https://github.com/halide/Halide
Tip revision: 22d5a94c4bc12ee26820c8f2f30c7bcc55410021 authored by Volodymyr Kysenko on 10 June 2019, 19:33:51 UTC
Increase thread priority whenever halide_hexagon_remote_poll_profiler_state is called
Increase thread priority whenever halide_hexagon_remote_poll_profiler_state is called
Tip revision: 22d5a94
CodeGen_D3D12Compute_Dev.cpp
#include <sstream>
#include <algorithm>
#include <iomanip>
#include "CodeGen_D3D12Compute_Dev.h"
#include "CodeGen_Internal.h"
#include "Debug.h"
#include "IROperator.h"
#include "IRMutator.h"
#define DEBUG_TYPES (0)
namespace Halide {
namespace Internal {
using std::ostringstream;
using std::string;
using std::vector;
using std::sort;
static ostringstream nil;
CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_Dev(Target t) :
d3d12compute_c(src_stream, t) {
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_type_maybe_storage(Type type, bool storage, AppendSpaceIfNeeded space) {
ostringstream oss;
// Storage uses packed vector types.
if (storage && type.lanes() != 1) {
// NOTE(marcos): HLSL has 'packoffset' but it only applies to constant
// buffer fields (constant registers (c)); because constant arguments
// are always converted to 32bit values by the runtime prior to kernel
// dispatch, there is no need to complicate things with packoffset.
}
if (type.is_float()) {
switch (type.bits()) {
case 16:
// 16-bit floating point value. This data type is provided only for language compatibility.
// Direct3D 10 shader targets map all half data types to float data types.
// A half data type cannot be used on a uniform global variable (use the /Gec flag if this functionality is desired).
oss << "half";
break;
case 32:
oss << "float";
break;
case 64:
// "64-bit floating point value. You cannot use double precision values as inputs and outputs for a stream.
// To pass double precision values between shaders, declare each double as a pair of uint data types.
// Then, use the asdouble function to pack each double into the pair of uints and the asuint function to
// unpack the pair of uints back into the double."
user_error << "HLSL (SM 5.1) does not have transparent support for 'double' types.\n";
oss << "double";
break;
default:
user_error << "Can't represent a float with this many bits in HLSL (SM 5.1): " << type << "\n";
}
} else {
switch (type.bits()) {
case 1:
oss << "bool";
break;
case 8:
case 16:
case 32:
if (type.is_uint()) oss << 'u';
oss << "int";
#if DEBUG_TYPES
oss << type.bits();
#endif
break;
case 64:
user_error << "HLSL (SM 5.1) does not support 64-bit integers.\n";
break;
default:
user_error << "Can't represent an integer with this many bits in HLSL (SM 5.1): " << type << "\n";
}
}
switch (type.lanes()) {
case 1:
break;
case 2:
case 3:
case 4:
#if DEBUG_TYPES
oss << "_(";
#endif
oss << type.lanes();
#if DEBUG_TYPES
oss << ")";
#endif
break;
case 8:
case 16:
// TODO(marcos): are there 8-wide and 16-wide types in HLSL?
// (CodeGen_GLSLBase seems to happily generate invalid vector types)
default:
user_error << "Unsupported vector width in HLSL (SM 5.1): " << type << "\n";
}
if (space == AppendSpace) {
oss << ' ';
}
return oss.str();
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_type(Type type, AppendSpaceIfNeeded space) {
return print_type_maybe_storage(type, false, space);
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_storage_type(Type type) {
return print_type_maybe_storage(type, true, DoNotAppendSpace);
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_reinterpret(Type type, Expr e)
{
return print_reinterpret_cast(type, print_expr(e));
}
namespace {
string simt_intrinsic(const string &name) {
if (ends_with(name, ".__thread_id_x")) {
return "tid_in_tgroup.x";
} else if (ends_with(name, ".__thread_id_y")) {
return "tid_in_tgroup.y";
} else if (ends_with(name, ".__thread_id_z")) {
return "tid_in_tgroup.z";
} else if (ends_with(name, ".__thread_id_w")) {
user_error << "HLSL (SM5.1) does not support more than three dimensions for compute kernel threads.\n";
} else if (ends_with(name, ".__block_id_x")) {
return "tgroup_index.x";
} else if (ends_with(name, ".__block_id_y")) {
return "tgroup_index.y";
} else if (ends_with(name, ".__block_id_z")) {
return "tgroup_index.z";
} else if (ends_with(name, ".__block_id_w")) {
user_error << "HLSL (SM5.1) does not support more than three dimensions for compute dispatch groups.\n";
}
