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torch-mlir/lib/RefBackend/RefBackend.cpp

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Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
//===----------------------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This is the base file for our "end-to-end" npcomp lowering pipeline.
// At the moment, the first "end" is TCF ops and the second "end" is `llvm`
// dialect suitable for jitting.
//
//===----------------------------------------------------------------------===//
[RefBackend] Rename "E2E" to RefBackend.
2020-10-07 07:14:37 +08:00
#include "npcomp/RefBackend/RefBackend.h"
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
#include "PassDetail.h"
Update llvm-project to 753a21928413f8a7e76978cb1354e09150e114e0
2020-05-22 04:09:06 +08:00
#include "mlir/Conversion/SCFToStandard/SCFToStandard.h"
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
#include "mlir/Conversion/ShapeToStandard/ShapeToStandard.h"
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
#include "mlir/Dialect/Linalg/IR/LinalgOps.h"
#include "mlir/Dialect/Linalg/IR/LinalgTypes.h"
Add lowering from linalg to loops. This also adds a small pass to clean up the `dim` ops that linalg introduces. For now, it only has a trivial pattern that looks for a `tcp.alloc_memref(%shape)` op to get the shape as we currently have an invariant that all memrefs are the result of such ops. But eventually this will need to look through view ops and any other shape-ish stuff that linalg introduces as it lowers to loops, along with any slicing ops introduced by buffer allocation.
2020-05-12 09:50:51 +08:00
#include "mlir/Dialect/Linalg/Passes.h"
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
#include "mlir/Dialect/Shape/IR/Shape.h"
#include "mlir/Dialect/StandardOps/IR/Ops.h"
#include "mlir/Pass/Pass.h"
#include "mlir/Pass/PassRegistry.h"
#include "mlir/Transforms/DialectConversion.h"
Add some cleanup passes. This makes the IR more presentable before going to the next phase of lowering (ops on memref/buffers -> LLVM ops).
2020-05-12 06:27:37 +08:00
#include "mlir/Transforms/Passes.h"
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
#include "npcomp/Conversion/TCFToTCP/TCFToTCP.h"
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
#include "npcomp/Dialect/RefBackend/IR/RefBackendOps.h"
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
#include "npcomp/Dialect/TCP/IR/TCPDialect.h"
#include "npcomp/Dialect/TCP/IR/TCPOps.h"
using namespace mlir;
using namespace mlir::NPCOMP;
Bump submodule versions. * llvm-project: b5924a8e27536d19dd5c4d302db29fb6163d5faa * mhlo: 848ca244d20f045b7921da55a98a04d95ef94f0e * Multiple breakages that need to be fixed. Fixes: * Refactor dialect registration * Remove all kindof methods (Casting functionality has been added upstream and is implicitly available, see https://llvm.discourse.group/t/removing-kinds-from-attributes-and-types/1547.) * Update dialect registration to comply with https://reviews.llvm.org/D85495. * Remove type kinds and update some changed dialect signatures. * Upgrade ATen dialect to match upstream needs. * Move dialect registration to tablegen. * Register the ListType in tablegen. * Change dialect initialization signature. * Use TypeSwitch in MlirIr location printer. * Remove global registry depends from npcomp-opt. * Change LowerToLLVM to pass an MLIRContext vs an LLVMDialect for type creation. * Remove dep on MLIREDSCInterface that is removed upstream. * Thread through the DialectRegistry for opt and python-like tools. * Modernize pass registration (This was forced because the GEN_PASS_REGISTRATION code now generates inline functions vs literal pass registration statements) Co-authored-by: Marius Brehler <marius.brehler@iml.fraunhofer.de>
2020-08-28 06:09:10 +08:00
//===----------------------------------------------------------------------===//
// Pass registration
//===----------------------------------------------------------------------===//
namespace {
#define GEN_PASS_REGISTRATION
[RefBackend] Rename "E2E" to RefBackend.
