torch-mlir/lib/Dialect/Torch/Transforms/InlineGlobalSlots.cpp

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//===- InlineGlobalSlots.cpp -------------------------------------*- C++-*-===//
//
// This file is licensed 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
// Also available under a BSD-style license. See LICENSE.
//
//===----------------------------------------------------------------------===//
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
2022-07-14 02:45:56 +08:00
//
// This file implements an optimistic dataflow analysis that proves that values
// used in global slot initializers are "safe" (see definition below). This
// analysis allows us to inline global slot initializers.
//
// One thing to note is that this inlining (as with all inlining) can create
// duplicate ops. That is usually not a problem, except for certain large
// tensor literals. We rely on later CSE passes to deduplicate those literals.
//
// For debugging this pass an effort has been made for
// `-debug-only=dataflow` and `-debug-only=torch-inline-global-slots` to give a
// good experience. When debugging this pass, it is recommended to start with
// `-debug-only=torch-inline-global-slots` to find values that are marked
// unsafe unexpectedly and then `-debug-only=dataflow` to find why.
//
//===----------------------------------------------------------------------===//
#include "PassDetail.h"
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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#include "mlir/Analysis/DataFlowFramework.h"
#include "mlir/Analysis/SliceAnalysis.h"
#include "mlir/IR/BuiltinOps.h"
#include "mlir/IR/IRMapping.h"
[torch-mlir earthmoving (1/N)] C/C++ code movement. This creates the `external/torch-mlir` directory as an LLVM_EXTERNAL_PROJECTS-compatible project (analogous to `iree-dialects`) and completes movement/rename of all pure MLIR C/C++ compiler code into there. The next step will be to move all the Python code / code that links/includes PyTorch C++ code (which currently lives in `frontends/pytorch`) into a subdirectory here. I call this "earthmoving" because it is mostly mechanical changes and renames. As a quick summary (we can change this down the road easily) - C++ `mlir::NPCOMP::Torch -> mlir::torch::Torch` - CAPI `npcompTorchListTypeGet -> torchMlirTorchListTypeGet` - preprocessor `#ifndef NPCOMP_ -> #ifndef TORCHMLIR_` - CMake `NPCOMPFoo -> TorchMLIRFoo` The goal of this is to create a standalone project creating a center of mass for entry into the MLIR ecosystem from PyTorch, suitable in scope for eventual inclusion/ownership in PyTorch. The idea is that `external/torch-mlir` will some day be pulled out into its own repository, and then npcomp will simply pull it in as a submodule. Layering-wise, what lives in `torch-mlir` lowers code from PyTorch (currently TorchScript, but TorchFX or pytorch/xla-style tracing are possible extensions) down to what we have been calling the "Torch backend contract" which is cleaned up IR (inlining, simplifcation, conversion to value tensors, ...) entirely in the `torch` dialect. This is the branching off point for further lowering, of which npcomp takes one opinion (outside `torch-mlir` of course!), namely the `TorchConversion` dialect/transforms which lower to IR suitable for IREE and other linalg-on-tensors based lower-level compilers. Summary of changes: - move `{include,lib,test}/Dialect/Torch` into `torch-mlir` - move relevant parts of CAPI into `torch-mlir`. - leave a few things related to the `torch-mlir` Python build commented out, which should be resolved in a subsequent change.