internal_error << "simt_intrinsic called on bad variable name: " << name << "\n";
return "";
}
} // namespace
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Evaluate *op) {
if (is_const(op->value)) return;
print_expr(op->value);
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_extern_call(const Call *op) {
internal_assert(!function_takes_user_context(op->name));
vector<string> args(op->args.size());
for (size_t i = 0; i < op->args.size(); i++) {
args[i] = print_expr(op->args[i]);
}
ostringstream rhs;
rhs << op->name << "(" << with_commas(args) << ")";
return rhs.str();
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Max *op) {
print_expr(Call::make(op->type, "max", {op->a, op->b}, Call::Extern));
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Min *op) {
print_expr(Call::make(op->type, "min", {op->a, op->b}, Call::Extern));
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Div *op) {
int bits;
if (is_const_power_of_two_integer(op->b, &bits)) {
ostringstream oss;
oss << print_expr(op->a) << " >> " << bits;
print_assignment(op->type, oss.str());
} else if (op->type.is_int()) {
print_expr(lower_euclidean_div(op->a, op->b));
} else {
visit_binop(op->type, op->a, op->b, "/");
}
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Mod *op) {
int bits;
if (is_const_power_of_two_integer(op->b, &bits)) {
ostringstream oss;
oss << print_expr(op->a) << " & " << ((1 << bits)-1);
print_assignment(op->type, oss.str());
} else if (op->type.is_int()) {
print_expr(lower_euclidean_mod(op->a, op->b));
} else {
visit_binop(op->type, op->a, op->b, "%");
}
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const For *loop)
{
if (!is_gpu_var(loop->name)) {
user_assert(loop->for_type != ForType::Parallel) << "Cannot use parallel loops inside D3D12Compute kernel\n";
CodeGen_C::visit(loop);
return;
}
internal_assert((loop->for_type == ForType::GPUBlock) ||
(loop->for_type == ForType::GPUThread))
<< "kernel loop must be either gpu block or gpu thread\n";
internal_assert(is_zero(loop->min));
do_indent();
stream << print_type(Int(32)) << " " << print_name(loop->name)
<< " = " << simt_intrinsic(loop->name) << ";\n";
loop->body.accept(this);
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Ramp *op) {
ostringstream rhs;
rhs << print_expr(op->base)
<< " + "
<< print_expr(op->stride)
<< " * "
<< print_type(op->type.with_lanes(op->lanes))
<< "(";
rhs << "0";
for (int i = 1; i < op->lanes; ++i) {
rhs << ", " << i;
}
rhs << ")";
print_assignment(op->type.with_lanes(op->lanes), rhs.str());
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Broadcast *op)
{
string id_value = print_expr(op->value);
user_assert(op->value.type().lanes() == 1) << "Broadcast source must be 1-wide.\n";
ostringstream rhs;
rhs << print_type(op->type.with_lanes(op->lanes))
<< "(";
for (int i = 0; i < op->lanes; ++i) {
rhs << id_value;
if (i < op->lanes-1)
rhs << ", ";
}
rhs << ")";
print_assignment(op->type.with_lanes(op->lanes), rhs.str());
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Call *op) {
if (op->is_intrinsic(Call::gpu_thread_barrier)) {
// Halide only ever needs threadgroup memory fences:
// NOTE(marcos): using "WithGroupSync" here just to be safe, as a
// simple "GroupMemoryBarrier" is probably too relaxed for Halide
// (also note we need to return an integer)
do_indent();
stream << "GroupMemoryBarrierWithGroupSync();\n";
print_assignment(op->type, "0");
} else {
CodeGen_C::visit(op);
}
}
namespace {
// If e is a ramp expression with stride 1, return the base, otherwise undefined.
Expr is_ramp_one(Expr e) {
const Ramp *r = e.as<Ramp>();
if (r == nullptr) {
return Expr();
}
if (is_one(r->stride)) {
return r->base;
}
return Expr();
}
template<typename T>
string hex_literal(T value)
{
ostringstream hex;
hex << "0x" << std::uppercase << std::setfill('0') << std::setw(8) << std::hex
<< value;
return hex.str();
}
} // namespace
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Load *op)
{
user_assert(is_one(op->predicate)) << "Predicated load is not supported inside D3D12Compute kernel.\n";
// __shared[x] is always uint(32): must reinterpret/unpack bits...
if (op->name == "__shared") {
ostringstream rhs;
internal_assert(allocations.contains(op->name));
// no ramps when accessing shared memory...
Expr ramp_base = is_ramp_one(op->index);
internal_assert(!ramp_base.defined());
// shared memory in Halide is represented as a byte buffer
// but the 'op->index' is actually in terms of elements...
