SPIRV-Cross/reference/shaders-msl/vulkan/comp/subgroups.nocompat.invalid.vk.msl21.comp
Chip Davis 31b6c93516 MSL: Support SubgroupLocalInvocationId and SubgroupSize in all stages.
MSL prior to 2.2 doesn't support these natively in any stage but
compute. But, we can (assuming no threads were terminated prematurely)
get their values with some creative uses of the
`simd_prefix_exclusive_sum()` and `simd_sum()` functions.

Also, fix a missing `to_expression()` with `BuiltInSubgroupEqMask`.

For KhronosGroup/MoltenVK#629.
2019-07-02 11:48:59 -05:00

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#pragma clang diagnostic ignored "-Wmissing-prototypes"
#include <metal_stdlib>
#include <simd/simd.h>
using namespace metal;
struct SSBO
{
float FragColor;
};
inline uint4 spvSubgroupBallot(bool value)
{
simd_vote vote = simd_ballot(value);
// simd_ballot() returns a 64-bit integer-like object, but
// SPIR-V callers expect a uint4. We must convert.
// FIXME: This won't include higher bits if Apple ever supports
// 128 lanes in an SIMD-group.
return uint4((uint)((simd_vote::vote_t)vote & 0xFFFFFFFF), (uint)(((simd_vote::vote_t)vote >> 32) & 0xFFFFFFFF), 0, 0);
}
inline bool spvSubgroupBallotBitExtract(uint4 ballot, uint bit)
{
return !!extract_bits(ballot[bit / 32], bit % 32, 1);
}
inline uint spvSubgroupBallotFindLSB(uint4 ballot)
{
return select(ctz(ballot.x), select(32 + ctz(ballot.y), select(64 + ctz(ballot.z), select(96 + ctz(ballot.w), uint(-1), ballot.w == 0), ballot.z == 0), ballot.y == 0), ballot.x == 0);
}
inline uint spvSubgroupBallotFindMSB(uint4 ballot)
{
return select(128 - (clz(ballot.w) + 1), select(96 - (clz(ballot.z) + 1), select(64 - (clz(ballot.y) + 1), select(32 - (clz(ballot.x) + 1), uint(-1), ballot.x == 0), ballot.y == 0), ballot.z == 0), ballot.w == 0);
}
inline uint spvSubgroupBallotBitCount(uint4 ballot)
{
return popcount(ballot.x) + popcount(ballot.y) + popcount(ballot.z) + popcount(ballot.w);
}
inline uint spvSubgroupBallotInclusiveBitCount(uint4 ballot, uint gl_SubgroupInvocationID)
{
uint4 mask = uint4(extract_bits(0xFFFFFFFF, 0, min(gl_SubgroupInvocationID + 1, 32u)), extract_bits(0xFFFFFFFF, 0, (uint)max((int)gl_SubgroupInvocationID + 1 - 32, 0)), uint2(0));
return spvSubgroupBallotBitCount(ballot & mask);
}
inline uint spvSubgroupBallotExclusiveBitCount(uint4 ballot, uint gl_SubgroupInvocationID)
{
uint4 mask = uint4(extract_bits(0xFFFFFFFF, 0, min(gl_SubgroupInvocationID, 32u)), extract_bits(0xFFFFFFFF, 0, (uint)max((int)gl_SubgroupInvocationID - 32, 0)), uint2(0));
return spvSubgroupBallotBitCount(ballot & mask);
}
template<typename T>
inline bool spvSubgroupAllEqual(T value)
{
return simd_all(value == simd_broadcast_first(value));
}
template<>
inline bool spvSubgroupAllEqual(bool value)
{
return simd_all(value) || !simd_any(value);
}
kernel void main0(device SSBO& _9 [[buffer(0)]], uint gl_NumSubgroups [[simdgroups_per_threadgroup]], uint gl_SubgroupID [[simdgroup_index_in_threadgroup]], uint gl_SubgroupSize [[thread_execution_width]], uint gl_SubgroupInvocationID [[thread_index_in_simdgroup]])
{
uint4 gl_SubgroupEqMask = gl_SubgroupInvocationID > 32 ? uint4(0, (1 << (gl_SubgroupInvocationID - 32)), uint2(0)) : uint4(1 << gl_SubgroupInvocationID, uint3(0));
uint4 gl_SubgroupGeMask = uint4(extract_bits(0xFFFFFFFF, min(gl_SubgroupInvocationID, 32u), (uint)max(min((int)gl_SubgroupSize, 32) - (int)gl_SubgroupInvocationID, 0)), extract_bits(0xFFFFFFFF, (uint)max((int)gl_SubgroupInvocationID - 32, 0), (uint)max((int)gl_SubgroupSize - (int)max(gl_SubgroupInvocationID, 32u), 0)), uint2(0));
