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The only big catch that I ran into with this batch was that I found the `float.getPi()` function was being emitted to the output GLSL even when that function wasn't being used. This seems to have been a latent problem in the earlier PR, but was only surfaced in the tests once a Slang->GLSL test started using another intrinsic that led to the `float : __BuiltinFloatingPointType` witness table being live in the IR.
The fix for the gotcha here was to add a late IR pass that basically empties out all witness tables in the IR, so that functions that are only referenced by witness tables can then be removed as dead code. This pass is something we should *not* apply if/when we start supporting real dynamic dispatch through witness tables, but that is a problem to be solved on another day.
The remaining tricky pieces of this change were:
* Needed to remember to mark functions as target intrinsics on HLSL and/or GLSL as appropriate (hopefully I caught all the cases) so they don't get emitted as source there.
* The `msad4` function in HLSL is very poorly documented, so filling in its definition was tricky. I made my best effort based on how it is described on MSDN, but it is likely that if anybody wants to rely on this function they will need us to vet our results with some tests.
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* Update slang-binaries to verison with SPIR-V version support.
* Support vec and matrix Wave intrinsics on vk.
Added wave-vector.slang test
Add wave-diverge.slang test
Add support for more wave intrinsics to vk.
* Test out Wave intrinsic support for matrices.
* Remove matrix glsl intrinsics -> not available.
Fix some typo.
* Remove generated slang generated headers.
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* Update slang-binaries to verison with SPIR-V version support.
* Support vec and matrix Wave intrinsics on vk.
Added wave-vector.slang test
Add wave-diverge.slang test
Add support for more wave intrinsics to vk.
* Test out Wave intrinsic support for matrices.
* Remove matrix glsl intrinsics -> not available.
Fix some typo.
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The actual definitions that got moved into the stdlib here are pretty few:
* `clip()`
* `cross()`
* `dxx()`, `ddy()` etc.
* `degrees()`
* `distance()`
* `dot()`
* `faceforward()`
The meat of the change is infrastructure changes required to support these new declarations
* Generic versions of the standard operators (e.g., `operator+`) were added that are generic for a type `T` that implements the matching `__Builtin`-prefixed interface. An open question is whether we can now drop the non-generic versions in favor of just having these generic operators.
* A `__BuiltinLogicalType` interface was added to capture the commonality between integers and `bool`
* `__BuiltinArithmeticType` was extended so that implementations must support initialization from an `int`
* `__BuiltinFloatingPointType` was extended to require an accessor that returns the value of pi for the given type, and the concrete floating-point types were extended to provide definitions of this value.
* It turns out that our logic for checking if two functions have the same signature (and should thus count as redeclarations/redefinitions) wasn't taking generic constraints into account at all. That was fixed with a stopgap solution that checks if the generic constraints are pairwise identical, but I didn't implement the more "correct" fix that would require canonicalizing the constraints.
* When doing overload resolution and considering potential callees, logic was added so that a non-generic candidate should always be selected over a generic one (generally the Right Thing to do), and also so that a generic candidate with fewer parameters will be selected over one with more (an approximation of the much more complicated rule we'd ideally have).
* The formatting of declarations/overloads for "ambiguous overload" errors was fleshed out a bit to include more context (the "kind" of declaration where appropriate, the return type for function declarations) and to properly space thing when outputting specialization of operator overloads that end with `<` (so that we print `func < <int>(int, int)` instead of just `func <<int,int>(int,int)`).
* The core lookup routines were heavily refactored and reorganized to try to make them bottleneck more effectively so that all paths handle all the nuances of inheritance, extensions, etc.
* Because of the refactoring to lookup logic, the semantic checking logic related to checking if a type conforms to an interface was updated to be driven based on the `Type` that is supposed to be conforming, rather than a `DeclRef` to the type's declaration. This allows it to use the type-based lookup entry point and eliminates one special-case entry point for lookup.
In addition to the various core changes, this change also refactors some of the existing stdlib code to favor writing more things in actual Slang syntax, and less in C++ code that uses `StringBuilder` to construct the Slang syntax. There is a lot more that could be done along those lines, but even pushing this far is showing that the current approach that `slang-generate` takes for how to separate meta-level C++ and Slang code isn't really ideal, so a revamp of the generator code is probably needed before I continue pushing.
One surprising casualty of the refactoring of lookup is that we no longer have the `lookedUpDecls` field in `LookupResult`. That field probably didn't belong there anyway, but the role it served was important. The idea of `lookedUpDecls` was to avoid looking up in the same interface more than once in cases where a type might have a "diamond" inheritance pattern. Removing that field doesn't appear to affect correctness of any of our existing tests, but by adding a specific test for "diamond" inheritance I could see that the refactoring introduced a regression and made looking up a member inherited along multiple paths ambiguous.