// to complicate things, HLSL (SM 5.1) only supports 32bit
// words (int/uint/float) as groupshared types...
internal_assert(allocations.get(op->name).type == UInt(8));
internal_assert(op->type.lanes() == 1);
string id_index = print_expr(op->index);
internal_assert(op->type.bits() <= 32);
Type promoted = op->type.with_bits(32);
rhs << "as" << print_type(promoted)
<< "("
<< print_name(op->name)
<< "[" << id_index << "]"
<< ")";
#if 0
// NOTE(marcos): let's keep this block of code here (disabled) in case
// we need to "emulate" byte/short packing in shared memory (recall that
// the smallest type granularity in HLSL SM 5.1 allows is 32bit types):
if (op->type.bits() == 32) {
// loading a 32bit word? great! just reinterpret as float/int/uint
rhs << "as" << print_type(op->type.element_of())
<< "("
<< print_name(op->name)
<< "[" << print_expr(op->index) << "]"
<< ")";
} else {
// not a 32bit word? hell ensues:
internal_assert(op->type.bits() < 32);
// must map element index to uint word array index:
ostringstream index;
auto bits = op->type.bits();
auto divisor = (32 / bits);
auto i = print_expr(op->index);
index << i << " / " << divisor;
ostringstream word;
word << print_name(op->name)
<< "[" + index.str() + "]";
// now mask the appropriate bits:
ostringstream mask;
mask << "("
<< hex_literal((1 << bits) - 1)
<< " << "
<< "(" << bits << "*(" << i << " % " << divisor << " ))"
<< ")";
// extract the correct bits from the word
ostringstream cut;
cut << "("
<< word.str()
<< " & "
<< mask.str()
<< ")"
<< " >> "
<< "(" << bits << "*(" << i << " % " << divisor << " ))";
// if it is signed, need to propagate sign... shift-up then down:
if (op->type.is_int()) {
rhs << "asint"
<< "("
<< cut.str()
<< " << "
<< (32 - bits)
<< ")"
<< " >> "
<< (32 - bits);
} else {
rhs << cut.str();
}
}
#endif
print_assignment(op->type, rhs.str());
return;
}
// If we're loading a contiguous ramp, "unroll" the ramp into loads:
Expr ramp_base = is_ramp_one(op->index);
if (ramp_base.defined()) {
internal_assert(op->type.is_vector());
ostringstream rhs;
rhs << print_type(op->type)
<< "(";
const int lanes = op->type.lanes();
for(int i = 0; i < lanes; ++i) {
rhs << print_name(op->name)
<< "["
<< print_expr(ramp_base)
<< "+" << i
<< "]";
if (i < lanes-1)
rhs << ", ";
}
rhs << ")";
print_assignment(op->type, rhs.str());
return;
}
string id_index = print_expr(op->index);
// Get the rhs just for the cache.
bool type_cast_needed = !(allocations.contains(op->name) &&
allocations.get(op->name).type == op->type);
ostringstream rhs;
if (type_cast_needed) {
ostringstream element;
element << print_name(op->name)
<< "[" << id_index << "]";
Type target_type = op->type;
Type source_type = allocations.get(op->name).type;
rhs << print_cast(target_type, source_type, element.str());
} else {
rhs << print_name(op->name);
rhs << "[" << id_index << "]";
}
std::map<string, string>::iterator cached = cache.find(rhs.str());
if (cached != cache.end()) {
id = cached->second;
return;
}
if (op->index.type().is_vector()) {
// If index is a vector, gather vector elements.
internal_assert(op->type.is_vector());
// This has to be underscore as print_name prepends an underscore to
// names without one and that results in a name mismatch if a Load
// appears as the value of a Let
id = unique_name('_');
cache[rhs.str()] = id;
do_indent();
stream << print_type(op->type)
<< " " << id << ";\n";
for (int i = 0; i < op->type.lanes(); ++i) {
do_indent();
stream << id << "[" << i << "] = "
<< print_type(op->type.element_of())
<< "("
<< print_name(op->name)
<< "[" << id_index << "[" << i << "]]"
<< ");\n";
}
} else {
print_assignment(op->type, rhs.str());
}
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Store *op)
{
user_assert(is_one(op->predicate)) << "Predicated store is not supported inside D3D12Compute kernel.\n";
Type value_type = op->value.type();
// __shared[x] is always uint(32): must reinterpret/pack bits...
