The dialect conversion-based bufferization passes have been migrated to One-Shot Bufferize about two years ago. To clean up the code base, this commit removes the `func-bufferize` pass, one of the few remaining parts of the old infrastructure. Most bufferization passes have already been removed. Note for LLVM integration: If you depend on this pass, migrate to One-Shot Bufferize or copy the pass to your codebase.
477 lines
22 KiB
Markdown
477 lines
22 KiB
Markdown
# Bufferization
|
|
|
|
[TOC]
|
|
|
|
## Overview
|
|
|
|
Bufferization in MLIR is the process of converting ops with `tensor` semantics
|
|
to ops with `memref` semantics. There are multiple MLIR passes that are related
|
|
to bufferization. These passes typically run as one of the last steps in a
|
|
pass pipeline, right before lowering to `memref` ops to LLVM. That is because
|
|
many transformations are easier or only supported in tensor land; e.g.,
|
|
[tile/fuse/… on tensors first](https://llvm.discourse.group/t/rfc-linalg-on-tensors-update-and-comprehensive-bufferization-rfc/3373),
|
|
then bufferize the remaining IR.
|
|
|
|

|
|
|
|
The most important bufferization pass is *One-Shot Bufferize*: This pass
|
|
rewrites `tensor` IR to `memref` IR. There are additional helper passes that
|
|
preprocess IR (e.g., so that IR can be bufferized more efficiently), perform
|
|
buffer-level optimizations such as allocation hoisting, and
|
|
[insert buffer deallocation ops](OwnershipBasedBufferDeallocation.md) so that
|
|
the resulting `memref` IR has no memory leaks.
|
|
|
|
## Deprecated Passes
|
|
|
|
The buffer deallocation pass has been deprecated in favor of the ownership-based
|
|
buffer deallocation pipeline. The deprecated pass has some limitations that may
|
|
cause memory leaks in the resulting IR.
|
|
|
|
## What is One-Shot Bufferize?
|
|
|
|
One-Shot Bufferize is a tensor bufferization pass designed for IR in
|
|
[destination-passing style](https://www.microsoft.com/en-us/research/wp-content/uploads/2016/11/dps-fhpc17.pdf),
|
|
and with aggressive in-place bufferization.
|
|
|
|
One-Shot Bufferize is:
|
|
|
|
* **Monolithic**: A single MLIR pass does the entire work.
|
|
|
|
* **Extensible** via an op interface: All ops that implement
|
|
`BufferizableOpInterface` can be bufferized.
|
|
|
|
* A **whole-function at a time analysis**. In-place bufferization decisions
|
|
are made by analyzing SSA use-def chains on tensors. Op interface
|
|
implementations not only provide the rewrite logic from tensor ops to memref
|
|
ops, but also helper methods for One-Shot Bufferize's analysis to query
|
|
information about an op's bufferization/memory semantics.
|
|
|
|
* **2-Phase**: Bufferization is internally broken down into 2 steps: First,
|
|
analyze the entire IR and make bufferization decisions. Then, bufferize
|
|
(rewrite) the IR. The analysis has access to exact SSA use-def information.
|
|
It incrementally builds alias and equivalence sets and does not rely on a
|
|
posteriori-alias analysis from preallocated memory.
|
|
|
|
* **Greedy**: Operations are analyzed one-by-one and it is decided on the spot
|
|
whether a tensor OpOperand must be copied or not. Heuristics determine the
|
|
order of analysis.
|
|
|
|
* **Modular**: The current One-Shot Analysis can be replaced with a different
|
|
analysis. The result of the analysis are queried by the bufferization via
|
|
`AnalysisState`, in particular `AnalysisState::isInPlace`. Any derived class
|
|
of `AnalysisState` that implements a small number virtual functions can
|
|
serve as a custom analysis. It is even possible to run One-Shot Bufferize
|
|
without any analysis (`AlwaysCopyAnalysisState`), in which case One-Shot
|
|
Bufferize copies every buffer before writing to it.
|
|
|
|
Note that One-Shot Bufferize does not deallocate buffers. That is done by the
|
|
[Ownership-based Buffer Deallocation passes](OwnershipBasedBufferDeallocation.md).
|
|
|
|
## Goals of Bufferization
|
|
|
|
The high-level goal of every bufferization technique is to:
|
|
|
|
1. Use as little memory as possible.
|
|
2. Copy as little memory as possible.
|
|
|
|
This implies reusing already allocated buffers when possible, turning
|
|
bufferization into an algorithmically complex problem with similarities to
|
|
register allocation.