2020-10-07 07:14:37 +08:00
#include "npcomp/RefBackend/Passes.h.inc"
Bump submodule versions. * llvm-project: b5924a8e27536d19dd5c4d302db29fb6163d5faa * mhlo: 848ca244d20f045b7921da55a98a04d95ef94f0e * Multiple breakages that need to be fixed. Fixes: * Refactor dialect registration * Remove all kindof methods (Casting functionality has been added upstream and is implicitly available, see https://llvm.discourse.group/t/removing-kinds-from-attributes-and-types/1547.) * Update dialect registration to comply with https://reviews.llvm.org/D85495. * Remove type kinds and update some changed dialect signatures. * Upgrade ATen dialect to match upstream needs. * Move dialect registration to tablegen. * Register the ListType in tablegen. * Change dialect initialization signature. * Use TypeSwitch in MlirIr location printer. * Remove global registry depends from npcomp-opt. * Change LowerToLLVM to pass an MLIRContext vs an LLVMDialect for type creation. * Remove dep on MLIREDSCInterface that is removed upstream. * Thread through the DialectRegistry for opt and python-like tools. * Modernize pass registration (This was forced because the GEN_PASS_REGISTRATION code now generates inline functions vs literal pass registration statements) Co-authored-by: Marius Brehler <marius.brehler@iml.fraunhofer.de>
2020-08-28 06:09:10 +08:00
} // end namespace
[RefBackend] Rename "E2E" to RefBackend.
2020-10-07 07:14:37 +08:00
void mlir::NPCOMP::registerRefBackendPasses() {
Bump submodule versions. * llvm-project: b5924a8e27536d19dd5c4d302db29fb6163d5faa * mhlo: 848ca244d20f045b7921da55a98a04d95ef94f0e * Multiple breakages that need to be fixed. Fixes: * Refactor dialect registration * Remove all kindof methods (Casting functionality has been added upstream and is implicitly available, see https://llvm.discourse.group/t/removing-kinds-from-attributes-and-types/1547.) * Update dialect registration to comply with https://reviews.llvm.org/D85495. * Remove type kinds and update some changed dialect signatures. * Upgrade ATen dialect to match upstream needs. * Move dialect registration to tablegen. * Register the ListType in tablegen. * Change dialect initialization signature. * Use TypeSwitch in MlirIr location printer. * Remove global registry depends from npcomp-opt. * Change LowerToLLVM to pass an MLIRContext vs an LLVMDialect for type creation. * Remove dep on MLIREDSCInterface that is removed upstream. * Thread through the DialectRegistry for opt and python-like tools. * Modernize pass registration (This was forced because the GEN_PASS_REGISTRATION code now generates inline functions vs literal pass registration statements) Co-authored-by: Marius Brehler <marius.brehler@iml.fraunhofer.de>
2020-08-28 06:09:10 +08:00
::registerPasses();
[RefBackend] Rename "E2E" to RefBackend.
2020-10-07 07:14:37 +08:00
mlir::PassPipelineRegistration<RefBackendLoweringPipelineOptions>(
"refback-lowering-pipeline", "RefBackend lowering pipeline.",
mlir::NPCOMP::createRefBackendLoweringPipeline);
Add lowering from linalg to loops. This also adds a small pass to clean up the `dim` ops that linalg introduces. For now, it only has a trivial pattern that looks for a `tcp.alloc_memref(%shape)` op to get the shape as we currently have an invariant that all memrefs are the result of such ops. But eventually this will need to look through view ops and any other shape-ish stuff that linalg introduces as it lowers to loops, along with any slicing ops introduced by buffer allocation.
2020-05-12 09:50:51 +08:00
}
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
//===----------------------------------------------------------------------===//
// LowerAllocMemRefOps
//===----------------------------------------------------------------------===//
namespace {
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
class LowerAllocMemRefOp : public OpRewritePattern<refback::AllocMemRefOp> {
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
public:
using OpRewritePattern::OpRewritePattern;
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
LogicalResult matchAndRewrite(refback::AllocMemRefOp op,
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
PatternRewriter &rewriter) const override {
auto memrefType = op.getType().cast<MemRefType>();
auto shape = op.getOperand();
// std.alloc only accepts the dynamic extents as operands, so only
// collect those.
SmallVector<Value, 6> dynamicExtents;
for (int i = 0, e = memrefType.getRank(); i < e; i++) {
if (memrefType.isDynamicDim(i)) {
Rework reference shape lowering based on upstream shape dialect changes. * Primarily, the upstream shape dialect now uses tensor<?xindex> for non-erroring, immediate shape calculations (and will return this for shape_of of a tensor or memref). * In addition, upstream passes do not yet exist for fully lowering to standard ops, so the passes here need to be extended to handle this new convention. * This should be seen as an intermediate state, necessary to integrate a new LLVM version and needs more work and cleanup for generality. * There is a good deal of awkwardness in these conversions. The hope is that additional upstream work will yield better defined conversion paths once out of this intermediate state.