if (op->name == "__shared") {
internal_assert(value_type.bits() <= 32);
ostringstream rhs;
rhs << print_name(op->name)
<< "[" << print_expr(op->index) << "]"
<< " = "
<< print_reinterpret(UInt(32), op->value)
<< ";\n";
do_indent();
stream << rhs.str();
#if 0
// NOTE(marcos): let's keep this block of code here (disabled) in case
// we need to "emulate" byte/short packing in shared memory (recall that
// the smallest type granularity in HLSL SM 5.1 allows is 32bit types):
if (value_type.bits() == 32) {
// storing a 32bit word? great! just reinterpret value to uint32:
stream << print_name(op->name)
<< "[" << print_expr(op->index) << "]"
<< " = "
<< print_reinterpret(UInt(32), op->value)
<< ";\n";
} else {
// nightmare:
internal_assert(value_type.bits() < 32);
// must map element index to uint word array index:
ostringstream index;
auto bits = value_type.bits();
auto divisor = (32 / bits);
auto i = print_expr(op->index);
index << i << " / " << divisor;
ostringstream word;
word << print_name(op->name)
<< "[" + index.str() + "]";
// now mask the appropriate bits:
ostringstream mask;
mask << "("
<< hex_literal((1 << bits) - 1)
<< " << "
<< "(" << bits << "*(" << i << " % " << divisor << " ))"
<< ")";
// apply the mask to the rhs value:
ostringstream value;
value << "("
<< mask.str()
<< " & "
<< "(" << print_expr(op->value) << ")"
<< ")";
// the performance impact of atomic operations on shared memory is
// not well documented... here is something:
// https://stackoverflow.com/a/19548723
do_indent();
stream << "InterlockedAnd(" << word.str() << ", " << "~" << mask.str() << ");\n";
do_indent();
stream << "InterlockedXor(" << word.str() << ", " << value.str() << ");\n";
}
#endif
return;
}
// If we're writing a contiguous ramp, "unroll" the ramp into stores:
Expr ramp_base = is_ramp_one(op->index);
if (ramp_base.defined()) {
internal_assert(value_type.is_vector());
int lanes = value_type.lanes();
for (int i = 0; i < lanes; ++i)
{
// TODO(marcos): this indentation looks funny in the generated code
ostringstream rhs;
rhs << print_name(op->name)
<< "["
<< print_expr(ramp_base)
<< " + " << i
<< "]"
<< " = "
<< print_expr(op->value)
<< "["
<< i
<< "]"
<< ";\n";
do_indent();
stream << rhs.str();
}
} else if (op->index.type().is_vector()) {
// If index is a vector, scatter vector elements.
internal_assert(value_type.is_vector());
for (int i = 0; i < value_type.lanes(); ++i) {
ostringstream rhs;
rhs << print_name(op->name)
<< "["
<< print_expr(op->index) << "[" << i << "]"
<< "]"
<< " = "
<< print_expr(op->value) << "[" << i << "];\n";
do_indent();
stream << rhs.str();
}
} else {
ostringstream rhs;
rhs << print_name(op->name)
<< "[" << print_expr(op->index) << "]"
<< " = "
<< print_expr(op->value)
<< ";\n";
do_indent();
stream << rhs.str();
}
cache.clear();
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Select *op) {
ostringstream rhs;
string true_val = print_expr(op->true_value);
string false_val = print_expr(op->false_value);
string cond = print_expr(op->condition);
rhs << print_type(op->type)
<< "(" << cond
<< " ? " << true_val
<< " : " << false_val
<< ")";
print_assignment(op->type, rhs.str());
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Allocate *op) {
if (op->name == "__shared") {
// Already handled
op->body.accept(this);
} else {
open_scope();
debug(2) << "Allocate " << op->name << " on device\n";
debug(3) << "Pushing allocation called " << op->name << " onto the symbol table\n";
// Allocation is not a shared memory allocation, just make a local declaration.
// It must have a constant size.
