HLSL Function Calls

Introduction

This document describes the design and implementation of HLSL’s function call semantics in Clang. This includes details related to argument conversion and parameter lifetimes.

This document does not seek to serve as official documentation for HLSL’s call semantics, but does provide an overview to assist a reader. The authoritative documentation for HLSL’s language semantics is the draft language specification.

Argument Semantics

In HLSL, all function arguments are passed by value in and out of functions. HLSL has 3 keywords which denote the parameter semantics (in, out and inout). In a function declaration a parameter may be annotated any of the following ways:

  1. <no parameter annotation> - denotes input

  2. in - denotes input

  3. out - denotes output

  4. in out - denotes input and output

  5. out in - denotes input and output

  6. inout - denotes input and output

Parameters that are exclusively input behave like C/C++ parameters that are passed by value.

For parameters that are output (or input and output), a temporary value is created in the caller. The temporary value is then passed by-address. For output-only parameters, the temporary is uninitialized when passed (if the parameter is not explicitly initialized inside the function an undefined value is stored back to the argument expression). For parameters that are both input and output, the temporary is initialized from the lvalue argument expression through implicit or explicit casting from the lvalue argument type to the parameter type.

On return of the function, the values of any parameter temporaries are written back to the argument expression through an inverted conversion sequence (if an out parameter was not initialized in the function, the uninitialized value may be written back).

Parameters of constant-sized array type are also passed with value semantics. This requires input parameters of arrays to construct temporaries and the temporaries go through array-to-pointer decay when initializing parameters.

Implementations are allowed to avoid unnecessary temporaries, and HLSL’s strict no-alias rules can enable some trivial optimizations.

Array Temporaries

Given the following example:

void fn(float a[4]) {
  a[0] = a[1] + a[2] + a[3];
}

float4 main() : SV_Target {
  float arr[4] = {1, 1, 1, 1};
  fn(arr);
  return float4(arr[0], arr[1], arr[2], arr[3]);
}

In C or C++, the array parameter decays to a pointer, so after the call to fn, the value of arr[0] is 3. In HLSL, the array is passed by value, so modifications inside fn do not propagate out.

Note

DXC may pass unsized arrays directly as decayed pointers, which is an unfortunate behavior divergence.

Out Parameter Temporaries

void Init(inout int X, inout int Y) {
  Y = 2;
  X = 1;
}

void main() {
  int V;
  Init(V, V); // MSVC (or clang-cl) V == 2, Clang V == 1
}

In the above example the Init function’s behavior depends on the C++ implementation. C++ does not define the order in which parameters are initialized or destroyed. In MSVC and Clang’s MSVC compatibility mode, arguments are emitted right-to-left and destroyed left-to-right. This means that the parameter initialization and destruction occurs in the order: {Y, X, ~X, ~Y}. This causes the write-back of the value of Y to occur last, so the resulting value of V is 2. In the Itanium C++ ABI, the parameter ordering is reversed, so the initialization and destruction occurs in the order: {X, Y, ~Y, X}. This causes the write-back of the value X to occur last, resulting in the value of V being set to 1.

void Trunc(inout int3 V) { }


void main() {
  float3 F = {1.5, 2.6, 3.3};
  Trunc(F); // F == {1.0, 2.0, 3.0}
}

In the above example, the argument expression F undergoes element-wise conversion from a float vector to an integer vector to create a temporary int3. On expiration the temporary undergoes elementwise conversion back to the floating point vector type float3. This results in an implicit element-wise conversion of the vector even if the value is unused in the function (effectively truncating the floating point values).

void UB(out int X) {}

void main() {
  int X = 7;
  UB(X); // X is undefined!
}

In this example an initialized value is passed to an out parameter. Parameters marked out are not initialized by the argument expression or implicitly by the function. They must be explicitly initialized. In this case the argument is not initialized in the function so the temporary is still uninitialized when it is copied back to the argument expression. This is undefined behavior in HLSL, and any use of the argument after the call is a use of an undefined value which may be illegal in the target (DXIL programs with used or potentially used undef or poison values fail validation).

Clang Implementation

Note

The implementation described here is a proposal. It has not yet been fully implemented, so the current state of Clang’s sources may not reflect this design. A prototype implementation was built on DXC which is Clang-3.7 based. The prototype can be found here. A lot of the changes in the prototype implementation are restoring Clang-3.7 code that was previously modified to its original state.

The implementation in clang adds a new non-decaying array type, a new AST node to represent output parameters, and minor extensions to Clang’s existing support for Objective-C write-back arguments. The goal of this design is to capture the semantic details of HLSL function calls in the AST, and minimize the amount of magic that needs to occur during IR generation.

Array Temporaries

The new ArrayParameterType is a sub-class of ConstantArrayType inheriting all the behaviors and methods of the parent except that it does not decay to a pointer during overload resolution or template type deduction.

