Address source. Can carry an index and/or offset
* Operand(1): SRSRC - Specifies which SGPR supplies T# (resource constant)
* Operand(2): SOFFSET - SGPR to supply unsigned byte offset. (SGPR, M0, or inline constant)
* Operand(3) / Definition(0): VDATA - Vector GPR for write result / read data
*
*/
struct MUBUF_instruction : public Instruction {
unsigned offset; /* Unsigned byte offset - 12 bit */
bool offen; /* Supply an offset from VGPR (VADDR) */
bool idxen; /* Supply an index from VGPR (VADDR) */
bool glc; /* globally coherent */
bool dlc; /* NAVI: device level coherent */
bool slc; /* system level coherent */
bool tfe; /* texture fail enable */
bool lds; /* Return read-data to LDS instead of VGPRs */
bool disable_wqm; /* Require an exec mask without helper invocations */
bool can_reorder;
barrier_interaction barrier;
};
/**
* Vector Memory Typed-buffer Instructions
* Operand(0): VADDR - Address source. Can carry an index and/or offset
* Operand(1): SRSRC - Specifies which SGPR supplies T# (resource constant)
* Operand(2): SOFFSET - SGPR to supply unsigned byte offset. (SGPR, M0, or inline constant)
* Operand(3) / Definition(0): VDATA - Vector GPR for write result / read data
*
*/
struct MTBUF_instruction : public Instruction {
uint8_t dfmt : 4; /* Data Format of data in memory buffer */
uint8_t nfmt : 3; /* Numeric format of data in memory */
unsigned offset; /* Unsigned byte offset - 12 bit */
bool offen; /* Supply an offset from VGPR (VADDR) */
bool idxen; /* Supply an index from VGPR (VADDR) */
bool glc; /* globally coherent */
bool dlc; /* NAVI: device level coherent */
bool slc; /* system level coherent */
bool tfe; /* texture fail enable */
bool disable_wqm; /* Require an exec mask without helper invocations */
bool can_reorder;
barrier_interaction barrier;
};
/**
* Vector Memory Image Instructions
* Operand(0): VADDR - Address source. Can carry an offset or an index.
* Operand(1): SRSRC - Scalar GPR that specifies the resource constant.
* Operand(2): SSAMP - Scalar GPR that specifies sampler constant.
* Operand(3) / Definition(0): VDATA - Vector GPR for read / write result.
*
*/
struct MIMG_instruction : public Instruction {
unsigned dmask; /* Data VGPR enable mask */
unsigned dim; /* NAVI: dimensionality */
bool unrm; /* Force address to be un-normalized */
bool dlc; /* NAVI: device level coherent */
bool glc; /* globally coherent */
bool slc; /* system level coherent */
bool tfe; /* texture fail enable */
bool da; /* declare an array */
bool lwe; /* Force data to be un-normalized */
bool r128; /* NAVI: Texture resource size */
bool a16; /* VEGA, NAVI: Address components are 16-bits */
bool d16; /* Convert 32-bit data to 16-bit data */
bool disable_wqm; /* Require an exec mask without helper invocations */
bool can_reorder;
barrier_interaction barrier;
};
/**
* Flat/Scratch/Global Instructions
* Operand(0): ADDR
* Operand(1): SADDR
* Operand(2) / Definition(0): DATA/VDST
*
*/
struct FLAT_instruction : public Instruction {
uint16_t offset; /* Vega only */
bool slc; /* system level coherent */
bool glc; /* globally coherent */
bool dlc; /* NAVI: device level coherent */
bool lds;
bool nv;
};
struct Export_instruction : public Instruction {
unsigned enabled_mask;
unsigned dest;
bool compressed;
bool done;
bool valid_mask;
};
struct Pseudo_instruction : public Instruction {
bool tmp_in_scc;
PhysReg scratch_sgpr; /* might not be valid if it's not needed */
};
struct Pseudo_branch_instruction : public Instruction {
/* target[0] is the block index of the branch target.
* For conditional branches, target[1] contains the fall-through alternative.
* A value of 0 means the target has not been initialized (BB0 cannot be a branch target).
*/
uint32_t target[2];
};
struct Pseudo_barrier_instruction : public Instruction {
};
enum ReduceOp {
iadd32, iadd64,
imul32, imul64,
fadd32, fadd64,
fmul32, fmul64,
imin32, imin64,
imax32, imax64,
umin32, umin64,
umax32, umax64,
fmin32, fmin64,
fmax32, fmax64,
iand32, iand64,
ior32, ior64,
ixor32, ixor64,
gfx10_wave64_bpermute
};
/**
* Subgroup Reduction Instructions, everything except for the data to be
* reduced and the result as inserted by setup_reduce_temp().