int32_t size = op->constant_allocation_size();
user_assert(size > 0)
<< "Allocation " << op->name << " has a dynamic size. "
<< "Only fixed-size allocations are supported on the gpu. "
<< "Try storing into shared memory instead.";
do_indent();
stream << print_storage_type(op->type) << ' '
<< print_name(op->name) << "[" << size << "];\n";
do_indent();
Allocation alloc;
alloc.type = op->type;
allocations.push(op->name, alloc);
op->body.accept(this);
// Should have been freed internally
internal_assert(!allocations.contains(op->name));
close_scope("alloc " + print_name(op->name));
}
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Free *op) {
if (op->name == "__shared") {
return;
} else {
// Should have been freed internally
internal_assert(allocations.contains(op->name));
allocations.pop(op->name);
do_indent();
}
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_assignment(Type type, const string &rhs)
{
string rhs_modified = print_reinforced_cast(type, rhs);
return CodeGen_C::print_assignment(type, rhs_modified);
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_vanilla_cast(Type type, string value_expr)
{
ostringstream ss;
ss << print_type(type) << "(" << value_expr << ")";
return ss.str();
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_reinforced_cast(Type type, string value_expr)
{
if (type.is_float()) {
return print_vanilla_cast(type, value_expr);
}
if (type.is_bool()) {
return print_vanilla_cast(type, value_expr);
}
if (type.bits() == 32) {
return print_reinterpret_cast(type, value_expr);
}
// HLSL SM 5.1 only supports 32bit integer types; smaller integer types have
// to be placed in 32bit integers, with special attention to signed integers
// that require propagation of the sign bit (MSB):
// a) for signed types: shift-up then shift-down
// b) for unsigned types: simply mask the LSB (but shift-up and down also works)
ostringstream sl;
sl << "(" << value_expr << ")"
<< " << "
<< "(" << (32 - type.bits()) << ")"; // 1. shift-up to MSB
ostringstream rsr;
rsr << print_reinterpret_cast(type, sl.str()) // 2. reinterpret bits
<< " >> " << (32 - type.bits()); // 3. shift-down to LSB
return rsr.str();
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_reinterpret_cast(Type type, string value_expr)
{
type = type.element_of();
string cast_expr;
cast_expr += "as";
switch (type.code()) {
case halide_type_uint :
cast_expr += "uint";
break;
case halide_type_int :
cast_expr += "int";
break;
case halide_type_float :
cast_expr += "float";
break;
case halide_type_handle :
default :
cast_expr = "BADCAST";
user_error << "Invalid reinterpret cast.\n";
break;
}
cast_expr += "(" + value_expr + ")";
return cast_expr;
}
string CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::print_cast(Type target_type, Type source_type, string value_expr)
{
// casting to or from a float type? just use the language cast:
if (target_type.is_float() || source_type.is_float()) {
return print_vanilla_cast(target_type, value_expr);
}
// casting to or from a bool type? just use the language cast:
if (target_type.is_bool() || source_type.is_bool()) {
return print_vanilla_cast(target_type, value_expr);
}
// let the integer cast zoo begin...
internal_assert(!target_type.is_float());
internal_assert(!source_type.is_float());
// HLSL (SM 5.1) only supports 32bit integers (signed and unsigned)...
// integer downcasting-to (or upcasting-from) lower bit integers require
// some emulation in code...
internal_assert(target_type.bits() >= 8);
internal_assert(source_type.bits() >= 8);
internal_assert(target_type.bits() <= 32);
internal_assert(source_type.bits() <= 32);
internal_assert(target_type.bits() % 8 == 0);
internal_assert(source_type.bits() % 8 == 0);
// Case 1: source and target both have the same "signess"
bool same_signess = false;
same_signess |= target_type.is_int() && source_type.is_int();
same_signess |= target_type.is_uint() && source_type.is_uint();
if (same_signess) {
ostringstream ss;
if (target_type.bits() >= source_type.bits()) {
// target has enough bits to fully accommodate the source:
// it's a no-op, but we print a vanilla cast for clarity:
ss << "(" << print_vanilla_cast(target_type, value_expr) << ")";
} else {
// for signed types: shift-up then shift-down
// for unsigned types: mask the target LSB (but shift-up and down also works)
ss << "("
<< "(" << value_expr << ")"
<< " << "
<< "(" << (32 - target_type.bits()) << ")" // 1. shift-up to MSB
<< ")"
<< " >> " << (32 - target_type.bits()); // 2. shift-down to LSB
}
return ss.str();
}
// Case 2: casting from a signed source to an unsigned target
if (source_type.is_int() && target_type.is_uint()) {
// reinterpret resulting bits as uint(32):
string masked = value_expr;
if (target_type.bits() < 32) {
masked = "(" + value_expr + ")"
+ " & "
+ hex_literal((1 << target_type.bits()) - 1); // mask target LSB
}
return print_reinterpret_cast(target_type, masked);
}
// Case 3: casting from an unsigned source to a signed target
internal_assert(source_type.is_uint());
internal_assert(target_type.is_int());
ostringstream ss;
if (target_type.bits() > source_type.bits()) {
// target has enough bits to fully accommodate the source:
// it's a no-op, but we print a vanilla cast for clarity:
ss << "(" << print_vanilla_cast(target_type, value_expr) << ")";
} else {
// shift-up, reinterpret as int (target_type), then shift-down
ss << print_reinforced_cast(target_type, value_expr);
}
return ss.str();
}
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::visit(const Cast *op)
{
Type target_type = op->type;
Type source_type = op->value.type();
string value_expr = print_expr(op->value);
string cast_expr = print_cast( target_type, source_type, print_expr(op->value) );
print_assignment(target_type, cast_expr);
}
void CodeGen_D3D12Compute_Dev::add_kernel(Stmt s,
const string &name,
const vector<DeviceArgument> &args) {
debug(2) << "CodeGen_D3D12Compute_Dev::compile " << name << "\n";
// TODO: do we have to uniquify these names, or can we trust that they are safe?
cur_kernel_name = name;
d3d12compute_c.add_kernel(s, name, args);
}
namespace {
struct BufferSize {
string name;
size_t size;
BufferSize() : size(0) {}
BufferSize(string name, size_t size) : name(name), size(size) {}
bool operator < (const BufferSize &r) const {
return size < r.size;
}
};
} // namespace
void CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C::add_kernel(Stmt s,
const string &name,
const vector<DeviceArgument> &args) {
debug(2) << "Adding D3D12Compute kernel " << name << "\n";
// Figure out which arguments should be passed in constant.
