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2017-11-13Parameter block work (#276)Tim Foley
* Don't auto-enable IR use for compute tests The `COMPARE_COMPUTE` and `COMPARE_RENDER_COMPUTE` test fixtures were set up to always enable the `-use-ir` flag on Slang, which precludes having any tests that confirm functionality on the old non-IR path (which is still required by our main customer). This change adds the `-xslang -use-ir` flags explicitly to any compute test cases that left them out, and makes the fixture no longer add it by default. * Continue building out parameter block support The initial front-end logic for parameter blocks was already added, but they are still missing a bunch of functionality. This change addresses some of the known issues: - Bug fix: don't try to emit HLSL `register` bindings for variables that consume whole register spaces/sets - Overhaul type layout logic so that it can make decisions based on a given code generation target (currently passed in as a `TargetRequest`), which allows us to decide whether or not a parameter block should get its own register set on a per-target basis. - Always use a register space/set for Vulkan - Never use a register space/set for HLSL SM 5.0 and lower - By default, don't use register spaces/sets for HLSL output - Add a command-line flag and some "target flags" to enable register-space usage for D3D targets - Hackily add initial support for parameter blocks in the AST-to-AST path - This just blindly lowers `ParameterBlock<T>` to `T`, which shouldn't quite work - A more complete overhaul will probably need to wait until the AST-to-AST legalization is changed to use the `LegalType`s from the IR legalization pass. - Add a compute-based test case to actually run code using parameter blocks - This file runs test cases both with and without the IR
2017-11-06Parameter blocks (#245)Tim Foley
* Rename existing ParameterBlock to ParameterGroup We are planning to add a new `ParameterBlock<T>` type, which maps to the notion of a "parameter block" as used in the Spire research work. Unfortunately, the compiler codebase already uses the term `ParameterBlock` as catch-all to encompass all of HLSL `cbuffer`/`tbuffer` and GLSL `uniform`/`buffer`/`in`/`out` blocks (all of which are lexical `{}`-enclosed blocks that define parameters...). This change instead renames all of the existing concepts over to `ParameterGroup`, which isn't an ideal name, but at least doesn't directly overlap the new terminology or any existing terminology. The new `ParameterBlockType` case will probably be a subclass of `ParameterGroupType`, since it is a logical extension of the underlying concept. * Add Shader Model 5.1 profiles The HLSL `register(..., space0)` syntax is only allowed on "SM5.1" and later profiles (which is supported by the newer version of `d3dcompiler_47.dll` that comes with the Win10 SDK, but not the older version of `d3dcompiler_47.dll` - good luck figuring out which you have!). This change adds those profiles to our master list of profiles, and nothing else. * First pass at support for `ParameterBlock<T>` - Add the type declaration in stdlib - Add a special case of `ParameterGroupType` for parameter blocks - Handle parameter blocks in type layout (currently handling them identically to constant buffers for now, which isn't going to be right in the long term) - Add an IR pass that basically replaces `ParameterBlock<T>` with `T` - Eventually this should replace it with either `T` or `ConstantBuffer<T>`, depending on whether the layout that was computed required a constant buffer to hold any "free" uniforms - Add first stab at an IR pass to "scalarize" global variables using aggregate types with resources inside. - This currently only applies to global variables, so it won't handle things passed through functions, or used as local variables - It also only supports cases where the references to the original variable are always references to its fields, and not the whole value itself - Add a single test case that technically passes with this level of support, but probably isn't very representative of what we need from the feature * Fold parameter-block desugaring into a more complete "type legalization" pass The basic problem that was arising is that once you desugar `ParameterBlock<T>` into `T`, you then need todeal with splitting `T` into its constituent fields if it contains any resource types. Handling those transformations by following the usual use-def chains wasn't really helping, because you might need systematic rewriting that can really only be handled bottom-up. This change adds a new pass that is intended to perform multiple kinds of type "legalization" at once: - It will turn `ParameterBlock<T>` into `T` - It may at some point also convert `ConstantBuffer<T>` into `T` as well - It will turn an value of an aggregate type that contains resources into N different values (one per field) - As a result of this, it will also deal with AOS-to-SOA conversion of these types Legalization is applied to *every* function/instruction/value, so that it can make large-scale changes that would be tough to manage with a work list. This pass needs to be run *after* generics have been fully specialized, so that we know we are always dealing with fully concrete types, so that their legalization for a given target is completely known. This is still work in progress; there's more to be done to get this working with all our test cases, and finish the remaining `ParameterBlock<T>` work. * Improve binding/layout information when using parameter blocks - When doing type layout for a parameter block, don't include the resources consumed by the element type in the resource usage for the parameter block - Note that this is pretty much identical to how a `ConstantBuffer<T>` does not report any `LayoutResourceKind::Uniform` usage, except that `ParameterBlock<T>` is *also* going to hide underlying texture/sampler reigster usage - The one exception here is that any nested items that use up entire `space`s or `set`s those need to be exposed in the resource usage of the parent (I don't have a test for this) - When type legalization needs to scalarize things, it must propagate layout information down to the new leaf variables. In general, the register/index for a new leaf parameter should be the sum of the offsets for all of the parent variables along the "chain" from the original variable down to the leaf (we aren't dealing with arrays here just yet). - When type legalization decides to eliminate a pointer(-like) type (e.g., desugar `ParameterBlock<T>` over to `T`), actually deal with that in terms of the `LegalVal`s created, so that we can know to turn a `load` into a no-op when applied to a value that got indirection removed. - Hack up the "complex" parameter-block test so that it actually passes (the big hack here is that the HLSL baseline is using names that are generated by the IR, and are unlikely to be stable as we add/remove transformations). - Note: I can't make these be compute tests right now, because regsiter spaces/sets are a feature of D3D12/Vulkan, and our test runner isn't using those APIs.