Rather than add back `lookedUpDecls` I went for a simpler (but arguably even hackier) solution where when ranking candidates from a `LookupResult` we check for identical `DeclRef`s and arbitrarily favor one over the other. One complication that arises here is that when comparing `DeclRef`s inherited along different paths they might have a `ThisTypeSubstitution` for the same type, but with different subtype witnesses (because different inheritance paths could lead to different transitive subtype witnesses: e.g., `A : B : D` and `A : C : D`).
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embedding. (#1257)
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* WIP add support for __spirv_version .
* Added IRRequireSPIRVVersionDecoration
* SPIR-V version passed to glslang.
Enable VK wave tests.
Split ExtensionTracker out, so can be cast and used externally to emit.
Added SourceResult.
* Fix warning on Clang.
* Missing hlsl.meta.h
* Refactor communication/parsing of __spirv_version with glslang.
* Fix some debug typos.
Be more precise in handling of substring handling.
* Make glslang forwards and backwards binary compatible.
* Small comment improvements.
* Added slang-spirv-target-info.h/cpp
* Fix for major/minor on gcc.
* Another fix for gcc/clang.
* VS projects include slang-spirv-target-info.h/cpp
* Removed SPIRVTargetInfo
Added SemanticVersion.
Don't bother with passing a target to glslang. Should be separate from 'version'.
* Renamed slang-emit-glsl-extension-tracker.cpp/.h -> slang-glsl-extension-tracker.cpp/.h
Fixed some VS project issues.
* Fix a comment.
* Added slang-semantic-version.cpp/.h
* Added slang-glsl-extension-tracker.cpp/.h
* Added split that can check for input has all been parsed.
* Fix problem on x86 win build.
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* WIP add support for __spirv_version .
* Added IRRequireSPIRVVersionDecoration
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Some of the functions declared in the Slang standard library are built in on some targets (almost always the case for HLSL) but aren't available on other targets (often the case for GLSL, CUDA, and CPU). To date, the CUDA and CPU targets have worked around this issue by synthesizing definitions of the missing functions on the fly as part of output code generation, at the cost of some amount of code complexity in the emit pass.
This change adds definitions inside the stdlib itself for a large number of built-in HLSL functions that act element-wise over both vectors and matrices (e.g., `sin()`, `sqrt()`, etc.), and changes the CPU/CUDA codegen path to *not* synthesize C++ code for those functions (instead relying on code generated from the Slang definitions).
The element-wise vector/matrix function bodies are being defined using macros in the stdlib, so that we can more easily swap out the definitions en masse if we find an implementation strategy we like better. This could involve defining special-case syntax just for vector/matrix "map" operations that can lower directly to the IR and theoretically generate cleaner code after specialization is complete.
As a byproduct of this change, the matrix versions of these functions should in principle now be available to GLSL (GLSL only defines vector versions of functions like `sin()`, and leaves out matrix ones). No testing has been done to confirm this fix.
In some cases builtins were being declared with multiple declarations to split out the HLSL and GLSL cases, and this change tries to unify these as much as possible into single declarations to keep the stdlib as small as possible.
Two functions -- `sincos()` and `saturate()` -- were simple enough that their full definitions could be given in the stdlib so that even the scalar cases wouldn't need to be synthesized, so the corresponding enumerants were removed in `slang-hlsl-intrinsic-set.h`. In the case of `saturate()` the pre-existing definition used for GLSL codegen could have been used for CPU/CUDA all along.
In some cases functions that can and should be defined in the future have had commented-out bodies added as an outline for what should be inserted in the future. Most of these functions cannot be implemented directly in the stdlib today because basic operations like `operator+` are currently not defined for `T : __BuiltinArithmeticType`, etc. Adding such declarations should be straightforward, but brings risks of creating unexpected breakage, so it seemed best to leave for a future change.
This change does not try to address making vector or matrix versions of builtin functions that map to single `IROp`s, because the existing mechanisms for target-based specialization, etc., do not apply for such cases. In the future we will either have to make those operations into ordinary functions (eliminating many `IROp`s) so that stdlib definitions can apply, or add an explicit IR pass to deal with legalizing vector/matrix ops for targets that don't support them natively. The right path for this is not yet clear, so this change doesn't wade into it.
This change does not touch the `Wave*` functions added in Shader Model 6, despite many of these having vector/matrix versions that could benefit from the same default mapping. It is expected that these functions will have GLSL/Vulkan translation added soon, and it probably makes sense to know what cases are directly supported on Vulkan before adding the hand-written definitions.
Because of the limitations on what could be ported into the stdlib, it is not yet possible to remove any of the infrastructure for synthesizing builtin function definitions in the CPU and CUDA back-ends.
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* Test for some wave intrinsics.
More wave intrinsic support on CUDA.
* Use shfl_xor_sync.
* Improvements around wave intrinsics.
Fix built in integer types belong to __BuiltinIntegerType.