2020-08-03 13:06:12 +08:00
auto extent =
rewriter.create<shape::GetExtentOp>(op.getLoc(), shape, i);
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
dynamicExtents.push_back(extent);
}
}
rewriter.replaceOpWithNewOp<AllocOp>(op, memrefType, dynamicExtents);
return success();
}
};
} // namespace
namespace {
class LowerAllocMemRefOps
: public LowerAllocMemRefOpsBase<LowerAllocMemRefOps> {
Register dialects in E2E passes
2020-09-10 15:23:46 +08:00
void getDependentDialects(DialectRegistry &registry) const override {
registry.insert<shape::ShapeDialect>();
}
void runOnOperation() override {
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
auto func = getOperation();
auto *context = &getContext();
OwningRewritePatternList patterns;
patterns.insert<LowerAllocMemRefOp>(context);
ConversionTarget target(*context);
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
target.addIllegalOp<refback::AllocMemRefOp>();
Rework reference shape lowering based on upstream shape dialect changes. * Primarily, the upstream shape dialect now uses tensor<?xindex> for non-erroring, immediate shape calculations (and will return this for shape_of of a tensor or memref). * In addition, upstream passes do not yet exist for fully lowering to standard ops, so the passes here need to be extended to handle this new convention. * This should be seen as an intermediate state, necessary to integrate a new LLVM version and needs more work and cleanup for generality. * There is a good deal of awkwardness in these conversions. The hope is that additional upstream work will yield better defined conversion paths once out of this intermediate state.
2020-08-03 13:06:12 +08:00
target.addLegalOp<shape::GetExtentOp>();
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
target.addLegalOp<AllocOp>();
Rework reference shape lowering based on upstream shape dialect changes. * Primarily, the upstream shape dialect now uses tensor<?xindex> for non-erroring, immediate shape calculations (and will return this for shape_of of a tensor or memref). * In addition, upstream passes do not yet exist for fully lowering to standard ops, so the passes here need to be extended to handle this new convention. * This should be seen as an intermediate state, necessary to integrate a new LLVM version and needs more work and cleanup for generality. * There is a good deal of awkwardness in these conversions. The hope is that additional upstream work will yield better defined conversion paths once out of this intermediate state.
2020-08-03 13:06:12 +08:00
target.addLegalOp<ConstantOp>();
Lower tcp.alloc_memref ops to tcp.get_extent + std.alloc. - tcp.get_extent will be liminated while lowering shapes - std.alloc is supported by the upstream LLVM lowering.
2020-05-19 03:50:16 +08:00
if (failed(applyPartialConversion(func, target, patterns))) {
return signalPassFailure();
}
}
};
} // namespace
std::unique_ptr<OperationPass<FuncOp>>
mlir::NPCOMP::createLowerAllocMemRefOpsPass() {
return std::make_unique<LowerAllocMemRefOps>();
}
[RefE2E] Use upstream shape constraint conversion pass. Now that we upstreamed our pass, we can remove it. The final pass that landed upstream doesn't do the shape.assuming canonicalization to legalize that op away, so added a restricted-canonicalizer pass that allowed to run just shape dialect canonicalizations, which deletes the shape.assuming. The pass ended up kind of ugly. See the TODO's on it for some potential cleaner directions.
2020-09-26 07:02:09 +08:00
//===----------------------------------------------------------------------===//
// RestrictedCanonicalizer
//===----------------------------------------------------------------------===//
namespace {
struct RestrictedCanonicalizer
: public RestrictedCanonicalizerBase<RestrictedCanonicalizer> {
void runOnOperation() override {
auto *context = &getContext();
// Find the dialects from their names.