2021-09-10 03:24:10 +08:00
#include "torch-mlir/Dialect/Torch/IR/TorchDialect.h"
#include "torch-mlir/Dialect/Torch/IR/TorchOps.h"
#include "torch-mlir/Dialect/Torch/Transforms/Passes.h"
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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#include "llvm/Support/Debug.h"
#define DEBUG_TYPE "torch-inline-global-slots"
using namespace mlir;
[torch-mlir earthmoving (1/N)] C/C++ code movement. This creates the `external/torch-mlir` directory as an LLVM_EXTERNAL_PROJECTS-compatible project (analogous to `iree-dialects`) and completes movement/rename of all pure MLIR C/C++ compiler code into there. The next step will be to move all the Python code / code that links/includes PyTorch C++ code (which currently lives in `frontends/pytorch`) into a subdirectory here. I call this "earthmoving" because it is mostly mechanical changes and renames. As a quick summary (we can change this down the road easily) - C++ `mlir::NPCOMP::Torch -> mlir::torch::Torch` - CAPI `npcompTorchListTypeGet -> torchMlirTorchListTypeGet` - preprocessor `#ifndef NPCOMP_ -> #ifndef TORCHMLIR_` - CMake `NPCOMPFoo -> TorchMLIRFoo` The goal of this is to create a standalone project creating a center of mass for entry into the MLIR ecosystem from PyTorch, suitable in scope for eventual inclusion/ownership in PyTorch. The idea is that `external/torch-mlir` will some day be pulled out into its own repository, and then npcomp will simply pull it in as a submodule. Layering-wise, what lives in `torch-mlir` lowers code from PyTorch (currently TorchScript, but TorchFX or pytorch/xla-style tracing are possible extensions) down to what we have been calling the "Torch backend contract" which is cleaned up IR (inlining, simplifcation, conversion to value tensors, ...) entirely in the `torch` dialect. This is the branching off point for further lowering, of which npcomp takes one opinion (outside `torch-mlir` of course!), namely the `TorchConversion` dialect/transforms which lower to IR suitable for IREE and other linalg-on-tensors based lower-level compilers. Summary of changes: - move `{include,lib,test}/Dialect/Torch` into `torch-mlir` - move relevant parts of CAPI into `torch-mlir`. - leave a few things related to the `torch-mlir` Python build commented out, which should be resolved in a subsequent change.
2021-09-10 03:24:10 +08:00
using namespace mlir::torch;
using namespace mlir::torch::Torch;
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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/// A program point representing a symbol.
///
/// In principle we could use the `Operation *` program point of the Symbol op,
/// but that just adds a layer of indirection through a symbol table for the
/// purpose of this analysis.
///
/// This is easier because we only support FlatSymbolRefAttr's in Torch-MLIR in
/// a single module. If we had to support complex nested symbol references, we
/// would probably want to go through the effort to indirect through the symbol
/// tables to make things clearer.
class FlatSymbolRefProgramPoint
: public GenericProgramPointBase<FlatSymbolRefProgramPoint,
FlatSymbolRefAttr> {
public:
using Base::Base;
void print(raw_ostream &os) const override {
os << "FlatSymbolRefProgramPoint(" << getValue() << ")";
}
Location getLoc() const override {
return UnknownLoc::get(getValue().getContext());
}
};
static bool isTypeTriviallySafe(Type type) {
return type.isa<Torch::IntType, Torch::FloatType, Torch::BoolType,
Torch::StringType, Torch::NoneType, Torch::ValueTensorType>();
}
static bool isUseTreatedWithValueSemantics(OpOperand &use) {
Operation *op = use.getOwner();
// If the op unconditionally has value semantics, then the use has value
// semantics.
if (op->hasTrait<Torch::OpTrait::HasValueSemantics>())
return true;
// The condition of the torch.prim.if op is treated with value semantics.
if (isa<PrimIfOp>(op) && use.getOperandNumber() == 0)
return true;
// TODO: Generalize the HasValueSemantics trait to support
// operand/result-granularity.
return false;
}
/// State tracking if an IR construct is "safe".
///
/// This state is tracked on Value's and also on global slots (via a
/// FlatSymbolRefProgramPoint).
///
/// In this context, "safe" means that the object is safe to inline.
/// This covers a few concepts
/// - the value cannot be mutated by the program
/// - the value cannot be potentially aliased, with that alias itself being
/// unsafe
class InlineGlobalSlotsAnalysisState : public AnalysisState {
public:
InlineGlobalSlotsAnalysisState(ProgramPoint point) : AnalysisState(point) {
(void)setSafe();
}
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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void print(raw_ostream &os) const override {
os << "InlineGlobalSlotsAnalysisState(" << (isSafe ? "safe" : "unsafe")
<< ")";
}
/// Helper for setting the state with the correct ChangeResult.
ChangeResult setSafe(bool newIsSafe = true) {
// As an optimistic analysis, once we prove that a value is unsafe, nothing
// can prove that it is safe again. This is the monotonicity property of
// the dataflow analysis that guarantees that we reach a fixed-point.
// If that property doesn't hold, then there is a bug in the analysis.
assert(!(isSafe == false && newIsSafe == true) && "non-monotonic update");
if (isSafe == newIsSafe)
return ChangeResult::NoChange;
isSafe = newIsSafe;
return ChangeResult::Change;
}
/// Helper for updatating the state with the correct ChangeResult based on the
/// safety of a use.