* Improvements and fixes around Wave intrinsics.
* Added WaveIsFirstLane test.
No longer use __wavemask_lt, as appears not available as an intrinsic.
* Small fixes to CUDA prelude.
* Add wave-active-product test.
Handle the special case for arbitray sums.
* Used macro to implement CUDA wave intrinsics.
* First pass at glsl wave intrinsics. Doesn't work in practice because require mechanism to set spir-v version
Replace use of _lanemask_lt() for CUDA.
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* Test for some wave intrinsics.
More wave intrinsic support on CUDA.
* Use shfl_xor_sync.
* Improvements around wave intrinsics.
Fix built in integer types belong to __BuiltinIntegerType.
* Improvements and fixes around Wave intrinsics.
* Added WaveIsFirstLane test.
No longer use __wavemask_lt, as appears not available as an intrinsic.
* Small fixes to CUDA prelude.
* Add wave-active-product test.
Handle the special case for arbitray sums.
* Used macro to implement CUDA wave intrinsics.
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* WIP slang-profile
* Turn on symbols needed for profile.
* Remove calls to slang API from core as doing so broke profiling information.
Fix premake so slang-profile works on VS.
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* Constant time dynamic cast.
* Use getClassInfo virtual function.
Fix problem because of instanciation of specializations was in wrong order for clang.
* Improve comments.
* Improve comment.
* Ensure s_first is defined before kClassInfo, to ensure construction ordering.
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We currently represent the `groupshared` qualifier as a kind of "rate" at the IR level (where a rate can qualify a type to indicate the frequency/rate at which a value is stored and/or computed). This means that when computing the type that a pointer points to, we need to handle both, e.g., `Ptr<Int>` and `@GroupShared Ptr<Int>`.
The logic that was trying to handle the rate-qualified case when deducing the "pointee" type of a pointer was somehow written incorrectly, and was querying `getDataType()` on an `IRRateQualifiedType` which is asking for the type of the type itself (null in this case), rather than `getValueType()` which gets the `T` part from a rate-qualified type `@R T`.
Somehow none of our tests were hitting this case, and I'm not immediately clear on how to write a targeted reproducer for this, since the problem arose as a debug-only assertion failure in a user shader with thousands of lines.
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* Fix for GCC C++ target - remove warning for int literal value.
* Comment around hack to negate -0x8000 0000
* Special case negation of literals in parser - to fix problems with errors on gcc.
* Apply the literal integer 'fix' when doing negation of a literal.
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* Added FloatTextureData as a mechanism to enable CPU based Texture writes.
* Add [] RWTexture access for CPU.
* Fixed rw-texture-simple.slang.expected.txt
* WIP: CUDA stdlib has support for [] surface access.
* Made IRWTexture class able to take different locations.
Doing a Texture2d access on CUDA works.
* Fix bug in outputing UniformState - was missing out padding.
Support RWTexture with array. Support RWTexture3D.
* Use * for locations for read only textures, so only need a ITexture interface.
* Fix problem around application of set/get for CUDA on subscript Texture types.
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This arose when a user tried to specialize the DXR 1.1 `RayQuery` type to a local variable:
```hlsl
RAY_FLAG rayFlags = RAY_FLAG_CULL_FRONT_FACING_TRIANGLES | RAY_FLAG_CULL_NON_OPAQUE;
RayQuery<rayFlags> query;
```
In this case, we issued an error around `rayFlags` not being a constant as expected, but then we also crashes later on in checking because the `DeclRef` that was being used for the type had a null pointer for the generic argument corresponding to `rayFlags`.
The main fix here was thus to add an `ErrorIntVal` case that can be used to represent something that should be an `IntVal` but where there was some kind of error in the input code so that the actual value isn't known to the compiler.
A secondary fix here is that we were issuing error messages about expecting a constant for a parameter like `rayFlags` there *twice*, and one of those times was during the `JustChecking` part of overload resolution (when we are not supposed to emit any diagnostics). I fixed that up by allowing the `DiagnosticSink` to be used to be passed down explicitly (and allowing it to be null), while also leaving behind overloaded functions with the old signatures so that all the existing logic can continue to work unmodified.
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These new cases were added in DXR 1.1 (Shader Model 6.5), while the `enum` type came from DXR 1.0, so that I failed to revisit it when adding the new features.
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There were two overlapping issues here:
1. We always mapped `SV_Coverage` to `gl_SampleMask`, even though `gl_SampleMaskIn` is the correct built-in variable to use for an input varying.
2. We treated `gl_SampleMask` like it was a scalar shader input, when it and `gl_SampleMaskIn` are actually arrays of indeterminate size (as a byproduct of trying to future-proof for implementations that might support hundreds or thousands of samples per pixel...)