* Operand(0): data to be reduced
* Operand(1): reduce temporary
* Operand(2): vector temporary
* Definition(0): result
* Definition(1): scalar temporary
* Definition(2): scalar identity temporary (not used to store identity on GFX10)
* Definition(3): scc clobber
* Definition(4): vcc clobber
*
*/
struct Pseudo_reduction_instruction : public Instruction {
ReduceOp reduce_op;
unsigned cluster_size; // must be 0 for scans
};
struct instr_deleter_functor {
void operator()(void* p) {
free(p);
}
};
template<typename T>
using aco_ptr = std::unique_ptr<T, instr_deleter_functor>;
template<typename T>
T* create_instruction(aco_opcode opcode, Format format, uint32_t num_operands, uint32_t num_definitions)
{
std::size_t size = sizeof(T) + num_operands * sizeof(Operand) + num_definitions * sizeof(Definition);
char *data = (char*) calloc(1, size);
T* inst = (T*) data;
inst->opcode = opcode;
inst->format = format;
inst->operands = aco::span<Operand>((Operand*)(data + sizeof(T)), num_operands);
inst->definitions = aco::span<Definition>((Definition*)inst->operands.end(), num_definitions);
return inst;
}
constexpr bool is_phi(Instruction* instr)
{
return instr->opcode == aco_opcode::p_phi || instr->opcode == aco_opcode::p_linear_phi;
}
static inline bool is_phi(aco_ptr<Instruction>& instr)
{
return is_phi(instr.get());
}
constexpr barrier_interaction get_barrier_interaction(Instruction* instr)
{
switch (instr->format) {
case Format::SMEM:
return static_cast<SMEM_instruction*>(instr)->barrier;
case Format::MUBUF:
return static_cast<MUBUF_instruction*>(instr)->barrier;
case Format::MIMG:
return static_cast<MIMG_instruction*>(instr)->barrier;
case Format::FLAT:
case Format::GLOBAL:
return barrier_buffer;
case Format::DS:
return barrier_shared;
default:
return barrier_none;
}
}
enum block_kind {
/* uniform indicates that leaving this block,
* all actives lanes stay active */
block_kind_uniform = 1 << 0,
block_kind_top_level = 1 << 1,
block_kind_loop_preheader = 1 << 2,
block_kind_loop_header = 1 << 3,
block_kind_loop_exit = 1 << 4,
block_kind_continue = 1 << 5,
block_kind_break = 1 << 6,
block_kind_continue_or_break = 1 << 7,
block_kind_discard = 1 << 8,
block_kind_branch = 1 << 9,
block_kind_merge = 1 << 10,
block_kind_invert = 1 << 11,
block_kind_uses_discard_if = 1 << 12,
block_kind_needs_lowering = 1 << 13,
block_kind_uses_demote = 1 << 14,
};
struct RegisterDemand {
constexpr RegisterDemand() = default;
constexpr RegisterDemand(const int16_t v, const int16_t s) noexcept
: vgpr{v}, sgpr{s} {}
int16_t vgpr = 0;
int16_t sgpr = 0;
constexpr friend bool operator==(const RegisterDemand a, const RegisterDemand b) noexcept {
return a.vgpr == b.vgpr && a.sgpr == b.sgpr;
}
constexpr bool exceeds(const RegisterDemand other) const noexcept {
return vgpr > other.vgpr || sgpr > other.sgpr;
}
constexpr RegisterDemand operator+(const Temp t) const noexcept {
if (t.type() == RegType::sgpr)
return RegisterDemand( vgpr, sgpr + t.size() );
else
return RegisterDemand( vgpr + t.size(), sgpr );
}
constexpr RegisterDemand operator+(const RegisterDemand other) const noexcept {
return RegisterDemand(vgpr + other.vgpr, sgpr + other.sgpr);
}
constexpr RegisterDemand operator-(const RegisterDemand other) const noexcept {
return RegisterDemand(vgpr - other.vgpr, sgpr - other.sgpr);
}
constexpr RegisterDemand& operator+=(const RegisterDemand other) noexcept {
vgpr += other.vgpr;
sgpr += other.sgpr;
return *this;
}
constexpr RegisterDemand& operator-=(const RegisterDemand other) noexcept {
vgpr -= other.vgpr;
sgpr -= other.sgpr;
return *this;
}
constexpr RegisterDemand& operator+=(const Temp t) noexcept {
if (t.type() == RegType::sgpr)
sgpr += t.size();
else
vgpr += t.size();