|
|
|
|
Depending on the concrete use case, there may be additional bufferization
|
|
requirements. If the contents of a buffer are expensive to compute, there could
|
|
be a tradeoff between *recomputation* and *compute once and copy*. On the
|
|
contrary, it may not even be possible to allocate new buffers at runtime on some
|
|
architectures.
|
|
|
|
## Destination-Passing Style
|
|
|
|
Bufferization is an algorithmically complex problem. Given an op with a tensor
|
|
result, bufferization has to choose a memref buffer in which the result can be
|
|
stored. It is always safe to allocate a brand new buffer, but such a
|
|
bufferization strategy would be unacceptable for high-performance codegen. When
|
|
choosing an already existing buffer, we must be careful not to accidentally
|
|
overwrite data that is still needed later in the program.
|
|
|
|
To simplify this problem, One-Shot Bufferize was designed to take advantage of
|
|
*destination-passing style* (DPS). In MLIR, DPS op should implement the
|
|
[`DestinationStyleOpInterface`](https://github.com/llvm/llvm-project/blob/792d437b56adfb3416daf8105942d4899fb82763/mlir/include/mlir/Interfaces/DestinationStyleOpInterface.td).
|
|
DPS exists in itself independently of bufferization and is tied to SSA
|
|
semantics: many ops are "updating" a part of their input SSA variables. For
|
|
example the LLVM instruction
|
|
[`insertelement`](https://llvm.org/docs/LangRef.html#insertelement-instruction)
|
|
is inserting an element inside a vector. Since SSA values are immutable, the
|
|
operation returns a copy of the input vector with the element inserted.
|
|
Another example in MLIR is `linalg.generic` on tensors, which always has an
|
|
extra `outs` operand for each result, which provides the initial values to
|
|
update (for example when the operation is doing a reduction).
|
|
|
|
`outs` operands are referred to as "destinations" in the following (quotes are
|
|
important as this operand isn't modified in place but copied) and comes into
|
|
place in the context of bufferization as a possible "anchor" for the
|
|
bufferization algorithm. This allows the user to shape the input in a form that
|
|
guarantees close to optimal bufferization result when carefully choosing the
|
|
SSA value used as "destination".
|
|
|
|
For every tensor result, a DPS op has a corresponding tensor operand. If there
|
|
aren't any other conflicting uses of this tensor, the bufferization can alias
|
|
it with the op result and perform the operation "in-place" by reusing the buffer
|
|
allocated for this "destination" input.
|
|
|
|
As an example, consider the following op: `%r = tensor.insert %f into
|
|
%t[%idx] : tensor<5xf32>`
|
|
|
|

|
|
|
|
`%t` is the "destination" in this example. When choosing a buffer for the result
|
|
`%r`, denoted as `buffer(%r)`, One-Shot Bufferize considers only two options:
|
|
|
|
1. `buffer(%r) = buffer(%t)`: store the result in the existing `buffer(%t)`.
|
|
Note that this is not always possible. E.g., if the old contents of
|
|
`buffer(%t)` are still needed. One-Shot Bufferize's main task is to detect
|
|
such cases and fall back to the second option when necessary.
|
|
2. `buffer(%r)` is a newly allocated buffer.
|
|
|
|
There may be other buffers in the same function that could potentially be used
|
|
for `buffer(%r)`, but those are not considered by One-Shot Bufferize to keep the
|
|
bufferization simple. One-Shot Bufferize could be extended to consider such
|
|
buffers in the future to achieve a better quality of bufferization.