2017-10-05Working on better handling of builtin functions in IR (#196)Tim Foley
The main change I was working on here was to start having more of the builtin functions (in this case, `cos`, `sin`, and `saturate`) just lower to the IR as calls to builtin functions (with declarations but no definition), rather than expect/require them to map to individual IR opcodes in every case. The main change there was the removal of some `intrinsic_op` modifiers in the stdlib. This then requires the `isTargetInstrinsic` logic in IR-based code emit to avoid emitting declarations for these intrinsics. The corresponding logic for emitting *calls* to these intrinsics is currently being skipped. Along the way, a variety of fixups were added: - In order to support lowering to GLSL, we need to handle cases where a variable/function name uses a GLSL reserved word. The right long-term fix there is to always use generated or mangled names, but for now I'm hacking it by adding a `_s` prefix to all names during IR-based emit. - This needs a flag to disable it, since some of our tests currently rely on checking binding information from generated HLSL/SPIR-V that will include these mangled/modified names. - Emit matrix layout modifiers appropriately for GLSL - Specialize IR parameter-block emission between GLSL and HLSL - Fix up argument count/index logic for a couple of opcodes that weren't fixed when removing the types from the explicit operand list - Fix up IR generation for calls to declarations with generic arguments. We were briefly adding the generic args to the ordinary argument list, which added complexity in several places. We now rely on the declaration-reference nodes in the IR to carry that extra info. - TODO: We actually need to make sure that this is the case, since we don't currently correctly generated specialized decl-refs when building IR for function calls The main test that would have been affected by this is `cross-compile-entry-point`, but I was not able to get that working fully with the IR. The main problem in this case was that when emitting GLSL we will need to perform certain required transformations on the IR to get legal code for GLSL. Notably: - We need to hoist entry-point parameters away from being function parameters, and make them be global variables. This is currently being hand-waved during the emit logic, but it seems way better to have it all get cleaned up in the IR first. - We need to scalarize entry-point parameters, because structure input/output is not supported as vertex input or fragment output (and it may be best to always scalarize anyway, to match HLSL semantics). (Note: "scalarize" here means to bust up structures, but not matrices/vectors)
2017-09-11Support IR-based codegen for a few more examples.Tim Foley
The main interesting change here is around support for lowering of calls to "subscript" operations (what a C++ programmer would think of as `operator[]`). An important infrastructure change here was to add an explicit AST-node representation for a "static member expression" which we use whenever a member is looked up in a type as opposed to a value. The implementation of this probably isn't robust yet, but it turns out to be important to be able to tell such cases apart.