return *this;
}
constexpr RegisterDemand& operator-=(const Temp t) noexcept {
if (t.type() == RegType::sgpr)
sgpr -= t.size();
else
vgpr -= t.size();
return *this;
}
constexpr void update(const RegisterDemand other) noexcept {
vgpr = std::max(vgpr, other.vgpr);
sgpr = std::max(sgpr, other.sgpr);
}
};
/* CFG */
struct Block {
unsigned index;
unsigned offset = 0;
std::vector<aco_ptr<Instruction>> instructions;
std::vector<unsigned> logical_preds;
std::vector<unsigned> linear_preds;
std::vector<unsigned> logical_succs;
std::vector<unsigned> linear_succs;
RegisterDemand register_demand = RegisterDemand();
uint16_t loop_nest_depth = 0;
uint16_t kind = 0;
int logical_idom = -1;
int linear_idom = -1;
Temp live_out_exec = Temp();
/* this information is needed for predecessors to blocks with phis when
* moving out of ssa */
bool scc_live_out = false;
PhysReg scratch_sgpr = PhysReg(); /* only needs to be valid if scc_live_out != false */
Block(unsigned idx) : index(idx) {}
Block() : index(0) {}
};
using Stage = uint16_t;
/* software stages */
static constexpr Stage sw_vs = 1 << 0;
static constexpr Stage sw_gs = 1 << 1;
static constexpr Stage sw_tcs = 1 << 2;
static constexpr Stage sw_tes = 1 << 3;
static constexpr Stage sw_fs = 1 << 4;
static constexpr Stage sw_cs = 1 << 5;
static constexpr Stage sw_mask = 0x3f;
/* hardware stages (can't be OR'd, just a mask for convenience when testing multiple) */
static constexpr Stage hw_vs = 1 << 6;
static constexpr Stage hw_es = 1 << 7; /* not on GFX9. combined into GS on GFX9 (and GFX10/legacy). */
static constexpr Stage hw_gs = 1 << 8;
static constexpr Stage hw_ls = 1 << 9; /* not on GFX9. combined into HS on GFX9 (and GFX10/legacy). */
static constexpr Stage hw_hs = 1 << 10;
static constexpr Stage hw_fs = 1 << 11;
static constexpr Stage hw_cs = 1 << 12;
static constexpr Stage hw_mask = 0x7f << 6;
/* possible settings of Program::stage */
static constexpr Stage vertex_vs = sw_vs | hw_vs;
static constexpr Stage fragment_fs = sw_fs | hw_fs;
static constexpr Stage compute_cs = sw_cs | hw_cs;
static constexpr Stage tess_eval_vs = sw_tes | hw_vs;
/* GFX10/NGG */
static constexpr Stage ngg_vertex_gs = sw_vs | hw_gs;
static constexpr Stage ngg_vertex_geometry_gs = sw_vs | sw_gs | hw_gs;
static constexpr Stage ngg_tess_eval_geometry_gs = sw_tes | sw_gs | hw_gs;
static constexpr Stage ngg_vertex_tess_control_hs = sw_vs | sw_tcs | hw_hs;
/* GFX9 (and GFX10 if NGG isn't used) */
static constexpr Stage vertex_geometry_gs = sw_vs | sw_gs | hw_gs;
static constexpr Stage vertex_tess_control_hs = sw_vs | sw_tcs | hw_hs;
static constexpr Stage tess_eval_geometry_gs = sw_tes | sw_gs | hw_gs;
/* pre-GFX9 */
static constexpr Stage vertex_ls = sw_vs | hw_ls; /* vertex before tesselation control */
static constexpr Stage vertex_es = sw_vs | hw_es; /* vertex before geometry */
static constexpr Stage tess_control_hs = sw_tcs | hw_hs;
static constexpr Stage tess_eval_es = sw_tes | hw_gs; /* tesselation evaluation before geometry */
static constexpr Stage geometry_gs = sw_gs | hw_gs;
class Program final {
public:
std::vector<Block> blocks;
RegisterDemand max_reg_demand = RegisterDemand();
uint16_t num_waves = 0;
uint16_t max_waves = 0; /* maximum number of waves, regardless of register usage */
ac_shader_config* config;
struct radv_shader_info *info;
enum chip_class chip_class;
enum radeon_family family;
unsigned wave_size;
Stage stage; /* Stage */
bool needs_exact = false; /* there exists an instruction with disable_wqm = true */
bool needs_wqm = false; /* there exists a p_wqm instruction */
bool wb_smem_l1_on_end = false;
std::vector<uint8_t> constant_data;
uint16_t lds_alloc_granule;
uint32_t lds_limit; /* in bytes */