|
|
|
|
Tensor ops that are not in destination-passing style always bufferized to a
|
|
memory allocation. E.g.:
|
|
|
|
```mlir
|
|
%0 = tensor.generate %sz {
|
|
^bb0(%i : index):
|
|
%cst = arith.constant 0.0 : f32
|
|
tensor.yield %cst : f32
|
|
} : tensor<?xf32>
|
|
```
|
|
|
|
The result of `tensor.generate` does not have a "destination" operand, so
|
|
bufferization allocates a new buffer. This could be avoided by instead using an
|
|
op such as `linalg.generic`, which can express the same computation with a
|
|
"destination" operand, as specified behind outputs (`outs`):
|
|
|
|
```mlir
|
|
#map = affine_map<(i) -> (i)>
|
|
%0 = linalg.generic {indexing_maps = [#map], iterator_types = ["parallel"]}
|
|
outs(%t : tensor<?xf32>) {
|
|
^bb0(%arg0 : f32):
|
|
%cst = arith.constant 0.0 : f32
|
|
linalg.yield %cst : f32
|
|
} -> tensor<?xf32>
|
|
```
|
|
|
|
At first glance, the above `linalg.generic` op may not seem very useful because
|
|
the output tensor `%t` is entirely overwritten. Why pass the tensor `%t` as an
|
|
operand in the first place? As an example, this can be useful for overwriting a
|
|
slice of a tensor:
|
|
|
|
```mlir
|
|
%t = tensor.extract_slice %s [%idx] [%sz] [1] : tensor<?xf32> to tensor<?xf32>
|
|
%0 = linalg.generic ... outs(%t) { ... } -> tensor<?xf32>
|
|
%1 = tensor.insert_slice %0 into %s [%idx] [%sz] [1]
|
|
: tensor<?xf32> into tensor<?xf32>
|
|
```
|
|
|
|
The above example bufferizes to a `memref.subview`, followed by a
|
|
"`linalg.generic` on memrefs" that overwrites the memory of the subview, assuming
|
|
that the slice `%t` has no other user. The `tensor.insert_slice` then bufferizes
|
|
to a no-op (in the absence of RaW conflicts such as a subsequent read of `%s`).
|
|
|
|
RaW conflicts are detected with an analysis of SSA use-def chains (details
|
|
later). One-Shot Bufferize works best if there is a single SSA use-def chain,
|
|
where the result of a tensor op is the operand of the next tensor ops, e.g.:
|
|
|
|
```mlir
|
|
%0 = "my_dialect.some_op"(%t) : (tensor<?xf32>) -> (tensor<?xf32>)
|
|
%1 = "my_dialect.another_op"(%0) : (tensor<?xf32>) -> (tensor<?xf32>)
|
|
%2 = "my_dialect.yet_another_op"(%1) : (tensor<?xf32>) -> (tensor<?xf32>)
|
|
```
|
|
|
|
Buffer copies are likely inserted if the SSA use-def chain splits at some point,
|
|
e.g.:
|
|
|
|
```mlir
|
|
%0 = "my_dialect.some_op"(%t) : (tensor<?xf32>) -> (tensor<?xf32>)
|
|
%1 = "my_dialect.another_op"(%0) : (tensor<?xf32>) -> (tensor<?xf32>)
|
|
|
|
// "yet_another_op" likely needs to read the data of %0, so "another_op" cannot
|
|
// in-place write to buffer(%0).
|
|
%2 = "my_dialect.yet_another_op"(%0) : (tensor<?xf32>) -> (tensor<?xf32>)
|
|
```
|
|
|
|
## Tensor / MemRef Boundary
|
|
|
|
The bufferization dialect provides a few helper ops to connect tensor IR (that
|
|
should be bufferized) with existing buffers (that may be allocated/provided by
|
|
a different runtime/library/etc.).
|
|
|
|
`bufferization.to_memref %t` returns the future buffer of a tensor SSA value.
|
|
`bufferization.to_tensor %m` returns a tensor SSA value for a given MemRef
|
|
buffer. `bufferization.materialize_in_destination` indicates that a tensor value
|
|
should materialize in a certain buffer.
|
|
|
|
Consider the following example, where a TOSA matmul result should materialize in
|
|
an existing buffer `%C`:
|
|
|
|
```mlir
|
|
// Batched TOSA matrix multiplication. %A and %B are the
|
|
// inputs, %C is the output.
|
|
func.func @test_matmul(%A: memref<1x17x19xf32>,
|
|
%B: memref<1x19x29xf32>,
|
|
%C: memref<1x17x29xf32>) {
|
|
|
|
%A_tensor = bufferization.to_tensor %A restrict : memref<1x17x19xf32>
|
|
%B_tensor = bufferization.to_tensor %B restrict : memref<1x19x29xf32>
|
|
|
|
%0 = tosa.matmul %A_tensor, %B_tensor
|
|
: (tensor<1x17x19xf32>, tensor<1x19x29xf32>) ->
|
|
tensor<1x17x29xf32>
|
|
|
|
bufferization.materialize_in_destination
|
|
%0 in restrict writable %C
|
|
: (tensor<1x17x29xf32>, memref<1x17x29xf32>) -> ()
|
|
|
|
return
|
|
}
|
|
```
|
|
|
|
Note that all bufferization ops in this example have the `restrict` unit
|
|
attribute set. This attribute is similar to the C restrict keyword and indicates
|
|
that there is no other `to_tensor` or `materialize_in_destination` op with
|
|
the same or an aliasing MemRef operand. Only such
|
|
`to_tensor`/`materialize_in_destination` ops are supported. The `restrict`
|
|
attribute gives strong aliasing guarantees to the bufferization analysis and
|
|
allows us to look only at the tensor IR in a program. (Ops that do not operate
|
|
on tensors are ignored by the One-Shot Bufferize.)