// Such arguments should be:
// - not written to,
// - loads are block-uniform,
// - constant size,
// - and all allocations together should be less than the max constant
// buffer size given by D3D11_REQ_CONSTANT_BUFFER_ELEMENT_COUNT*(4*sizeof(float))
// The last condition is handled via the preprocessor in the kernel
// declaration.
vector<BufferSize> constants;
auto isConstantBuffer = [&s](const DeviceArgument &arg)
{
return arg.is_buffer
&& CodeGen_GPU_Dev::is_buffer_constant(s, arg.name)
&& arg.size > 0;
};
for (auto &arg : args) {
if (isConstantBuffer(arg)) {
constants.push_back(BufferSize(arg.name, arg.size));
}
}
// Sort the constant candidates from smallest to largest. This will put
// as many of the constant allocations in constant as possible.
// Ideally, we would prioritize constant buffers by how frequently they
// are accessed.
sort(constants.begin(), constants.end());
// Compute the cumulative sum of the constants.
for (size_t i = 1; i < constants.size(); i++) {
constants[i].size += constants[i-1].size;
}
// Find all the shared allocations and declare them at global scope.
class FindSharedAllocations : public IRVisitor
{
using IRVisitor::visit;
void visit(const Allocate *op) override
{
op->body.accept(this);
if (starts_with(op->name, "__shared")) {
allocs.push_back(op);
}
}
friend class CodeGen_D3D12Compute_Dev::CodeGen_D3D12Compute_C;
vector<const Allocate *> allocs;
};
FindSharedAllocations fsa;
s.accept(&fsa);
for (const Allocate *op : fsa.allocs) {
internal_assert( op->extents.size() == 1 );
// The 'op->type' of shared memory allocations is always uint8 in Halide
// since shared storaged is considered a "byte buffer"... In D3D12 there
// is no uint8 type, so we'll have to emulate it with some 32bit type...
// This will also require pack/unpack logic with bit-masking and aliased
// type reinterpretation via asfloat()/asuint() in the shader code... :(
internal_assert( op->type == UInt(8) );
stream << "groupshared"
<< " " << print_type(op->type) // print_type(uint8) -> uint32
<< " " << print_name(op->name);
if (is_const(op->extents[0])) {
std::stringstream ss;
ss << op->extents[0];
size_t elements = 0;
ss >> elements;
size_t bytesize = elements * sizeof(uint32_t);
// SM 5.1: 32KB limit for shared memory...
size_t packing_factor = 1;
while (bytesize > 32 * 1024) {
// must pack/unpack elements to/from shared memory...
elements /= 2;
bytesize /= 2;
packing_factor *= 2;
}
stream << " [" << elements << "];\n";
// smallest possible pack type is a byte (no nibbles)
internal_assert( packing_factor <= 4 );
} else {
// fill-in __GROUPSHARED_SIZE_IN_BYTES later on when D3DCompile()
// is invoked in halide_d3d12compute_run(); must get divided by 4
// since groupshared memory elements have 32bit granularity:
stream << " [ ( __GROUPSHARED_SIZE_IN_BYTES + 3 ) / 4 ];\n";
}
Allocation alloc;
alloc.type = op->type;
allocations.push(op->name, alloc);
}
// Find and patch situations where the __shared buffer is read before having
// ever being initialized:
// NOTE(marcos): it would be cleaner if we could just use an IRVisitor here
// but in order to find the enclosing Stmt of a Load expression we need to
// to walk through base Stmt nodes, and only IRMutator has this overload:
struct FindUninitializedSharedLoads : public IRMutator {
using IRMutator::visit;
using IRMutator::mutate;
virtual Expr visit(const Load *op) override {
if (op->name == "__shared") {
if (!latest_store) {
// attempting to read from __shared before anything has been
// written to it yet!