DenseSet<StringRef> neededDialects;
for (const std::string &dialectName : includedDialects)
neededDialects.insert(dialectName);
DenseSet<Dialect *> dialectsToCanonicalize;
for (Dialect *dialect : context->getLoadedDialects()) {
if (neededDialects.count(dialect->getNamespace())) {
dialectsToCanonicalize.insert(dialect);
// Erase the dialect so that we can report an error below for any
// dialect names that are not loaded.
neededDialects.erase(dialect->getNamespace());
}
}
// Report a helpful error if a dialect is not found.
auto missingDialects = llvm::to_vector<6>(neededDialects);
if (!missingDialects.empty()) {
llvm::sort(missingDialects);
std::string buf;
llvm::raw_string_ostream os(buf);
llvm::interleaveComma(missingDialects, os);
llvm::report_fatal_error("restricted-canonicalize: unknown dialects: " +
os.str());
}
// Collect all canonicalization patterns from ops in the included dialects.
OwningRewritePatternList patterns;
for (AbstractOperation *op : context->getRegisteredOperations())
if (dialectsToCanonicalize.count(&op->dialect))
op->getCanonicalizationPatterns(patterns, context);
Operation *op = getOperation();
applyPatternsAndFoldGreedily(op->getRegions(), patterns);
}
};
} // end anonymous namespace
std::unique_ptr<Pass> mlir::NPCOMP::createRestrictedCanonicalizerPass() {
return std::make_unique<RestrictedCanonicalizer>();
}
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
//===----------------------------------------------------------------------===//
[RefBackend] Rename "E2E" to RefBackend.
2020-10-07 07:14:37 +08:00
// createRefBackendLoweringPipeline
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
//===----------------------------------------------------------------------===//
[RefBackend] Rename "E2E" to RefBackend.
2020-10-07 07:14:37 +08:00
void mlir::NPCOMP::createRefBackendLoweringPipeline(
OpPassManager &pm, const RefBackendLoweringPipelineOptions &options) {
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// This "end to end" lowering pipline loewrings from approximately the "numpy"
// level of abstraction (which is a dialect we call "TCF", or "Tensor Compute
// Frontend") all the way down to LLVM IR.
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// Convert from TCF to TCP.
//
// TCF has implicit broadcasting, and issues errors "inside the ops" in the
// case of invalid broadcasts.
//
// TCP does not. So we need to reify the broadcasting and error checking.
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
pm.addPass(createConvertTCFToTCPPass());
"Finish" tensor -> memref conversion. There's a lot of details to flesh out here, but the basic approach seems promising (see comments in createE2ELoweringPipeline). This approach will be put to the test when we try to do our first fusions since that tickles some of the nasty phase ordering issues involved here. But we're not there yet.
2020-05-12 05:24:57 +08:00
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// For operations with a shape transfer function, explicitly bypass their
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
// shape computations with refback.shaped_results ops.
"Finish" tensor -> memref conversion. There's a lot of details to flesh out here, but the basic approach seems promising (see comments in createE2ELoweringPipeline). This approach will be put to the test when we try to do our first fusions since that tickles some of the nasty phase ordering issues involved here. But we're not there yet.
2020-05-12 05:24:57 +08:00
//
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// Right now, our lowering flow depends heavily on descriptors, so technically
// we don't need to bypass shapes -- we can just splat out the shape
// calculations when lowering the ops themselves. However, this design keeps
// the door open to various future directions, and is an interesting example
// in its own right.
"Finish" tensor -> memref conversion. There's a lot of details to flesh out here, but the basic approach seems promising (see comments in createE2ELoweringPipeline). This approach will be put to the test when we try to do our first fusions since that tickles some of the nasty phase ordering issues involved here. But we're not there yet.
2020-05-12 05:24:57 +08:00
//
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// For example, if we want to lower to command-buffer style API's like Vulkan,
// then we need (for correctness) to bypass the shapes (actually,
// something more sophisticated than just that) if we want to do command
// buffer formation while we are still on tensors (e.g. to record workgroup
// sizes). We might not care about pursuing that direction here though. So
// consider this pass as purely advisory now.
"Finish" tensor -> memref conversion. There's a lot of details to flesh out here, but the basic approach seems promising (see comments in createE2ELoweringPipeline). This approach will be put to the test when we try to do our first fusions since that tickles some of the nasty phase ordering issues involved here. But we're not there yet.
2020-05-12 05:24:57 +08:00
//
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// One case where we might still be interested in this is dealing with
// linalg.generic ops and other types of "fusions" that have shape transfer
// functions that are not easily reconstructible and thus we have to capture
// the shape transfer functions earlier in the pipeline.
pm.addPass(createBypassShapesPass());
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// Lower shape constraints before we enter tensor->memref conversion.