The fix here is simple: map to either `gl_SampleMask[0]` or `gl_SampleMaskIn[0]` as appropriate. I suppose that this approach doesn't handle the possibility of eventually supporting >32 samples per pixel by having something like `uint2 coverage : SV_Coverage`, but I think we can cross that bridge when we come to it.
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Just adding the enumerants for the new stages/profiles didn't automatically update the code that computes a profile string for passing to fxc/dxc.
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Within the context of an aggregate type (or an `extension` of one), the programmer can use `this` to refer to the "current" instance of the surrounding type, but there is no easy way to utter the name of the type itself. This is especially relevant inside of an `interface`, where the type of `this` isn't actually the `interface` type, but rather a placeholder for the as-yet-unknown concrete type that will implement the interface.
This change adds a keyword `This` that works similarly to `this`, but names the current *type* instead of the current instance. It can be used to declare things like binary methods or factory functions in an interface:
```
interface IBasicMathType
{
This absoluteValue();
This sumWith(This left);
}
T doSomeMath<T:IBasicMathType>(T value)
{
return value.sumWith(value.absoluteValue());
}
```
The `This` type is consistent with the type named `Self` in Rust and Swift (where Rust/Swift use `self` instead of `this`). Other names could be considered (e.g., `ThisType`) if we find that users don't like the name in this change.
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This change makes it so that for a suitable type `MyType`, a variable declaration like:
MyType v;
is treated as if it were written:
MyType v = MyType();
The definition of "suitable" here is that `MyType` needs to have an available `__init` declaration that can be invoked with zero arguments. I've added a test to confirm that the new behavior works in this specific case.
There are a bunch of caveats to the feature as it stands today:
* Just because `MyType` has a zero-parameter `__init`, that doesn't mean an array type like `MyType[10]` does, so arrays currently remain uninitialized by default. Fixing this gap requires careful consideration because some, but not all, array types should be default-initializable.
* The change here should mean that a `struct` type with a field like `MyType f;` should count as having a default initial-value expression for that field, but I haven't confirmed that.
* Even if a `struct` provides initial values for all its fields (e.g., `struct S { float f = 0; }`), that doesn't mean it has a default `__init` right now, so those `struct` types will still be left uninitialized by default. Converging all this behavior is still TBD.
Just to be clear: there is no provision or plan in Slang to support destructors, RAII, copy constructors, move constructors, overloaded assignment operations, or any other features that buy heavily into the C++ model of how construction and destruction of values gets done.
In fact, I'm not even 100% sure I like having this change in place at all, and I think we should reserve the right to revert it and say that only specific stdlib types get to opt in to default initialization along these lines.
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* CUDA support for array of resources.
* * Add support for Texture2DArray on CPU
* Expand texture-simple.slang to test Texture2DArray
* Reorganise CUDAComputeUtil to split out createTextureResource.
* Add TextureCubeArray support for CPU/CUDA targets.
* Pulled out CUDAResource
Renamed derived classes to reflect that change.
* Creation of SurfObject type.
* Functions to return read/write access for simplifying future additions.
* WIP for RWTexture access on CPU/CUDA.
* CUsurfObject cannot have mips.
* Ability to set number of mips on test data.
Preliminary support for CUsurfObj and RWTexture1D on CUDA.
CUDA docs improvements.
* Fix typo.
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The basic idea is that the user can write:
```hlsl
struct MyThing
{
int a;
float b;
__init(int x, float y)
{
a = x;
b = y;
}
}
```
and after that point, they can create an intstance of their `MyThing` type as simply as `MyThing(123, 4.56f)`.
There was already a large amount of infrastructure laying around that is shared between ininitializers and ordinary functions, so enabling this feature mostly amounted to tying up some loose ends:
* In the parser, make sure to properly push/pop the scope for an `__init` (or `__subscript`) declaration, so parameters would be visible to the body
* In semantic checking, make sure that declaration "header" checking properly bottlenecks all the function-like cases into a base routine
* In semantic checking, make sure that the logic for checking function bodies applies to every `FunctionDeclBase` with a body, and not just `FuncDecl`s
* Update semeantic checking for statements to allow for any `FunctionDeclBase` as the parent declaration, not just a `FuncDecl`
* In lookup, treat the `this` parameter of an `__init` (well, not actually a *parameter* in this case) as being mutable, just like for a `[mutating]` method
* In IR codegen, don't just assume that all `__init`s are intrinsics, and narrow the scope of that hack to just `__init`s without bodies
* In IR codegen, detect when we are emitting an IR function for an `__init`, and in that case create a local variable to represent the `this` value, and implicitly return that value at the end of the body.
From that point on the rest of the compiler Just Works and IR codegen doesn't have to think of an `__init` as being any different than if the user had declared a `static MyThing make(...)` function.
Caveats:
* C++ users might like to use that naming convention (so `MyThing` as the name instead of `__init`). We can consider that later.