An argument of ConstantArrayType can be implicitly converted to an equivalent non-decayed ArrayParameterType if the underlying canonical ConstantArrayType is the same. This occurs during overload resolution instead of array to pointer decay.

void SizedArray(float a[4]);
void UnsizedArray(float a[]);

void main() {
  float arr[4] = {1, 1, 1, 1};
  SizedArray(arr);
  UnsizedArray(arr);
}

In the example above, the following AST is generated for the call to SizedArray:

CallExpr 'void'
|-ImplicitCastExpr 'void (*)(float [4])' <FunctionToPointerDecay>
| `-DeclRefExpr 'void (float [4])' lvalue Function 'SizedArray' 'void (float [4])'
`-ImplicitCastExpr 'float [4]' <HLSLArrayRValue>
  `-DeclRefExpr 'float [4]' lvalue Var 'arr' 'float [4]'

In the example above, the following AST is generated for the call to UnsizedArray:

CallExpr 'void'
|-ImplicitCastExpr 'void (*)(float [])' <FunctionToPointerDecay>
| `-DeclRefExpr 'void (float [])' lvalue Function 'UnsizedArray' 'void (float [])'
`-ImplicitCastExpr 'float [4]' <HLSLArrayRValue>
  `-DeclRefExpr 'float [4]' lvalue Var 'arr' 'float [4]'

In both of these cases the argument expression is of known array size so we can initialize an appropriately sized temporary.

It is illegal in HLSL to convert an unsized array to a sized array:

void SizedArray(float a[4]);
void UnsizedArray(float a[]) {
  SizedArray(a); // Cannot convert float[] to float[4]
}

When converting a sized array to an unsized array, an array temporary can also be inserted. Given the following code:

void UnsizedArray(float a[]);
void SizedArray(float a[4]) {
  UnsizedArray(a);
}

An expected AST should be something like:

CallExpr 'void'
|-ImplicitCastExpr 'void (*)(float [])' <FunctionToPointerDecay>
| `-DeclRefExpr 'void (float [])' lvalue Function 'UnsizedArray' 'void (float [])'
`-ImplicitCastExpr 'float [4]' <HLSLArrayRValue>
  `-DeclRefExpr 'float [4]' lvalue Var 'arr' 'float [4]'

Out Parameter Temporaries

Output parameters are defined in HLSL as casting expiring values (cx-values), which is a term made up for HLSL. A cx-value is a temporary value which may be the result of a cast, and stores its value back to an lvalue when the value expires.

To represent this concept in Clang we introduce a new HLSLOutParamExpr. An HLSLOutParamExpr has two forms, one with a single sub-expression and one with two sub-expressions.

The single sub-expression form is used when the argument expression and the function parameter are the same type, so no cast is required. As in this example:

void Init(inout int X) {
  X = 1;
}

void main() {
  int V;
  Init(V);
}

The expected AST formulation for this code would be something like:

CallExpr 'void'
|-ImplicitCastExpr 'void (*)(int &)' <FunctionToPointerDecay>
| `-DeclRefExpr 'void (int &)' lvalue Function  'Init' 'void (int &)'
|-HLSLOutParamExpr 'int' lvalue inout
  `-DeclRefExpr 'int' lvalue Var 'V' 'int'

The HLSLOutParamExpr captures that the value is inout vs out to denote whether or not the temporary is initialized from the sub-expression. If no casting is required the sub-expression denotes the lvalue expression that the cx-value will be copied to when the value expires.

The two sub-expression form of the AST node is required when the argument type is not the same as the parameter type. Given this example:

void Trunc(inout int3 V) { }


void main() {
  float3 F = {1.5, 2.6, 3.3};
  Trunc(F);
}

For this case the HLSLOutParamExpr will have sub-expressions to record both casting expression sequences for the initialization and write back:

-CallExpr 'void'
  |-ImplicitCastExpr 'void (*)(int3 &)' <FunctionToPointerDecay>
  | `-DeclRefExpr 'void (int3 &)' lvalue Function 'inc_i32' 'void (int3 &)'
  `-HLSLOutParamExpr 'int3' lvalue inout
    |-ImplicitCastExpr 'float3' <IntegralToFloating>
    | `-ImplicitCastExpr 'int3' <LValueToRValue>
    |   `-OpaqueValueExpr 'int3' lvalue
    `-ImplicitCastExpr 'int3' <FloatingToIntegral>
      `-ImplicitCastExpr 'float3' <LValueToRValue>
        `-DeclRefExpr 'float3' lvalue 'F' 'float3'

In this formation the write-back casts are captured as the first sub-expression and they cast from an OpaqueValueExpr. In IR generation we can use the OpaqueValueExpr as a placeholder for the HLSLOutParamExpr’s temporary value on function return.

In code generation this can be implemented with some targeted extensions to the Objective-C write-back support. Specifically extending CGCall.cpp’s EmitWriteback function to support casting expressions and emission of aggregate lvalues.