bad_load_expr = op;
}
}
return IRMutator::visit(op);
}
virtual Stmt visit(const Store *op) override {
Stmt store = IRMutator::visit(op);
if (op->name == "__shared") {
latest_store = op;
}
return store;
}
virtual Stmt mutate(const Stmt &stmt) override {
if (!bad_load_expr) {
current_stmt = &stmt;
}
return IRMutator::mutate(stmt);
}
const Stmt *current_stmt = nullptr;
const Load *bad_load_expr = nullptr;
const Store *latest_store = nullptr;
};
FindUninitializedSharedLoads fusl;
s = fusl.mutate(s);
if (fusl.bad_load_expr) {
debug(1) << "Found a potential load-before-initialization on __shared buffer!\n";
// use IRMutator to inject a zero-initialization before the load
struct ZeroInitializeSharedMemory : public IRMutator {
using IRMutator::mutate;
virtual Stmt mutate(const Stmt &op) override {
if (&op != uninitialized_load_stmt) {
return IRMutator::mutate(op);
}
debug(1) << "Patching __shared buffer with zero-intialization...\n";
const Load* lop = uninitialized_load_expr;
Stmt initialization = Store::make(lop->name, Expr(0), lop->index, Parameter(), lop->predicate, ModulusRemainder());
return Block::make({ initialization, op });
}
const Stmt *uninitialized_load_stmt = nullptr;
const Load *uninitialized_load_expr = nullptr;
};
ZeroInitializeSharedMemory zism;
zism.uninitialized_load_stmt = fusl.current_stmt;
zism.uninitialized_load_expr = fusl.bad_load_expr;
s = zism.mutate(s);
}
// Emit the kernel function preamble (numtreads):
// Figure out the thread group size by traversing the stmt:
struct FindThreadGroupSize : public IRVisitor
{
using IRVisitor::visit;
void visit(const For *loop) override
{
if (!is_gpu_var(loop->name))
return loop->body.accept(this);
if (loop->for_type != ForType::GPUThread)
return loop->body.accept(this);
internal_assert(is_zero(loop->min));
int index = thread_loop_workgroup_index(loop->name);
user_assert(index >= 0) << "Invalid 'numthreads' index for loop variable '" << loop->name << "'.\n";
// if 'numthreads' for a given dimension can't be determined at code
// generation time, emit code such that it can be patched some point
// later when calling D3DCompile() / halide_d3d12compute_run()
numthreads[index] = 0; // <-- 0 indicates 'undetermined'
const IntImm *int_limit = loop->extent.as<IntImm>();
if (nullptr != int_limit) {
numthreads[index] = int_limit->value;
user_assert(numthreads[index] > 0) << "For D3D12Compute, 'numthreads[" << index << "]' values must be greater than zero.\n";
}
debug(4) << "Thread group size for index " << index << " is " << numthreads[index] << "\n";
loop->body.accept(this);
}
int thread_loop_workgroup_index(const string &name)
{
string ids[] = { ".__thread_id_x",
".__thread_id_y",
".__thread_id_z",
".__thread_id_w" };
for (auto &id : ids) {
if (ends_with(name, id)) {
return (&id - ids);
}
}
return -1;
}
int numthreads [3] = { 1, 1, 1 };
};
FindThreadGroupSize ftg;
s.accept(&ftg);
// for undetermined 'numthreads' dimensions, insert placeholders to the code
// such as '__NUM_TREADS_X' that will later be patched when D3DCompile() is
// invoked in halide_d3d12compute_run()
stream << "[ numthreads(";
(ftg.numthreads[0] > 0) ?
(stream << " " << ftg.numthreads[0]) :
(stream << " __NUM_TREADS_X ");
(ftg.numthreads[1] > 0) ?
(stream << ", " << ftg.numthreads[1]) :
(stream << ", __NUM_TREADS_Y ");
(ftg.numthreads[2] > 0) ?
(stream << ", " << ftg.numthreads[2]) :
(stream << ", __NUM_TREADS_Z ");
stream << ") ]\n";
// Emit the kernel function prototype:
stream << "void " << name << "(\n";
stream << ' ' << "uint3 tgroup_index : SV_GroupID,\n"
<< ' ' << "uint3 tid_in_tgroup : SV_GroupThreadID";
for (auto &arg : args) {
stream << ",\n";
stream << ' ';
if (arg.is_buffer) {
// NOTE(marcos): Passing all buffers as RWBuffers in order to bind
// all buffers as UAVs since there is no way the runtime can know
// if a given halide_buffer_t is read-only (SRV) or read-write...