[RefE2E] Use upstream shape constraint conversion pass. Now that we upstreamed our pass, we can remove it. The final pass that landed upstream doesn't do the shape.assuming canonicalization to legalize that op away, so added a restricted-canonicalizer pass that allowed to run just shape dialect canonicalizations, which deletes the shape.assuming. The pass ended up kind of ugly. See the TODO's on it for some potential cleaner directions.
2020-09-26 07:02:09 +08:00
// That is, we expand shape.cstr_* ops to eager error handling code.
pm.addPass(createConvertShapeConstraintsPass());
// Run shape canonicalizations. In particular, this erases shape.assuming,
// now that we have converted shape constraints.
// TODO: This is kind of ugly. Either we use pass options or a constructor
// that takes C++ data structures. The former makes the pass usable on the
// command line (including reproducers), the latter makes the pass more
// convenient.
std::unique_ptr<Pass> shapeCanonicalizer =
createRestrictedCanonicalizerPass();
if (failed(shapeCanonicalizer->initializeOptions("included-dialects=shape")))
llvm::report_fatal_error("couldn't initialize restricted-canonicalize");
pm.addPass(std::move(shapeCanonicalizer));
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// --------------------------------------------------------------------------
// Lower the `tensor` type to `memref`.
// --------------------------------------------------------------------------
// We make a conscious effort here to do this as a sequence of separate passes
// rather than a single mega dialect conversion pass.
"Finish" tensor -> memref conversion. There's a lot of details to flesh out here, but the basic approach seems promising (see comments in createE2ELoweringPipeline). This approach will be put to the test when we try to do our first fusions since that tickles some of the nasty phase ordering issues involved here. But we're not there yet.
2020-05-12 05:24:57 +08:00
//
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// This means that intermediate steps have source/target materializations
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
// (refback.memref_to_tensor / refback.tensor_to_memref) in the IR.
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
// Lower ops enclosed in refback.shaped_results regions.
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// For now, this is covering the "tensor compute" ops like tcp.add /
// tcp.broadcast_to (the former being handled via a special subset of
// linalg.generic) -- we only handle those two, so having an isolated pass
// that hardcodes all of them is fine -- eventually we might want something
// more pluggable. The exact interface for this pluggability depends on
// what design we want to settle on for bypassing shape computations.
pm.addPass(createLowerShapedResultsToMemrefPass());
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
// Lower tensor-valued constants to refback.global.
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
pm.addPass(createLowerConstantTensorsToMemrefPass());
[RefBackend] Split out RefBackend (refback) dialect from TCP. This is the first in a patch series that is refactoring the constellation of things variously called or associated with "E2E", "RefE2E", "npcomprt", and "TCP" into a more cleanly layered result. Concretely, this first patch fixes the fact that TCP was basically acting like a dumping ground needed by the reference backend. This splits it out, which is fairly mechanical, but touches a lot of lines of code (basically replacing `tcp` with `refback` and `TCP` with `RefBackend). Now, the RefBackend dialect is that dumping ground, which is slighly better, as it starts allowing TCP to become a nice clean middle layer that is not related per se to the reference backend. The previous name RefE2E or "reference e2e flow" was super confusing. Now that we are seeing more clearly where the "backend" distinction lies, the [RefBackend] commit tag is born :)
2020-10-07 06:44:18 +08:00
// refback::AllocMemRefOp takes a shape (i.e. extent tensor) as an argument.
// We need to resolve this to std.alloc which takes individual extents.
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
pm.addPass(createLowerAllocMemRefOpsPass());
// Lower shape ops to std.
// TODO: This should in principle be moved before tensor->memref conversion.
// But some of the tensor->memref lowerings above use shape.get_extent. For
// example, when lowering a broadcast, we need to get an extent from its shape
// operand to allocate the output.
pm.addPass(createConvertShapeToStandardPass());
// Lower std ops to memref.
// This includes ops like extract_element.
pm.addPass(createLowerStdToMemrefPass());
// Lower control flow and other "structural" ops.
//
// These ops are generally not sensitive to the types that they operate on
// (e.g. the types of block operands, function arguments, etc.). But they all
// need to be converted consistently. So it makes sense to do this as the
// final step of conversion, which also finalizes the elimination of all
// stray source/target materializations introduced by the incremental
// tensor->memref lowering.