ChangeResult
incorporateSafetyOfUse(const InlineGlobalSlotsAnalysisState *useState) {
// The use is safe, so no need to change anything.
if (useState->isSafe)
return ChangeResult::NoChange;
return setSafe(false);
}
/// This is an optimistic analysis. We start assuming everything is safe.
bool isSafe = true;
};
class InlineGlobalSlotsAnalysis : public DataFlowAnalysis {
public:
InlineGlobalSlotsAnalysis(DataFlowSolver &solver);
LogicalResult initialize(Operation *top) override;
LogicalResult visit(ProgramPoint point) override;
private:
/// The local transfer function determining the safety of `value`.
bool isValueSafeTransferFunction(Value value);
/// The InitializeGlobalSlotsOp of the current module we are analyzing.
///
/// This is used to propagate the analysis from globals into to the module
/// initializer.
InitializeGlobalSlotsOp initializeGlobalSlotsOp;
};
InlineGlobalSlotsAnalysis::InlineGlobalSlotsAnalysis(DataFlowSolver &solver)
: DataFlowAnalysis(solver) {
registerPointKind<FlatSymbolRefProgramPoint>();
}
LogicalResult InlineGlobalSlotsAnalysis::initialize(Operation *top) {
auto walkResult = top->walk([this](Operation *op) {
if (auto globalSlot = dyn_cast<Torch::GlobalSlotOp>(op)) {
auto *state = getOrCreate<InlineGlobalSlotsAnalysisState>(
getProgramPoint<FlatSymbolRefProgramPoint>(
FlatSymbolRefAttr::get(globalSlot.getSymNameAttr())));
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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propagateIfChanged(state,
state->setSafe(globalSlot.getVisibility() !=
SymbolTable::Visibility::Public));
}
if (auto globalSlotSet = dyn_cast<Torch::GlobalSlotSetOp>(op)) {
auto *state = getOrCreate<InlineGlobalSlotsAnalysisState>(
getProgramPoint<FlatSymbolRefProgramPoint>(
globalSlotSet.getSlotAttr()));
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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propagateIfChanged(state, state->setSafe(false));
}
// Save the InitializeGlobalSlotsOp for later referencee
if (auto initialize = dyn_cast<Torch::InitializeGlobalSlotsOp>(op)) {
initializeGlobalSlotsOp = initialize;
}
for (Value result : op->getResults()) {
if (failed(visit(result)))
return WalkResult::interrupt();
}
return WalkResult::advance();
});
if (walkResult.wasInterrupted())
return failure();
return success();
}
LogicalResult InlineGlobalSlotsAnalysis::visit(ProgramPoint point) {
if (Value value = dyn_cast<Value>(point)) {
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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bool isSafe = isValueSafeTransferFunction(value);
auto *state = getOrCreate<InlineGlobalSlotsAnalysisState>(value);
propagateIfChanged(state, state->setSafe(isSafe));
// Handle GlobalSlotGetOp's.
if (auto opResult = dyn_cast<OpResult>(value)) {
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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if (auto globalSlotGet =
dyn_cast<Torch::GlobalSlotGetOp>(opResult.getOwner())) {
auto *flatSymbolRefPoint = getProgramPoint<FlatSymbolRefProgramPoint>(
globalSlotGet.getSlotAttr());
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
2022-07-14 02:45:56 +08:00
auto *valueState = getOrCreateFor<InlineGlobalSlotsAnalysisState>(
flatSymbolRefPoint, globalSlotGet.getResult());
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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auto *globalState =
getOrCreate<InlineGlobalSlotsAnalysisState>(flatSymbolRefPoint);
propagateIfChanged(globalState,
globalState->incorporateSafetyOfUse(valueState));
}
}
return success();
}
if (auto *genericProgramPoint = dyn_cast<GenericProgramPoint *>(point)) {
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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if (auto *flatSymbolRefPoint =
dyn_cast<FlatSymbolRefProgramPoint>(genericProgramPoint)) {
if (initializeGlobalSlotsOp) {
auto it =
llvm::find(initializeGlobalSlotsOp.getSlotSymNames(),
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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static_cast<Attribute>(flatSymbolRefPoint->getValue()));
Value value = initializeGlobalSlotsOp->getOperand(std::distance(
initializeGlobalSlotsOp.getSlotSymNames().begin(), it));
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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auto *flatSymbolRefState =
getOrCreateFor<InlineGlobalSlotsAnalysisState>(value,
flatSymbolRefPoint);
auto *valueState = getOrCreate<InlineGlobalSlotsAnalysisState>(value);
propagateIfChanged(valueState,
valueState->setSafe(flatSymbolRefState->isSafe));
}
return success();
}
}
LLVM_DEBUG(
{ llvm::dbgs() << "visit failing because of: " << point << "\n"; });
return failure();
}
// This is only a member function to access protected get* functions.