uint4 gl_SubgroupGtMask = uint4(extract_bits(0xFFFFFFFF, min(gl_SubgroupInvocationID + 1, 32u), (uint)max(min((int)gl_SubgroupSize, 32) - (int)gl_SubgroupInvocationID - 1, 0)), extract_bits(0xFFFFFFFF, (uint)max((int)gl_SubgroupInvocationID + 1 - 32, 0), (uint)max((int)gl_SubgroupSize - (int)max(gl_SubgroupInvocationID + 1, 32u), 0)), uint2(0));
uint4 gl_SubgroupLeMask = uint4(extract_bits(0xFFFFFFFF, 0, min(gl_SubgroupInvocationID + 1, 32u)), extract_bits(0xFFFFFFFF, 0, (uint)max((int)gl_SubgroupInvocationID + 1 - 32, 0)), uint2(0));
uint4 gl_SubgroupLtMask = uint4(extract_bits(0xFFFFFFFF, 0, min(gl_SubgroupInvocationID, 32u)), extract_bits(0xFFFFFFFF, 0, (uint)max((int)gl_SubgroupInvocationID - 32, 0)), uint2(0));
_9.FragColor = float(gl_NumSubgroups);
_9.FragColor = float(gl_SubgroupID);
_9.FragColor = float(gl_SubgroupSize);
_9.FragColor = float(gl_SubgroupInvocationID);
simdgroup_barrier(mem_flags::mem_device | mem_flags::mem_threadgroup | mem_flags::mem_texture);
simdgroup_barrier(mem_flags::mem_device | mem_flags::mem_threadgroup | mem_flags::mem_texture);
simdgroup_barrier(mem_flags::mem_device);
simdgroup_barrier(mem_flags::mem_threadgroup);
simdgroup_barrier(mem_flags::mem_texture);
bool elected = simd_is_first();
_9.FragColor = float4(gl_SubgroupEqMask).x;
_9.FragColor = float4(gl_SubgroupGeMask).x;
_9.FragColor = float4(gl_SubgroupGtMask).x;
_9.FragColor = float4(gl_SubgroupLeMask).x;
_9.FragColor = float4(gl_SubgroupLtMask).x;
float4 broadcasted = simd_broadcast(float4(10.0), 8u);
float3 first = simd_broadcast_first(float3(20.0));
uint4 ballot_value = spvSubgroupBallot(true);
bool inverse_ballot_value = spvSubgroupBallotBitExtract(ballot_value, gl_SubgroupInvocationID);
bool bit_extracted = spvSubgroupBallotBitExtract(uint4(10u), 8u);
uint bit_count = spvSubgroupBallotBitCount(ballot_value);
uint inclusive_bit_count = spvSubgroupBallotInclusiveBitCount(ballot_value, gl_SubgroupInvocationID);
uint exclusive_bit_count = spvSubgroupBallotExclusiveBitCount(ballot_value, gl_SubgroupInvocationID);
uint lsb = spvSubgroupBallotFindLSB(ballot_value);
uint msb = spvSubgroupBallotFindMSB(ballot_value);
uint shuffled = simd_shuffle(10u, 8u);
uint shuffled_xor = simd_shuffle_xor(30u, 8u);
uint shuffled_up = simd_shuffle_up(20u, 4u);
uint shuffled_down = simd_shuffle_down(20u, 4u);
bool has_all = simd_all(true);
bool has_any = simd_any(true);
bool has_equal = spvSubgroupAllEqual(0);
has_equal = spvSubgroupAllEqual(true);
float4 added = simd_sum(float4(20.0));
int4 iadded = simd_sum(int4(20));
float4 multiplied = simd_product(float4(20.0));
int4 imultiplied = simd_product(int4(20));
float4 lo = simd_min(float4(20.0));
float4 hi = simd_max(float4(20.0));
int4 slo = simd_min(int4(20));
int4 shi = simd_max(int4(20));
uint4 ulo = simd_min(uint4(20u));
uint4 uhi = simd_max(uint4(20u));
uint4 anded = simd_and(ballot_value);
uint4 ored = simd_or(ballot_value);
uint4 xored = simd_xor(ballot_value);
added = simd_prefix_inclusive_sum(added);
iadded = simd_prefix_inclusive_sum(iadded);
multiplied = simd_prefix_inclusive_product(multiplied);
imultiplied = simd_prefix_inclusive_product(imultiplied);
added = simd_prefix_exclusive_sum(multiplied);
multiplied = simd_prefix_exclusive_product(multiplied);
iadded = simd_prefix_exclusive_sum(imultiplied);
imultiplied = simd_prefix_exclusive_product(imultiplied);
added = quad_sum(added);
multiplied = quad_product(multiplied);
iadded = quad_sum(iadded);
imultiplied = quad_product(imultiplied);
lo = quad_min(lo);
hi = quad_max(hi);
ulo = quad_min(ulo);
uhi = quad_max(uhi);
slo = quad_min(slo);
shi = quad_max(shi);
anded = quad_and(anded);
ored = quad_or(ored);
xored = quad_xor(xored);
float4 swap_horiz = quad_shuffle_xor(float4(20.0), 1u);
float4 swap_vertical = quad_shuffle_xor(float4(20.0), 2u);
float4 swap_diagonal = quad_shuffle_xor(float4(20.0), 3u);
float4 quad_broadcast0 = quad_broadcast(float4(20.0), 3u);
}