//
// This completes conversion to memref. There are no `tensor`'s after
// this point.
pm.addPass(createLowerStructuralToMemrefPass());
Lower to the upstream memref ABI. Specifically, we use unranked memrefs which get passed as a fixed-size set of arguments/returns. One big caveat about this is that returning results isn't going to work. See TODO in LowerTensorLoadOp. This is far from enough runtime-wise, but it starts to demarcate a plausible layering. Notice for example how this removes the runtime-dependence from LowerRankedShapes. Eventually, we want to have an `npcomp_rt` or `npcomp_hal` dialect with its own set of runtime types that will supercede this. See comments in LowerTensorLoadOp for more direction about where this is going to evolve.
2020-05-16 07:33:01 +08:00
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// TODO: Do buffer assignment. We should be able to just drop in the upstream
// pass?
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// At this point, we have lots of loose stuff floating around from lowering,
// so it's a good time to do some general cleanups.
Add ability to run without optimizations. The default is to only do the bare minimum needed for correctness, since that stresses the layering of the system maximally.
2020-06-02 10:30:13 +08:00
if (options.optimize) {
pm.addPass(createCanonicalizerPass());
pm.addPass(createCSEPass());
}
Add some cleanup passes. This makes the IR more presentable before going to the next phase of lowering (ops on memref/buffers -> LLVM ops).
2020-05-12 06:27:37 +08:00
Add lowering from linalg to loops. This also adds a small pass to clean up the `dim` ops that linalg introduces. For now, it only has a trivial pattern that looks for a `tcp.alloc_memref(%shape)` op to get the shape as we currently have an invariant that all memrefs are the result of such ops. But eventually this will need to look through view ops and any other shape-ish stuff that linalg introduces as it lowers to loops, along with any slicing ops introduced by buffer allocation.
2020-05-12 09:50:51 +08:00
// --------------------------------------------------------------------------
Lower to LLVM dialect. With this commit, we finish conversion to LLVM dialect, and should be ready for subsequent commits to convert to an LLVM module and let LLVM codegen to native machine code. This required a custom "lower to LLVM" pass to support lowering tcp.abort_if to a runtime call. In the future, this pass will grow to do type conversions for our own runtime types as we add those.
2020-05-21 09:48:53 +08:00
// Preparation for converting to an LLVM module.
Add lowering from linalg to loops. This also adds a small pass to clean up the `dim` ops that linalg introduces. For now, it only has a trivial pattern that looks for a `tcp.alloc_memref(%shape)` op to get the shape as we currently have an invariant that all memrefs are the result of such ops. But eventually this will need to look through view ops and any other shape-ish stuff that linalg introduces as it lowers to loops, along with any slicing ops introduced by buffer allocation.
2020-05-12 09:50:51 +08:00
// --------------------------------------------------------------------------
// Now, we begin the process of lowering to LLVM's level of abstraction
// (after which LLVM will take over lowering to machine code).
// Lower linalg ops to loops.
// TODO: Do some linalg optimizations like tiling here.
pm.addPass(createConvertLinalgToLoopsPass());
Cleanup after going to `llvm` dialect. This reduces IR size a lot, which can help when staring at it.
2020-07-14 07:15:42 +08:00
// Run a some cleanups.
Add ability to run without optimizations. The default is to only do the bare minimum needed for correctness, since that stresses the layering of the system maximally.
2020-06-02 10:30:13 +08:00
if (options.optimize) {
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
pm.addPass(createCanonicalizerPass());
Add ability to run without optimizations. The default is to only do the bare minimum needed for correctness, since that stresses the layering of the system maximally.
2020-06-02 10:30:13 +08:00
pm.addPass(createCSEPass());
}
Lower to LLVM dialect. With this commit, we finish conversion to LLVM dialect, and should be ready for subsequent commits to convert to an LLVM module and let LLVM codegen to native machine code. This required a custom "lower to LLVM" pass to support lowering tcp.abort_if to a runtime call. In the future, this pass will grow to do type conversions for our own runtime types as we add those.
2020-05-21 09:48:53 +08:00
// --------------------------------------------------------------------------
// Final conversion to an LLVM module.