stream << "RW"
<< "Buffer"
<< "<" << print_type(arg.type) << ">"
<< " " << print_name(arg.name);
Allocation alloc;
alloc.type = arg.type;
allocations.push(arg.name, alloc);
} else {
stream << "uniform"
<< " " << print_type(arg.type)
<< " " << print_name(arg.name);
}
}
stream << ")\n";
// Emit the kernel code:
open_scope();
print(s);
close_scope("kernel " + name);
for (size_t i = 0; i < args.size(); i++) {
// Remove buffer arguments from allocation scope
if (args[i].is_buffer) {
allocations.pop(args[i].name);
}
}
stream << "\n";
}
void CodeGen_D3D12Compute_Dev::init_module() {
debug(2) << "D3D12Compute device codegen init_module\n";
// wipe the internal kernel source
src_stream.str("");
src_stream.clear();
// compiler control pragmas
src_stream
// Disable innocent warnings:
// warning X3078 : loop control variable conflicts with a previous declaration in the outer scope; most recent declaration will be used
<< "#pragma warning( disable : 3078 )" "\n"
// warning X3557: loop only executes for 1 iteration(s), forcing loop to unroll
<< "#pragma warning( disable : 3557 )" "\n"
// Disable more serious warnings:
// TODO(marcos): should revisit the warnings below, as they are likely to impact performance (and possibly correctness too)
// warning X3556 : integer modulus may be much slower, try using uints if possible
// TODO(marcos): can we interchangeably replace ints by uints when we have modulo operations in the generated code?
<< "#pragma warning( disable : 3556 )" "\n"
// warning X3571 : pow(f, e) will not work for negative f, use abs(f) or conditionally handle negative values if you expect them
<< "#pragma warning( disable : 3571 )" "\n"
// warning X4714 : sum of temp registers and indexable temp registers times 256 threads exceeds the recommended total 16384. Performance may be reduced
<< "#pragma warning( disable : 4714 )" "\n"
<< "\n";
// Write out the Halide math functions.
src_stream
//<< "namespace {\n" // HLSL does not support unnamed namespaces...
#if DEBUG_TYPES
<< "#define int8 int\n"
<< "#define int16 int\n"
<< "#define int32 int\n"
<< "#define uint8 uint\n"
<< "#define uint16 uint\n"
<< "#define uint32 uint\n"
<< "\n"
<< "#define bool_(x) bool##x\n"
<< "#define int8_(x) int##x\n"
<< "#define int16_(x) int##x\n"
<< "#define int32_(x) int##x\n"
<< "#define uint8_(x) uint##x\n"
<< "#define uint16_(x) uint##x\n"
<< "#define uint32_(x) uint##x\n"
<< "\n"
<< "#define asint32 asint\n"
<< "#define asuint32 asuint\n"
<< "\n"
#endif
<< "float nan_f32() { return 1.#IND; } \n" // Quiet NaN with minimum fractional value.
<< "float neg_inf_f32() { return -1.#INF; } \n"
<< "float inf_f32() { return +1.#INF; } \n"
<< "#define float_from_bits asfloat \n"
<< "#define sqrt_f32 sqrt \n"
<< "#define sin_f32 sin \n"
<< "#define cos_f32 cos \n"
<< "#define exp_f32 exp \n"
<< "#define log_f32 log \n"
<< "#define abs_f32 abs \n"
<< "#define floor_f32 floor \n"
<< "#define ceil_f32 ceil \n"
<< "#define round_f32 round \n"
<< "#define trunc_f32 trunc \n"
<< "#define pow_f32 pow \n"
<< "#define asin_f32 asin \n"
<< "#define acos_f32 acos \n"
<< "#define tan_f32 tan \n"
<< "#define atan_f32 atan \n"
<< "#define atan2_f32 atan2 \n"
<< "#define sinh_f32 sinh \n"
<< "#define cosh_f32 cosh \n"
<< "#define tanh_f32 tanh \n"
<< "#define asinh_f32(x) (log_f32(x + sqrt_f32(x*x + 1))) \n"
<< "#define acosh_f32(x) (log_f32(x + sqrt_f32(x*x - 1))) \n"
<< "#define atanh_f32(x) (log_f32((1+x)/(1-x))/2) \n"
<< "#define fast_inverse_f32 rcp \n"
<< "#define fast_inverse_sqrt_f32 rsqrt \n"
<< "\n";
//<< "}\n"; // close namespace
src_stream << '\n';
cur_kernel_name = "";
}
vector<char> CodeGen_D3D12Compute_Dev::compile_to_src() {
string str = src_stream.str();
debug(1) << "D3D12Compute kernel:\n" << str << "\n";
vector<char> buffer(str.begin(), str.end());
buffer.push_back(0);
return buffer;
}
string CodeGen_D3D12Compute_Dev::get_current_kernel_name() {
return cur_kernel_name;
}
void CodeGen_D3D12Compute_Dev::dump() {
std::cerr << src_stream.str() << std::endl;
}
std::string CodeGen_D3D12Compute_Dev::print_gpu_name(const std::string &name) {
return name;
}
}} // namespace Halide::Internal