|
|
|
|
Also note that `tosa.matmul` cannot be bufferized as is: there is no
|
|
`BufferizableOpInterface` implementation for that op. However, the op can be
|
|
lowered to a combination of `tensor.empty` and `linalg.matmul`, which can be
|
|
bufferized.
|
|
|
|
## Using One-Shot Bufferize
|
|
|
|
MLIR provides a pass
|
|
[`-one-shot-bufferize`](https://mlir.llvm.org/docs/Passes/#-one-shot-bufferize-one-shot-bufferize)
|
|
that performs an analysis and bufferizes all ops with tensor semantics that
|
|
implement `BufferizableOpInterface`. For modularity reasons, these op interface
|
|
implementations are typically external models that live in a dialect's
|
|
"Transforms" build unit. (External models are a mechanism for implementing an op
|
|
interface in a different build unit.) It is the user's responsibility to ensure
|
|
that all needed external models are registered before running One-Shot
|
|
Bufferize.
|
|
|
|
By default, One-Shot Bufferize fails when it encounters an op with tensor
|
|
semantics (i.e., tensor result or tensor operand) that is not bufferizable
|
|
(i.e., does not implement `BufferizableOpInterface`). This can be avoided with
|
|
`allow-unknown-ops`. In that case, One-Shot Bufferize inserts
|
|
`to_memref`/`to_tensor` ops around the bufferization boundary.
|
|
|
|
One-Shot Bufferize can be configured to bufferize only ops from a set of
|
|
dialects with `dialect-filter`.
|
|
|
|
One-Shot Bufferize can also be called programmatically with
|
|
[`bufferization::runOneShotBufferize`](https://github.com/llvm/llvm-project/blob/ae2764e835a26bad9774803eca0a6530df2a3e2d/mlir/include/mlir/Dialect/Bufferization/Transforms/OneShotAnalysis.h#L167).
|
|
Alternatively,
|
|
[`bufferization::bufferizeOp`](https://github.com/llvm/llvm-project/blob/ae2764e835a26bad9774803eca0a6530df2a3e2d/mlir/include/mlir/Dialect/Bufferization/Transforms/Bufferize.h#L78)
|
|
skips the analysis and inserts a copy on every buffer write.
|
|
|
|
By default, function boundaries are not bufferized. This is because there are
|
|
currently limitations around function graph bufferization: recursive
|
|
calls are not supported. As long as there are no recursive calls, function
|
|
boundary bufferization can be enabled with `bufferize-function-boundaries`. Each
|
|
tensor function argument and tensor function result is then turned into a
|
|
memref. The layout map of the memref type can be controlled with
|
|
`function-boundary-type-conversion`.
|
|
|
|
## Memory Layouts
|
|
|
|
One-Shot Bufferize bufferizes ops from top to bottom. This works well when all
|
|
ops are bufferizable. However, when encountering a non-bufferizable tensor with
|
|
`allow-unknown-ops`, One-Shot Bufferize must insert `to_memref` ops at the
|
|
bufferization boundary and decide on a memref type. By default, One-Shot
|
|
Bufferize choose the most dynamic memref type wrt. layout maps. E.g.:
|
|
|
|
```mlir
|
|
%0 = "my_dialect.unbufferizable_op(%t) : (tensor<?x?xf32>) -> (tensor<?x?xf32>)
|
|
%1 = tensor.extract %0[%idx1, %idx2] : tensor<?xf32>
|
|
```
|
|
|
|
When bufferizing the above IR, One-Shot Bufferize inserts a `to_memref` ops with
|
|
dynamic offset and strides:
|
|
|
|
```mlir
|
|
%0 = "my_dialect.unbufferizable_op(%t) : (tensor<?x?xf32>) -> (tensor<?x?xf32>)
|
|
%0_m = bufferization.to_memref %0 : memref<?x?xf32, strided<[?, ?], offset: ?>>
|
|
%1 = memref.load %0_m[%idx1, %idx2] : memref<?x?xf32, strided<[?, ?], offset: ?>>
|
|
```
|
|
|
|
All users of `%0` have fully dynamic layout maps. This ensures that the
|
|
bufferized IR composes well with future bufferizations of `unbufferizable_op`
|
|
(maybe bufferized by another pass), regardless of the exact memref type of the
|
|
future bufferization. If the op turns out to be bufferized to an op with a
|
|
simpler memref type (e.g., identity layout map), we expect that canonicalization
|
|
patterns would clean up unnecessarily dynamic layout maps. (Some of these
|
|
canonicalization patterns may not be implemented yet.)