// --------------------------------------------------------------------------
// Convert scf to std control flow in preparation for going to LLVM.
pm.addPass(createLowerToCFGPass());
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// Convert functions signatures and other constructs that interface with the
// runtime to the `npcomprt` dialect.
pm.addPass(createLowerToNpcomprtABIPass());
Lower to LLVM dialect. With this commit, we finish conversion to LLVM dialect, and should be ready for subsequent commits to convert to an LLVM module and let LLVM codegen to native machine code. This required a custom "lower to LLVM" pass to support lowering tcp.abort_if to a runtime call. In the future, this pass will grow to do type conversions for our own runtime types as we add those.
2020-05-21 09:48:53 +08:00
// Finally, convert to LLVM dialect using our custom LowerToLLVM pass
// which reuses the upstream patterns and gives us a place to add our own
Totally rework RefE2E tensor to memref flow. (#42) This now gets the overall "RefE2E" compilation stack to a point that I'm fairly happy with. We simplify it by mostly embracing the "descriptor" view of the world. The overall flow is best understood by reading through the createE2ELoweringPipeline function in lib/E2E/E2E.cpp That function creates a pass pipeline that lowers from "TCF" (which is ~numpy level of abstraction) down to LLVM IR. A brief high-level summary of what happens there: 1. TCF to TCP conversion. This involves reifying error handling in the form of shape constraints. See test/Conversion/TCFToTCP/basic.mlir 2. Lowering shape constraints. This converts shape constraints into eager error-handling code. See test/E2E/lower-shape-constraints.mlir This pass will soon go upstream. Because this lowers to std.assert, some later passes like LowerToNpcomprtABI and LowerToLLVM are updated to properly plumb this through e2e. See test/npcomp-run-mlir/invalid-broadcast.mlir for an execution test that properly aborts in case of an error. 3. Lowering tensors to memrefs. This is done via a series of passes rather than an single mega conversion. Unlike the previous code that mixed in the npcomprt ABI stuff here, it's now a very clean "pure memref" conversion. See test/E2E/lower-*-to-memref.mlir and lib/E2E/TensorToMemref/ Most of the changes are concentrated here. 4. As part of the above, we use the upstream ConvertShapeToStandard for lowering shapes. 5. We lower linalg to loops and lower loops to CFG using upstream passes. 6. Rewrite the "ABI" boundaries of the program to npcomprt data structures (LowerToNpcomprtABI). This mainly affects ABI boundaries and how global tensor constants are represented. One of the major improvements in this commit is that now it's a very clean rewrite that just replaces memrefs on ABI boundaries with !npcomprt.tensor (before there was a get_extent function that is not needed). See test/E2E/lower-to-npcomprt-abi.mlir 7. Lower to LLVM with upstream mlir patterns + some patterns for the npcomprt lowerings. One aspect here that is still a remnant of a non-descriptor-based tensor to memref flow is the BypassShapes + LowerShapedResultsToMemref. BypassShapes wraps the "tensor compute" ops in a tcp.shaped_results (basically a "tie_shape" kind of op), and then LowerShapedResultsToMemref uses those annotations to allocate output buffers while lowering the "tensor compute ops". Note that there are very few "tensor compute" ops currently supported (tcp.add + tcp.broadcast_to), so we just hardcode them in both passes. Realistically, I expect this to go away as we fully embrace the descriptor-based approach for simplicity, so don't look too deep into it.
2020-09-17 08:31:40 +08:00
// patterns for our own custom ops like the npcomprt ops.
Lower to LLVM dialect. With this commit, we finish conversion to LLVM dialect, and should be ready for subsequent commits to convert to an LLVM module and let LLVM codegen to native machine code. This required a custom "lower to LLVM" pass to support lowering tcp.abort_if to a runtime call. In the future, this pass will grow to do type conversions for our own runtime types as we add those.
2020-05-21 09:48:53 +08:00
pm.addPass(createLowerToLLVMPass());
Cleanup after going to `llvm` dialect. This reduces IR size a lot, which can help when staring at it.
2020-07-14 07:15:42 +08:00
// Although LLVM will clean everything up eventually, for the sake of IR
// clarity while still in MLIR, run some cleanups.
if (options.optimize) {
pm.addPass(createCanonicalizerPass());
pm.addPass(createCSEPass());
}
Initial TCF/TCP E2E seed. Very much WIP. This is enough to get tcf.add down to approximately the "linalg.generic on buffers" level of abstraction. (but there are nuances)
2020-05-07 09:41:54 +08:00
}