* Everybody else might prefer a keyword other than `__init` (e.g., just `init` as in Swift), but I'm keeping this as a "preview" feature for now, rather than something officially supported
* Early `return`s from the body of an `__init` aren't going to work right now.
* There is currently no provision for automatically synthesizing initializers for `struct` types based on their fields. This seems like a reasonable direction to take in the future.
* There is no provision for routing `{}`-based initializer lists over to initializer calls. The two syntaxes probably need to be unified at some point so that doing `MyType x = { a, b, c }` and `let x = MyType(a, b, c)` are semantically equivalent.
It is possible that as a byproduct of this change user-defined `__subscript`s might Just Work, but I am guessing there will still be loose ends on that front as well, so I will refrain from looking into that feature until we have a use case that calls for it.
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When a shader only uses `ParameterBlock`s plus a single buffer for root constants:
```hlsl
ParameterBlock<A> a;
ParameterBlock<B> b;
[[vk::push_constant]] cbuffer Stuff { ... }
```
we expect the push-constant buffer should not affect the `space` allocated to the parameter blocks (so `a` should get `space=0`).
This behavior wasn't being implemented correctly in `slang-parameter-binding.cpp`. There was logic to ignore certain resource kinds in entry-point parameter lists when computing whether a default space is needed, but the equivalent logic for the global scope only considered parameters that consuem whole register spaces/sets.
This change shuffles the code around and makes sure it considers a global push-constant buffer as *not* needing a default space/set.
Note that this change will have no impact on D3D targets, where `Stuff` above would always get put in `space0` because for D3D targets a push-constant buffer is no different from any other constant buffer in terms of register/space allocation.
One unrelated point that this change brings to mind is the `[[vk::push_constant]]` should ideally also be allowed to apply to an entry point (where it would modify the default/implicit constant buffer). In fact, it could be argued that push-constant allocation should be the *default* for (non-RT) entry point `uniform` parameters (while `[[vk::shader_record]]` should be the default for RT entry point `uniform` parameters).
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This is pretty straightforward, because we were calling `Session::init` (which can retain/release the session) on a `Session*` (no reference held).
The catch is that our current tests use the older form of the Slang API, while Falcor relies on the newer API, and so the recent change to our reference-counting logic introduced a regression that we didn't detect in testing.
This change just fixes the direct issue but doesn't address the gap in testing. A better long-term fix would be to fully define our "1.0" API, shift our testing to it, and layer the old API on top of it (to try and avoid regressions for client code).
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* Start work on wave intrinsics for CUDA.
* Add prelimary CUDA support for some Wave intrinsics.
Document the issue around WaveGetLaneIndex
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The previous change that added `RayQuery` to the standard library didn't mark it as any kind of intrinsic, so the first fix here was to add the appopriate attribtue to the stdlib declaration of `RayQuery`.
Next I found that the legalization pass was obliterating the `RayQuery` type because it had no members, and thus looked like an empty `struct` (which we eliminate for a variety of reasons). I fixed that by adding a check for a target-intrinsic decoration in type legalization.
Next I found that the type wasn't emitted correctly because our generic specialization was turning `RayQuery<0>` into a new type `RayQuery_0` (which is what our specialization is designed to do, after all).
I then disabled generic specialization for types that are marked as target intrinsics (which probably renders the preceding fix moot).
Finally, I found that the emit logic for types in HLSL wasn't handling the case of a generic intrinsic type that didn't also use its own dedicated opcode. I fixes that up by adding a specific case for `IRSpecialize` as a late catch-all.
After all these changes, a declaration of a `RayQuery` variable seems to Just Work (even without any new/improved behavior for handling default constructors).
One potential gotcha looking forward is that my checks for `IRTargetIntrinsicDecoration` aren't checking what target the decoration is for. This is fine for now because there are only two types using the decoration right now (`RayDesc` and `RayQuery`), and the special cases above are reasonable for both of them. If/when we have more target-intrinsic types with this decoration, and some of them are only intrinsic for specific targets, then we will need to revisit this choice and either:
* make these checks perform filtering based on the "current" target (similar to what the emit logic has today), or
* (more likely) make the linking and target-specialization step strip out any target-intrinsic decorations that aren't the right one(s) for the current target
Note that this change doesn't include a test case yet because I don't have a DXR 1.1 ready version of dxc to test against. I have manually confirmed that appropriate Slang input seems to be producing reasonable HLSL output when using these functions, but I cannot yet try to check that in (using an HLSL file for the expected output would be quite fragile).
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* Added support for Targets to TypeTextUtil.
* Made Function names 'get' and 'find' instead of 'as' in TypeTextUtil.
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* Add cubemap support.
* Add CUDA fence instrinsics.
* Added Gather for CUDA.
* Use the CUDA driver API as much as possible.
* * Support 1D texture on CPU
* WIP on 1D texture on CUDA
* Added simplified texture test
* Fix test.