bool InlineGlobalSlotsAnalysis::isValueSafeTransferFunction(Value value) {
if (isTypeTriviallySafe(value.getType()))
return true;
for (OpOperand &use : value.getUses()) {
Operation *op = use.getOwner();
if (isUseTreatedWithValueSemantics(use))
continue;
// If the op is read-only and all results are safe, then this value is
// safe. This covers, for example, view-like ops that create aliases.
if ((op->hasTrait<Torch::OpTrait::ReadOnly>() || isMemoryEffectFree(op)) &&
llvm::all_of(op->getResults(), [&](Value result) {
auto *state =
getOrCreateFor<InlineGlobalSlotsAnalysisState>(value, result);
return state->isSafe;
}))
continue;
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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if (auto initialize = dyn_cast<Torch::InitializeGlobalSlotsOp>(op)) {
auto symName = initialize.getSlotSymNames()[use.getOperandNumber()]
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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.cast<FlatSymbolRefAttr>();
auto *state = getOrCreateFor<InlineGlobalSlotsAnalysisState>(
value, getProgramPoint<FlatSymbolRefProgramPoint>(symName));
if (state->isSafe)
continue;
}
// We may not create all the dependency edges, but that is ok since at
// this point we have already reached the fixed-point.
return false;
}
return true;
}
SmallVector<Operation *> getBackwardSliceIncludingRoot(Value initialValue) {
SetVector<Operation *> sliceSet;
getBackwardSlice(initialValue, &sliceSet);
SmallVector<Operation *> slice;
llvm::append_range(slice, sliceSet);
slice.push_back(initialValue.getDefiningOp());
return slice;
}
static bool isInitialValueTransitivelySafeToInline(Value initialValue,
DataFlowSolver &solver) {
SmallVector<Operation *> slice = getBackwardSliceIncludingRoot(initialValue);
for (Operation *op : slice) {
for (auto result : op->getResults()) {
auto *state = solver.lookupState<InlineGlobalSlotsAnalysisState>(result);
if (!state->isSafe) {
return false;
}
}
}
return true;
}
namespace {
class InlineGlobalSlotsPass
: public InlineGlobalSlotsBase<InlineGlobalSlotsPass> {
void runOnOperation() override {
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
2022-07-14 02:45:56 +08:00
ModuleOp module = getOperation();
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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DataFlowSolver solver;
solver.load<InlineGlobalSlotsAnalysis>();
if (failed(solver.initializeAndRun(module)))
return signalPassFailure();
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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LLVM_DEBUG({
module->walk([&](Operation *op) {
if (auto globalSlot = dyn_cast<Torch::GlobalSlotOp>(op)) {
auto *state = solver.lookupState<InlineGlobalSlotsAnalysisState>(
solver.getProgramPoint<FlatSymbolRefProgramPoint>(
FlatSymbolRefAttr::get(globalSlot.getSymNameAttr())));
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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state->print(llvm::dbgs());
llvm::dbgs() << ": "
<< FlatSymbolRefAttr::get(globalSlot.getSymNameAttr())
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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<< "\n";
return;
}
if (op->getNumResults() != 1)
return;
auto *state = solver.lookupState<InlineGlobalSlotsAnalysisState>(
op->getResult(0));
state->print(llvm::dbgs());
llvm::dbgs() << ": ";
op->dump();
});
});
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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Torch::InitializeGlobalSlotsOp initialize;
// TODO: Have a torch.module with an optional initializer region to make
// this tighter.