|
|
|
|
One-Shot Bufferize tries to infer the most precise memref type when bufferizing
|
|
an op. If the entire IR is bufferizable, we do not have to resort to
|
|
conservatively use fully dynamic layout maps. In that case, we also do not have
|
|
to rely on canonicalization patterns to clean up the bufferized IR.
|
|
|
|
Note: There are some bufferizable ops for which a percise layout map cannot be
|
|
inferred. E.g., a `tensor.cast` from a `tensor<*xf32>` to a `tensor<?x?xf32>`
|
|
must be bufferized to a `memref.cast` with a memref type that has a fully
|
|
dynamic layout map.
|
|
|
|
One-Shot Bufferize has an option `unknown-type-conversion` to control the
|
|
generation of layout maps when no precise layout can be inferred:
|
|
|
|
* `fully-dynamic-layout-map` uses fully dynamic layout maps and is the default
|
|
behavior. This composes well when IR is partially bufferized.
|
|
* `identity-layout-map` uses static identity layout maps. This option can be
|
|
useful for legacy code that cannot handle memref types with layout maps.
|
|
Note that this setting can lead to additional buffer copies when folding a
|
|
`to_tensor`/`to_memref` pair with memref types that are not cast-compatible.
|
|
|
|
Note: The `unknown-type-conversion` option does not affect layout maps of
|
|
function signatures. There is a separate `function-signature-type-conversion`
|
|
option that controls layout maps of function parameters and function results.
|
|
|
|
## Extending One-Shot Bufferize
|
|
|
|
Custom ops can be bufferized if they implement `BufferizableOpInterface`. Users
|
|
must at least implement the following interface methods.
|
|
|
|
* `bufferizesToMemoryRead`: Return `true` if the buffer of the given tensor
|
|
OpOperand is read.
|
|
* `bufferizesToMemoryWrite`: Return `true` if the buffer of the given tensor
|
|
OpOperand is written (if bufferizing in-place).
|
|
* `getAliasingOpResult`: Return the OpResults that may share the same buffer
|
|
as the given OpOperand. This interface method describes to
|
|
OpOperand-to-OpResult mapping wrt. destination-passing style.
|
|
* `bufferRelation`: Return `BufferRelation::Equivalent` if the given OpResult
|
|
is the exact same memref as the aliasing OpOperand after bufferization (in
|
|
case of in-place bufferization). Otherwise, (e.g., they overlap but are not
|
|
necessarily the exact same memrefs), `BufferRelation::Unknown` should be
|
|
returned. Additional buffer relations will be added in the future, but
|
|
`BufferRelation::Unknown` is always safe.
|
|
* `bufferize`: Rewrite the op with the given rewriter. Ops should be replaced
|
|
with `bufferization::replaceOpWithBufferizedValues`.
|
|
|
|
To get a better intuition of the interface methods, we invite users to take a
|
|
look at existing implementations in MLIR, e.g., the implementation of
|
|
`tensor.insert` or `tensor.extract`.
|
|
|
|
Interface implementations of DPS ops (that implement
|
|
`DestinationStyleOpInterface`) can derive from
|
|
`DstBufferizableOpInterfaceExternalModel`, which provides all necessary
|
|
method implementations except for `bufferize`.
|
|
|
|
## Debugging Buffer Copies
|
|
|
|
To get a better understanding of why One-Shot Bufferize introduced a buffer
|
|
copy, users can run the pass with `test-analysis-only print-conflicts`. Every
|
|
tensor op is then annotated with an attribute that has a boolean value for each
|
|
tensor OpOperand. `true` means that the OpOperand bufferizes in-place. `false`
|
|
means that the OpOperand bufferizes out-of-place and a buffer copy will be
|
|
inserted.