* Improve texture-simple tests.
* * Add CPU support for 3d textures
* Add support for mip maps to CUDA
* Disable warnings in nvrtc
* Update CUDA docs
* WIP on 3d texture support.
* Add support for 3d textures for CPU and CUDA.
* CPU and CUDA support for cube maps.
* Add CPU support for Texture1DArray.
* Support CUDA Layered/Array type in meta library.
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* Add cubemap support.
* Add CUDA fence instrinsics.
* Added Gather for CUDA.
* Use the CUDA driver API as much as possible.
* * Support 1D texture on CPU
* WIP on 1D texture on CUDA
* Added simplified texture test
* Fix test.
* Improve texture-simple tests.
* * Add CPU support for 3d textures
* Add support for mip maps to CUDA
* Disable warnings in nvrtc
* Update CUDA docs
* WIP on 3d texture support.
* Add support for 3d textures for CPU and CUDA.
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* Add cubemap support.
* Add CUDA fence instrinsics.
* Added Gather for CUDA.
* Use the CUDA driver API as much as possible.
* * Support 1D texture on CPU
* WIP on 1D texture on CUDA
* Added simplified texture test
* Fix test.
* Improve texture-simple tests.
Co-authored-by: Tim Foley <tfoleyNV@users.noreply.github.com>
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The main thing this adds is the `RayQuery` type with its `TraceRayInline` method for DXR 1.1.
None of these new functions/types/constants have been tested, and many of them are not expected to work at all (e.g., we don't actually have any mesh shader support, so adding them as stage types is just for completeness at the API level).
I would like to write some test cases after this is checked in by looking for existing DXR 1.1 examples. We currently have an issue around default initialization that means we probably can't run any DXR 1.1 shaders right now with just the stdlib changes.
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* Test to check fix
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* Added 'truncate' for fixing floats, for floats near the max value (as opposed to making infinite).
Put AreNearlyEqual into Math
* Test for ::make static method.
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* Added support ldexp.
* Added classify-float.slang test
Fixed glsl output.
* Added classify-double.slang
* Added ldexp test to scalar-double.slang
* isnan, isinf, isfinite are macros (on some targets) so remove :: prefix.
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* * Improved fastRemoveAt
* Fixed off by one bug
* Fixed const safeness with List<>
* Made List begin and end const safe.
* Revert to previous RefPtr usage.
* Fix bug with casting.
* Tabs -> spaces.
Small fixes/improvements to List.
* Improve comment on List.
* Group shared/atomic test works on CUDA.
* * Enabled CUDA tests for atomics tests
* Enabled DX12 test for atomics-buffer.slang
Not clear just yet how to implement that for CUDA - it will work with StructuredBuffer.
* hasContent -> isNonEmpty
* Remove unneeded comment.
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* * Improved fastRemoveAt
* Fixed off by one bug
* Fixed const safeness with List<>
* Made List begin and end const safe.
* Revert to previous RefPtr usage.
* Fix bug with casting.
* Tabs -> spaces.
Small fixes/improvements to List.
* Improve comment on List.
* hasContent -> isNonEmpty
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There are two main fixes here:
The first is to remove a memory leak in the reflection test tool, in the case where Slang compilation fails. There is no real reason to be using the reflection test tool for tests that produce diagnostics (we have the slangc tool for that), but it makes sense to go ahead and fix the leak rather than work around it. This was one of those leaks that could have been avoided with smart pointers and a COM-lite API.
The second issue was that the logic for constructing an `AttributeDecl` based on a user-defined `struct` was not correctly setting the parent of the attribute decl. The code in question was a little hard to follow and had a few steps that didn't seem strictly necessary given its goals, so I went ahead and scrubbed+commented it to just do what made sense to me (and the tests still pass...).
I'm not entirely happy with the design and implementation approach for user-defined attributes, so we might want to take another stab at it sooner or later. This change is not meant to address any design issues, and is just about fixing bugs in what is already there.
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We had been translating an `SV_PrimitiveID` input in a shader over to `gl_PrimitiveID` in GLSL.
That translation seemed to work just fine for users, so we thought it was correct.
It turns out that `gl_PrimitiveID` is the correct GLSL for a primitive ID input in every stage *except* a geometry shader.
In a geometry shader, `gl_PrimitiveID` is a primitive ID *output*, and if you want the input case you have to write `gl_PrimitiveIDIn` (note the `In` suffix).
This change sets aside my bewilderment at the above long enough to implement a workaround in the GLSL legalization step.
I also modified our current geometry shader cross compilation test to make use of an input primitive ID.