for (auto moduleInitializer :
module.getOps<Torch::GlobalSlotModuleInitializerOp>()) {
initialize = cast<Torch::InitializeGlobalSlotsOp>(
moduleInitializer.getBody()->getTerminator());
}
if (!initialize) {
return;
}
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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DenseSet</*FlatSymbolRefAttr*/ Attribute> safeToInline;
for (int i = 0, e = initialize->getNumOperands(); i != e; i++) {
auto slotSymName =
initialize.getSlotSymNames()[i].cast<FlatSymbolRefAttr>();
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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Value operand = initialize.getOperand(i);
auto symbolRefPoint = solver.getProgramPoint<FlatSymbolRefProgramPoint>(
initialize.getSlotSymNames()[i].cast<FlatSymbolRefAttr>());
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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auto *state =
solver.lookupState<InlineGlobalSlotsAnalysisState>(symbolRefPoint);
// We roll the analysis of whether a slot is set or public into the
// main dataflow analysis, so we need to check the slot's
// FlatSymbolRefProgramPoint itself to see if it is safe to inline.
// For example, a public !torch.int is not safe to inline, even though
// it is a value-semantic type and so the actual initializer value
// itself is conceptually safe to inline.
if (!state->isSafe) {
continue;
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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}
// Check to see if the initializing value is safe to inline.
// This requires a transitive check of all subobjects.
// TODO: This would really be more logical to do as a forward dataflow
// analyis on the whole module initializer rather than doing the
// transitive check backward for each initial value. But it is just
// too much boilerplate to write that with the dataflow framework and we
// generally don't expect long transitive chains of values here -- most
// initial values are just single tensor literals.
if (isInitialValueTransitivelySafeToInline(operand, solver)) {
safeToInline.insert(slotSymName);
}
}
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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SymbolTable symbolTable(module);
DenseSet<Operation *> toErase;
module.walk([&](Torch::GlobalSlotGetOp op) {
if (!safeToInline.count(op.getSlotAttr()))
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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return;
// TODO: Make this more ergonomic.
auto it = llvm::find(initialize.getSlotSymNames(), op.getSlotAttr());
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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Value initialValue = initialize.getOperand(
std::distance(initialize.getSlotSymNames().begin(), it));
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
2022-07-14 02:45:56 +08:00
// It seems inefficient to get a backward slice again here, but we are
// going to be cloning the whole slice anyway, so it doesn't seem like a
// big deal.
SmallVector<Operation *> slice =
getBackwardSliceIncludingRoot(initialValue);
IRMapping mapping;
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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OpBuilder builder(op);
for (Operation *opInSlice : slice)
builder.clone(*opInSlice, mapping);
auto inlinedInitialValue = mapping.lookup(initialValue);
inlinedInitialValue = Torch::adjustStaticInformation(
builder, op.getLoc(), inlinedInitialValue, op.getType(),
/*userAllowsRefinement=*/false);
op.replaceAllUsesWith(inlinedInitialValue);
toErase.insert(op);
});
// Clean up after the transform.
// Erase any pending ops.
for (Operation *op : toErase)
op->erase();
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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// Erase any global slots that we inlined.
// This could be left to SymbolDCE but it's not hard to do here.
for (FlatSymbolRefAttr symName :
llvm::map_range(safeToInline, [](Attribute attr) {
return cast<FlatSymbolRefAttr>(attr);
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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})) {
auto globalSlot =
symbolTable.lookup<Torch::GlobalSlotOp>(symName.getValue());
globalSlot.erase();
}
// Update the initializer.