uint16_t vgpr_limit;
uint16_t physical_sgprs;
uint16_t sgpr_alloc_granule; /* minus one. must be power of two */
uint16_t sgpr_limit;
bool needs_vcc = false;
bool needs_xnack_mask = false;
bool needs_flat_scr = false;
uint32_t allocateId()
{
assert(allocationID <= 16777215);
return allocationID++;
}
uint32_t peekAllocationId()
{
return allocationID;
}
void setAllocationId(uint32_t id)
{
allocationID = id;
}
Block* create_and_insert_block() {
blocks.emplace_back(blocks.size());
return &blocks.back();
}
Block* insert_block(Block&& block) {
block.index = blocks.size();
blocks.emplace_back(std::move(block));
return &blocks.back();
}
private:
uint32_t allocationID = 1;
};
struct live {
/* live temps out per block */
std::vector<std::set<Temp>> live_out;
/* register demand (sgpr/vgpr) per instruction per block */
std::vector<std::vector<RegisterDemand>> register_demand;
};
void select_program(Program *program,
unsigned shader_count,
struct nir_shader *const *shaders,
ac_shader_config* config,
struct radv_shader_info *info,
struct radv_nir_compiler_options *options);
void lower_wqm(Program* program, live& live_vars,
const struct radv_nir_compiler_options *options);
void lower_bool_phis(Program* program);
void update_vgpr_sgpr_demand(Program* program, const RegisterDemand new_demand);
live live_var_analysis(Program* program, const struct radv_nir_compiler_options *options);
std::vector<uint16_t> dead_code_analysis(Program *program);
void dominator_tree(Program* program);
void insert_exec_mask(Program *program);
void value_numbering(Program* program);
void optimize(Program* program);
void setup_reduce_temp(Program* program);
void lower_to_cssa(Program* program, live& live_vars, const struct radv_nir_compiler_options *options);
void register_allocation(Program *program, std::vector<std::set<Temp>> live_out_per_block);
void ssa_elimination(Program* program);
void lower_to_hw_instr(Program* program);
void schedule_program(Program* program, live& live_vars);
void spill(Program* program, live& live_vars, const struct radv_nir_compiler_options *options);
void insert_wait_states(Program* program);
void insert_NOPs(Program* program);
unsigned emit_program(Program* program, std::vector<uint32_t>& code);
void print_asm(Program *program, std::vector<uint32_t>& binary,
unsigned exec_size, std::ostream& out);
void validate(Program* program, FILE *output);
bool validate_ra(Program* program, const struct radv_nir_compiler_options *options, FILE *output);
#ifndef NDEBUG
void perfwarn(bool cond, const char *msg, Instruction *instr=NULL);
#else
#define perfwarn(program, cond, msg, ...)
#endif
void aco_print_instr(Instruction *instr, FILE *output);
void aco_print_program(Program *program, FILE *output);
/* number of sgprs that need to be allocated but might notbe addressable as s0-s105 */
uint16_t get_extra_sgprs(Program *program);
/* get number of sgprs allocated required to address a number of sgprs */
uint16_t get_sgpr_alloc(Program *program, uint16_t addressable_sgprs);
/* return number of addressable SGPRs for max_waves */
uint16_t get_addr_sgpr_from_waves(Program *program, uint16_t max_waves);
typedef struct {
const int16_t opcode_gfx9[static_cast<int>(aco_opcode::num_opcodes)];
const int16_t opcode_gfx10[static_cast<int>(aco_opcode::num_opcodes)];
const std::bitset<static_cast<int>(aco_opcode::num_opcodes)> can_use_input_modifiers;
const std::bitset<static_cast<int>(aco_opcode::num_opcodes)> can_use_output_modifiers;
const char *name[static_cast<int>(aco_opcode::num_opcodes)];
const aco::Format format[static_cast<int>(aco_opcode::num_opcodes)];
} Info;
extern const Info instr_info;
}
#endif /* ACO_IR_H */
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