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This change adds support for the `[[vk::location(...)]]` and `[[vk::index(...)]]` attributes, which can be used together to mark up shader outputs for dual-source blending on Vulkan. HLSL/Slang code like the following:
```hlsl
struct Output
{
[[vk::location(0)]]
float4 a : SV_Target0;
[[vk::location(0), vk::index(1)]]
float4 b : SV_Target1;
}
[shader("fragment")]
Output main(...) { ...}
```
can be used to set up dual-source blending on both D3D and Vulkan APIs. The output GLSL for the above will look something like:
```glsl
layout(location = 0) out vec4 a;
layout(location = 0, index = 1) out vec4 b;
void main() { ... }
```
The more or less straightforward parts of this change were:
* Added new `attribute_syntax` declarations to the stdlib, for `[[vk::location(...)]]` and `[[vk::index(...)]]`
* Added new AST node types for the new attribute cases, sharing a base class so that argument checking can be shared
* Added checks for the arguments to the new attributes in `slang-check-modifier.cpp` (eventually this kind of logic shouldn't be needed for new attributes)
* Updated GLSL emit logic so that it treats the `index`/`space` parts of a variable layout as the `location`/`index` for varying parameters.
* Updated GLSL legalization so that when it translates entry-point parameters into globals (and scalarizes structures) it handles both a binding index and space for the parameters.
* Added a cross-compilation test case to verify that the basics of the feature work
The remaining work is all in `slang-parameter-binding.cpp`.
There is some work that isn't technically related to this change (and which could be reverted if it causes problems), around the detection and handling of fragment shader outputs with `SV_Target` semantics. The basic changes (which could be backed out and then merged separately) are:
* Made the special-case `SV_Target` logic only trigger for fragment shaders (that is the only place where `SV_Target` should appear, but we weren't guarding against it)
* Made the logic to reserve a `u<N>` register for `SV_Target<N>` only trigger for D3D Shader Model 5.0 and below (since it is not required for SM 5.1 and up). This could be a breaking change for some users, but that seems unlikely.
* Fixed one test case that relied on the behavior of reserving `u0` for `SV_Target0` even though it was a SM6.0 test.
* Also added more comments to the system-value handling logic.
The more interesting changes come up starting in `processEntryPointVaryingParameterDecl()`. The basic issue is that we have so far only supported implicit layout for varying parameters on GLSL/Vulkan, but the `[[vk::location(...)]]` attribute is a form of explicit layout annotation. Rather than try to kludge something that only works in narrow cases, I instead opted to try to fix things more generally.
In `processEntryPointVaryingParameterDecl()` we now check for the `location` and `index` attributes when we are on "Khronos" targets (Vulkan/OpenGL/GLSL) and immediately add them to the variable layout being constructed if they are found. There is nothing in this logic specific to fragment-shader outputs, so this feature now applies to any varying input/output on Khronos targets.
Allowing explicit layouts creates the potential for mixing implicit and explicit layout. For example, consider:
```hlsl
struct Output
{
float4 color : COLOR;
[[vk::location(0)]] float3 normal : NORMAL;
}
```
What `location` should `color` get? Should this code be an error? There are two cases where this conundrum can come up: when working with `struct` types used for varying parameters, and the entry-point parameter list itself.
For the varying `struct` case we currently make an expedient choice. We handle fields with both implicit or explicit layotu with appropriate logic, but logic that doesn't account for the case of mixing the two. Then at the end of layout for the `struct` we issue an error if there was a mix of implicit and explicit layout (such that our results aren't likely to be valid).
For the entry point varying parameter case, things were already using a `ScopeLayoutBuilder` type (that encapsulates some logic shared between entry-point and global parameters). The entry-point-specific bits were moved out into a `SimpleScopeLayoutBuilder` and it was updated so that rather than assuming all parameters use implicit layout it does a two-phase layout approach similar to what we use for the global scope:
* First all parameters are enumerated to collect explicit bindings and mark certain ranges as "used"
* Next the parameters are enumerated again and those without explicit bindings get allocated space using a "first fit" algorithm
In principle we could extend the two-phase approach to apply to `struct` types as well, but that would be best saved for a future refactoring of some of this parameter binding logic, since I would like to exploit more of the opportunities for sharing code across the uniform/varying and struct/entry-point/global cases.
By moving the point where entry point parameters get their offsets assigned, it was necessary to move around some of the logic that removes varying parameter usage (and other things that shouldn't "leak" out of an entry point) to a different point in the entry point layout process.
While adding these various pieces does not quite enable us to support explicit bindings on entry point parameters (e.g., putting `uniform Texture2D t : register(t0)` in an entry point parameter list) or in `struct` types (e.g., explicit `packoffset` annotations on fields), it starts to provide some of the infrastructure that we'd need in order to support those cases.
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* Launch CUDA test taking into account dispatch size.
* Enable isCPUOnly hack to work on CUDA.
* Rename 'isCPUOnly' hack to 'onlyCPULikeBinding'.
* Add $T special type.
Support SampleLevel on CUDA.
* Fix typo.