2017-09-07Replace old notion of "intrinsic" operationsTim Foley
The code previously had an enumerated type for "intrinsic" operations, and allowed functions to be marked `__intrinsic_op(...)` to indicate the operation they map to. The nature of the IR meant that each of these intrinsic ops had to have a corresponding IR opcode, but the `enum` types weren't the same. This change cleans things up a bit by deciding that the `__intrinsic_op(...)` modifier names an actual IR opcode, and so the `IntrinsicOp` enum is gone. The biggest source of complexity here is that there are certain operations that need to be "intrinsic"-ish for the purposes of the current AST-based translation path, because we need them to round-trip from source to AST and back. Right now this is being handled by defining a bunch of "pseudo-ops" which can be used in the `__intrinsic_op` modifier, but which are *not* meant to be represented in the IR. Currently I don't actually handle this during IR generation. In the long run, once we are using IR for everything that needs cross-compilation, we should be able to eliminate the pseudo-ops in favor of just having these be ordinary (inline) functions defined in the stdlib (e.g., the `+=` operator can just have a direct definition). There was a second category of modifier that gets a little caught up in this, which is the `__intrinsic` modifier, which got used in two ways: 1. A function marked `__intrinsic(glsl, ...)` had what I call a "target intrinsic" modifier, which specified how to lower it for a specific target (e.g., GLSL). 2. A function just marked `__intrinsic` was supposed to be a marker for "this function shouldn't be emitted in the output, because the implementation is expected to be provided" The latter category of function should really be an `__intrinsic_op`, so I translated all those uses. I added a tiny bit of sugar so that `__intrinsic_op` without an explicit opcode will look up an opcode based on the name of the function being called, so that an operation like `sin` can automatically be plumbed through to an equivalent IR op. (The first category is a stopgap for the AST-based cross-compilation, and will hopefully be replaced by something better as we get the IR-based path working). Getting the switch from `__intrinsic` to `__intrinsic_op` working required shuffling around some code in `emit.cpp` that handles looking up those modifiers and emitting builtin operations appropriately during cross-compilation. Depending on where we go with things, a possible extension of this approach is to allow multiple operands to `__intrinsic_op` so that the first specifies the opcode, and then the rest are literal arguments to specify "sub-ops." This could help us handle stuff like texture-fetch operations without an explosion in the number of opcodes. I still need to think about whether this is a good idea or not.
2017-09-06Continue work on IR-based codegenTim Foley
This gets us far enough that we can convert a single test case to use the IR, under the new `-use-ir` flag. Getting this merged into mainline will at least ensure that we keep the IR path working in a minimal fashion, even when we have to add functionality the existing AST-based path There is definitely some clutter here from keeping both IR-based and AST-based translation around, but I don't want to have a long-lived branch for the IR that gets further and further away from the `master` branch that is actually getting used and tested. Summary of changes: - Add pointer types and basic `load` operation to be able to handle variable declarations - Add basic `call` instruction type - Add simple address math for field reference in l-value - Always add IR for referenced decls to global scope - Add notion of "intrinsic" type modifier, which maps a type declaration directly to an IR opcode (plus optional literal operands to handle things like texture/sampler flavor) - Improve printing of IR instructions, types, operands - Add constant-buffer type to IR - Allow any instruction to be detected as "should be folded into use sites" and use this to tag things of constant-buffer type - Also add logic for implicit base on member expressions, to handle references to `cbuffer` members - Add connection back to original decl to IR variables (including global shader parameters...) - Use reflection name instead of true name when emitting HLSL from IR (so that we can match HLSL output) - Make IR include decorations for type layout - Re-use existing emit logic for HLSL semantics to output `register` semantics for IR-based code - Make IR-based codegen be an option we can enable from the command line - It still isn't on by default (it can barely manage a trivial shader), but it seems better to enable it always instead of putting it under an `#ifdef` - Fix up how we check for intrinsic operations suring AST-based cross compilation so that adding new intrinsic ops for the IR won't break codegen.
2017-07-13An array of resources in Vulkan only consumes one bindingTim Foley
Fixes #84 - When computing resource usage for an array type, don't multiply the resource usage of the element type by the element count foor descriptor-table-slot resources. - When reporting the "stride" of an array type through reflection, report the stride for descriptor table slots as zero, always.
2017-06-14AppVeyor: Run tests as part of AppVeyor buildsTim Foley
This includes a bunch of related changes: - `slang-test` - Add a notion of an "output mode" that specifies whether we output to console (the default), or invoke the apprpriate AppVeyor command to update test status - Add a notion of test categories, so that tests can be tagged with categories, and then we can invoke only those tets in a given category, or choose to *exclude* tests with specific categories - Allow the `OSProcessSpawner` to look up an executable by "path" (meaning a full path is expected) or by "name" (meaning it should be allowed to look in the current directory, `PATH` environment variable, etc.). This was important to make sure that I can run `appveyor` without having to know its absolute path. - AppVeyor configuration - Change badge to reflect new build account for organization (rather than a single-user account) - Remove attempt to set AppVeyor build version in a clever way, since it breaks links from GitHub to AppVeyor - Change order or configurations in the build matrix to front-load the Release build (which has the main tests) - Turn on `fast_finish` flag so we don't have to wait as long for failed builds - Turn on `parallel` builds - Set `verbosity: minimal` to avoid getting build spew about Xamarin stuff I'm not using - Add custom `test_script` to invoke `test.bat` - Sets the test category based on teh build configuration, so we don't run the full test suite on every input. - `test.bat` - Allow for `-platform` and `-configuration` arguments - Rewrute a platform of `Win32` over to `x86` to match how the output directories are named - Futz around with how the directories are being passed along to work around annoying `.bat` file quoting behavior (I still don't get how batch files work) - Tests - Mark a bunch of tests as `smoke` tests - Mark the relevant tests as `render` tests (these get filtered out for AppVeyor builds)
2017-06-09Initial import of code.Tim Foley