SPIRV-Cross/reference/shaders-msl/frag/array-component-io.frag

#pragma clang diagnostic ignored "-Wmissing-prototypes"
#pragma clang diagnostic ignored "-Wmissing-braces"

#include <metal_stdlib>
#include <simd/simd.h>

using namespace metal;

template<typename T, size_t Num>
struct spvUnsafeArray
{
    T elements[Num ? Num : 1];
    
    thread T& operator [] (size_t pos) thread
    {
        return elements[pos];
    }
    constexpr const thread T& operator [] (size_t pos) const thread
    {
        return elements[pos];
    }
    
    device T& operator [] (size_t pos) device
    {
        return elements[pos];
    }
    constexpr const device T& operator [] (size_t pos) const device
    {
        return elements[pos];
    }
    
    constexpr const constant T& operator [] (size_t pos) const constant
    {
        return elements[pos];
    }
    
    threadgroup T& operator [] (size_t pos) threadgroup
    {
        return elements[pos];
    }
    constexpr const threadgroup T& operator [] (size_t pos) const threadgroup
    {
        return elements[pos];
    }
};

struct main0_out
{
    float4 m_location_0 [[color(0)]];
    float4 m_location_1 [[color(1)]];
    float4 m_location_2 [[color(2)]];
};

struct main0_in
{
    float InC_0 [[user(locn0_1), flat]];
    float InA_0 [[user(locn1), flat]];
    float InC_1 [[user(locn1_1), flat]];
    float2 InB_0 [[user(locn1_2), flat]];
    float InA_1 [[user(locn2), flat]];
    float InC_2 [[user(locn2_1), flat]];
    float2 InB_1 [[user(locn2_2), flat]];
    float InD [[user(locn3_1), sample_perspective]];
    float InE [[user(locn4_2), center_no_perspective]];
    float InF [[user(locn5_3), centroid_perspective]];
};

fragment main0_out main0(main0_in in [[stage_in]])
{
    main0_out out = {};
    spvUnsafeArray<float, 2> A = {};
    spvUnsafeArray<float2, 2> B = {};
    spvUnsafeArray<float, 3> C = {};
    float D = {};
    spvUnsafeArray<float, 2> InA = {};
    spvUnsafeArray<float2, 2> InB = {};
    spvUnsafeArray<float, 3> InC = {};
    InA[0] = in.InA_0;
    InA[1] = in.InA_1;
    InB[0] = in.InB_0;
    InB[1] = in.InB_1;
    InC[0] = in.InC_0;
    InC[1] = in.InC_1;
    InC[2] = in.InC_2;
    A = InA;
    B = InB;
    C = InC;
    D = (in.InD + in.InE) + in.InF;
    out.m_location_1.x = A[0];
    out.m_location_2.x = A[1];
    out.m_location_1.zw = B[0];
    out.m_location_2.zw = B[1];
    out.m_location_0.y = C[0];
    out.m_location_1.y = C[1];
    out.m_location_2.y = C[2];
    out.m_location_0.w = D;
    return out;
}
MSL: Handle array with component when we cannot rely on user() attrib. In these cases, we emit one variable per location, and so we must flatten stuff. 2021-05-21 11:03:05 +00:00			`#pragma clang diagnostic ignored "-Wmissing-prototypes"`
			`#pragma clang diagnostic ignored "-Wmissing-braces"`

			`#include <metal_stdlib>`
			`#include <simd/simd.h>`

			`using namespace metal;`

			`template<typename T, size_t Num>`
			`struct spvUnsafeArray`
			`{`
			`T elements[Num ? Num : 1];`

			`thread T& operator [] (size_t pos) thread`
			`{`
			`return elements[pos];`
			`}`
			`constexpr const thread T& operator [] (size_t pos) const thread`
			`{`
			`return elements[pos];`
			`}`

			`device T& operator [] (size_t pos) device`
			`{`
			`return elements[pos];`
			`}`
			`constexpr const device T& operator [] (size_t pos) const device`
			`{`
			`return elements[pos];`
			`}`

			`constexpr const constant T& operator [] (size_t pos) const constant`
			`{`
			`return elements[pos];`
			`}`

			`threadgroup T& operator [] (size_t pos) threadgroup`
			`{`
			`return elements[pos];`
			`}`
			`constexpr const threadgroup T& operator [] (size_t pos) const threadgroup`
			`{`
			`return elements[pos];`
			`}`
			`};`

			`struct main0_out`
			`{`
			`float4 m_location_0 [[color(0)]];`
			`float4 m_location_1 [[color(1)]];`
			`float4 m_location_2 [[color(2)]];`
			`};`

			`struct main0_in`
			`{`
			`float InC_0 [[user(locn0_1), flat]];`
			`float InA_0 [[user(locn1), flat]];`
			`float InC_1 [[user(locn1_1), flat]];`
			`float2 InB_0 [[user(locn1_2), flat]];`
			`float InA_1 [[user(locn2), flat]];`
			`float InC_2 [[user(locn2_1), flat]];`
			`float2 InB_1 [[user(locn2_2), flat]];`
			`float InD [[user(locn3_1), sample_perspective]];`
			`float InE [[user(locn4_2), center_no_perspective]];`
			`float InF [[user(locn5_3), centroid_perspective]];`
			`};`

			`fragment main0_out main0(main0_in in [[stage_in]])`
			`{`
			`main0_out out = {};`
			`spvUnsafeArray<float, 2> A = {};`
			`spvUnsafeArray<float2, 2> B = {};`
			`spvUnsafeArray<float, 3> C = {};`
			`float D = {};`
			`spvUnsafeArray<float, 2> InA = {};`
			`spvUnsafeArray<float2, 2> InB = {};`
			`spvUnsafeArray<float, 3> InC = {};`
			`InA[0] = in.InA_0;`
			`InA[1] = in.InA_1;`
			`InB[0] = in.InB_0;`
			`InB[1] = in.InB_1;`
			`InC[0] = in.InC_0;`
			`InC[1] = in.InC_1;`
			`InC[2] = in.InC_2;`
			`A = InA;`
			`B = InB;`
			`C = InC;`
			`D = (in.InD + in.InE) + in.InF;`
			`out.m_location_1.x = A[0];`
			`out.m_location_2.x = A[1];`
			`out.m_location_1.zw = B[0];`
			`out.m_location_2.zw = B[1];`
			`out.m_location_0.y = C[0];`
			`out.m_location_1.y = C[1];`
			`out.m_location_2.y = C[2];`
			`out.m_location_0.w = D;`
			`return out;`
			`}`