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* Upper camel -> lowerCamel
m_ prefix members where appropriate
_ prefix module local functions
* m_ prefix members in Lexer. Fit's standard because type has methods/ctor.
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* Fix CPP construct when matrix type.
* Test intrinsics on float matrices.
* Fix typo in _areNearlyEqual test. Increased default sensitivity.
Added matrix-float test.
* Matrix double test.
Fixed some issues with CUDA.
* Added reduced intrinsic version of matrix-double test.
* Improve matrix double coverage.
Test reflect/length etc on vector float.
* * Added literal-float test.
* Added vector double test
* Improved coverage of vector/matrix tests
* Disable Dx11 double-vector test because fails on CI.
* Disable literal-float, because on CI fails.
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* Change handling of strings for HLSL/GLSL targets
This change switches our handling of string literals and `getStringHash` to something that is more streamlined at the cost of potentially being less general/flexible.
* `String` is now allowed as a parameter type in user-defined functions
* `getStringHash` is now allowed to apply to `String`-type values that aren't literals
* The list of strings in an IR module is now generated during IR lowering as part of lowering a string literal expression, rather than being defined by recursively walking the IR of the module looking for `getStringHash` calls. The public API still refers to these as "hashed" strings, but they are realistically now "static strings."
* When emitting code for HLSL/GLSL, the `String` type emits as `int`, and `getStringHash(x)` emits as `x`.
In terms of implementation, the choice was whether to translate `String` over to `int` in an explicit IR pass, or to lump it into the emit pass. While adding the logic to emit clutters up an already complicated step, it is ultimately much easier to make the change there than to write a clean IR pass to eliminate all `String` use.
Note that other targets that can handle a more full-featured `String` type are *not* addressed by this change and thus do not support `String` at all. It may be woth emitting `String` as `const char*` on those targets, and emitting string literals directly, but the `getStringHash` function would need to be implemented in the "prelude" then, and we probably want to pick a well-known/-documented hash algorithm before we go that far.
This change also brings along some some clean-ups to the `gpu-printing` example, since it can now take advantage of the new functionality of `String`.
* Fix up tests for new string handling
* Add global string literal list to string-literal test (since we now list *all* static string literals and not just those passed to `getStringHash`)
* Disable `getStringHash` test on CPU, since we don't have a working `String` on that platform right now (only HLSL/GLSL)
Co-authored-by: Tim Foley <tim.foley.is@gmail.com>
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* Fix CPP construct when matrix type.
* Test intrinsics on float matrices.
* Fix typo in _areNearlyEqual test. Increased default sensitivity.
Added matrix-float test.
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* WIP: 64 literal diagnostic and truncation.
* Improve how integer truncation is handled/supported.
Added literal-int64.slang test.
Set a suffix on all literals.
Fixed problem on C++ based targets where l suffix was not the same as int() cast. So on C++ derived emitters, int() is used instead of l suffix to have same behavior across targets.
* Add literal diagnostic testing.
* Allow lexer to lex - in front of literals.
* Fix lexing and converting int literal with -.
* Too large small values of floats become inf.
Handling writing inf types out on different targets.
Add function to deterimine if a float literals kind.
* Roll back the support of lexer lexing negative literals.
* Fixed tests broken because of diagnostics numbers.
Improved _isFinite
* Fix compilation on linux.
* Fix problem with abs on linux - use Math::Abs.
* Fix typo.
* * Improve warnings for float literals zeroed
* Improved 64 bit type documentation
* Handle half
* Improved comments
* Fixed tests broken
* Use capital letters for suffixes.
* Make default behavior on outputting a int literal that is an 'int32_t' is cast (not suffix) to avoid platform inconsistencies.
Improve documentation for 64 bit types.
Make tests cover material in docs.
* Fixed tests.
* Rename FloatKind::Normal -> Finite
* Fix half zero check.
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* Improve checks and diagnostics around redeclarations
This change turns checking for redeclarations into a dedicated phase of semantic checking, and ensures that it applies to the main categories of declarations: functions, types, and variables.
Note that "variables" here includes function parameters and `struct` fields in addition to the more obvious global and local variables.
Some of the logic for checking redeclarations already existed for functions, and was refactored to deal with other cases of declarations. The checking for functions still needs to be special-cased because functions are much more flexible about the kinds of redeclarations that are allowed.
In addition to improving the diagnosis of redeclaration itself, this change also changes the error message that is produced when referencing a symbol that is ambiguous due to begin redeclared.
This is a small quality-of-life fix, and has the benefit of being much easier to implement than robust tracking of what variables have had redeclaration errors issued so that we can skip emitting an ambiguity error at the use site.
A new test case was added to cover the redeclaration cases for variables (but not types or functions), and the test for function parameters was updated to account for the new more universal diagnostic message (since function parameters used to have special-case redeclaration checking).
* fixup: missing file
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