SmallVector<Attribute> newSlotSymNames;
SmallVector<Value> newInitialValues;
for (int i = 0, e = initialize.getNumOperands(); i != e; i++) {
auto slotSymName =
initialize.getSlotSymNames()[i].cast<FlatSymbolRefAttr>();
Rework how global slot initializers work. Rather than a per-global-slot initializer region, we now have one for the whole module. For example, it might look like this: ``` torch.global_slot "private" @tensor : !torch.tensor torch.global_slot "private" @list : !torch.list<tensor> torch.global_slot.module_initializer { %0 = torch.tensor.literal(dense<0.0> : tensor<f32>) : !torch.tensor %1 = torch.prim.ListConstruct %0 : (!torch.tensor) -> !torch.list<tensor> torch.initialize.global_slots [ @tensor(%0 : !torch.tensor) @list(%1 : !torch.list<tensor>) ] } ``` This new structure allows GlobalizeObjectGraph to create the initializer in a much simpler way, avoiding the need to reason about whether different slots alias each other. Reasoning about whether slots alias each other now is the responsibility of InlineGlobalSlots, which has to do a much more complicated analysis, implemented using MLIR's dataflow analysis framework. Recommended review order: - Check out the new IR constructs in the .mlir files of various passes - Op definitions (*.td) - Changes to GlobalizeObjectGraph pass. - InlineGlobalSlots pass (~total rewrite) - Misc changes: - Moving torchMlirAdjustStaticInformation for sharing with C++ code. - EraseModuleInitializer pass To make this a bit nicer, it would be good to have a `torch.module` op with an initializer region attached. That would be more invasive though. This change has highlighted certain aspects of our project layering which are worth calling out. None of our backends can handle global slots, so we enforce that there are no global slots before backend lowering. At an earlier stage in the project, we had aspirations of transparently handling mutable global state and such, but for reasons described below, that is no longer a goal. So really global slots should be seen as a progressive lowering step as part of inlining all the IValue's in the original program (GlobalizeObjectGraph is also one such step). Over time, with insights from work like IREE-JAX, it has become clear that there isn't a reliable programming model we can compile for users where we just transparently handle mutable global state (and some other things, like lists and dictionaries). There is a need for an "outer program" that orchestrates more restricted subroutines of the kind we can handle in our compile flow here. The benefit of that is that it decouples considerations like shapes, dtypes, etc. from the program constructs used in the outer program. As long as the outer program can efficiently invoke (pipelining/async/etc.) high-performance data-parallel numerical subroutines of the kind we compile in our flow here, then there is a complete programming model. This is also consistent with the direction of upstream PyTorch which is becoming more tracing-based (which inherently loses a lot of program structure, which then has to be applied back with an "outer program" orchestrating the traced subroutines).
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if (!safeToInline.count(slotSymName)) {
newSlotSymNames.push_back(slotSymName);
newInitialValues.push_back(initialize.getOperand(i));
}
}
{
OpBuilder builder(initialize);
builder.create<Torch::InitializeGlobalSlotsOp>(
initialize.getLoc(),
ArrayAttr::get(module.getContext(), newSlotSymNames),
newInitialValues);
}
initialize.erase();
}
};
} // namespace
std::unique_ptr<OperationPass<ModuleOp>>
[torch-mlir earthmoving (1/N)] C/C++ code movement. This creates the `external/torch-mlir` directory as an LLVM_EXTERNAL_PROJECTS-compatible project (analogous to `iree-dialects`) and completes movement/rename of all pure MLIR C/C++ compiler code into there. The next step will be to move all the Python code / code that links/includes PyTorch C++ code (which currently lives in `frontends/pytorch`) into a subdirectory here. I call this "earthmoving" because it is mostly mechanical changes and renames. As a quick summary (we can change this down the road easily) - C++ `mlir::NPCOMP::Torch -> mlir::torch::Torch` - CAPI `npcompTorchListTypeGet -> torchMlirTorchListTypeGet` - preprocessor `#ifndef NPCOMP_ -> #ifndef TORCHMLIR_` - CMake `NPCOMPFoo -> TorchMLIRFoo` The goal of this is to create a standalone project creating a center of mass for entry into the MLIR ecosystem from PyTorch, suitable in scope for eventual inclusion/ownership in PyTorch. The idea is that `external/torch-mlir` will some day be pulled out into its own repository, and then npcomp will simply pull it in as a submodule. Layering-wise, what lives in `torch-mlir` lowers code from PyTorch (currently TorchScript, but TorchFX or pytorch/xla-style tracing are possible extensions) down to what we have been calling the "Torch backend contract" which is cleaned up IR (inlining, simplifcation, conversion to value tensors, ...) entirely in the `torch` dialect. This is the branching off point for further lowering, of which npcomp takes one opinion (outside `torch-mlir` of course!), namely the `TorchConversion` dialect/transforms which lower to IR suitable for IREE and other linalg-on-tensors based lower-level compilers. Summary of changes: - move `{include,lib,test}/Dialect/Torch` into `torch-mlir` - move relevant parts of CAPI into `torch-mlir`. - leave a few things related to the `torch-mlir` Python build commented out, which should be resolved in a subsequent change.
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mlir::torch::Torch::createInlineGlobalSlotsPass() {
return std::make_unique<InlineGlobalSlotsPass>();
}