|
|
|
|
There are two reasons why a buffer copy may be inserted.
|
|
|
|
1. Due to a RaW conflict, it is not safe to bufferize in-place. I.e., the
|
|
overwritten data is still needed.
|
|
2. The buffer is not writable. E.g., `memref.global` buffers that are the
|
|
result of `arith.constant` ops are never modified.
|
|
|
|
In the first case, `print-conflicts` illustrates the conflict in the form of a
|
|
("read", "conflicting write", "last write") tuple.
|
|
|
|
A RaW conflict consists of three parts, in the following order according to
|
|
op dominance:
|
|
|
|
1. **Definition:** A tensor `%t` is defined.
|
|
2. **Conflicting Write:** An operation writes to `buffer(%t)`.
|
|
3. **Read:** An operation reads `%t`.
|
|
|
|
When such a RaW conflict is detected during the analysis phase, One-Shot
|
|
Bufferize will insert a buffer copy for the conflicting write.
|
|
|
|
**Example**
|
|
|
|
```mlir
|
|
// RUN: mlir-opt %s -one-shot-bufferize="bufferize-function-boundaries test-analysis-only print-conflicts"
|
|
func.func @test(%arg0: f32, %arg1: f32, %arg2: index, %arg3: index) -> (f32, tensor<3xf32>) {
|
|
// Create a new tensor with [%arg0, %arg0, %arg0].
|
|
%0 = tensor.from_elements %arg0, %arg0, %arg0 : tensor<3xf32>
|
|
|
|
// Insert something into the new tensor.
|
|
%1 = tensor.insert %arg1 into %0[%arg2] : tensor<3xf32>
|
|
|
|
// Read from the old tensor.
|
|
%r = tensor.extract %0[%arg3] : tensor<3xf32>
|
|
|
|
// Return the extracted value and the result of the insertion.
|
|
func.return %r, %1 : f32, tensor<3xf32>
|
|
}
|
|
```
|
|
|
|
The output IR is as follows:
|
|
|
|
```mlir
|
|
func.func @test(%arg0: f32, %arg1: f32, %arg2: index, %arg3: index) -> (f32, tensor<3xf32>) {
|
|
%from_elements = tensor.from_elements %arg0, %arg0, %arg0 {"C_0[DEF: result 0]"} : tensor<3xf32>
|
|
%inserted = tensor.insert %arg1 into %from_elements[%arg2] {"C_0[CONFL-WRITE: 1]", __inplace_operands_attr__ = ["none", "false", "none"]} : tensor<3xf32>
|
|
%extracted = tensor.extract %from_elements[%arg3] {"C_0[READ: 0]", __inplace_operands_attr__ = ["true", "none"]} : tensor<3xf32>
|
|
return {__inplace_operands_attr__ = ["none", "true"]} %extracted, %inserted : f32, tensor<3xf32>
|
|
}
|
|
```
|
|
|
|
Note that the IR was not bufferized. It was merely annotated with the results
|
|
of the bufferization analysis. Every operation with tensor semantics has a
|
|
`__inplace_operands_attr__` attribute with one value per operand. If an operand
|
|
is not a tensor, the respective value is `none`. Otherwise, if the operand was
|
|
decided to be bufferized in-place, the value is `true`. A value of `false`
|
|
indicates a buffer copy. In the above example, a buffer copy would be inserted
|
|
for `tensor.insert`, so that it does not overwrite `buffer(%from_elements)`,
|
|
which is still needed for `tensor.extract`.
|
|
|
|
For each RaW (there is only one in the example), three `C_i` attributes were
|
|
added:
|
|
|
|
* `C_0[DEF: result 0]`: A tensor is defined: 0-th result of
|
|
`tensor.from_elements`.
|
|
* `C_0[CONFL-WRITE: 1]`: An operation (if bufferized in-place) would write into
|
|
the future buffer of the defined tensor: 1-st operand of `tensor.insert`.
|
|
* `C_0[READ: 0]`: An operation reads the tensor definition: 0-th operand of
|
|
`tensor.extract`.
|
|
|
|
The fully bufferized IR (with the inserted buffer copy) is as follows:
|
|
|
|
```mlir
|
|
func.func @test(%arg0: f32, %arg1: f32, %arg2: index, %arg3: index) -> (f32, memref<3xf32>) {
|
|
%c2 = arith.constant 2 : index
|
|
%c1 = arith.constant 1 : index
|
|
%c0 = arith.constant 0 : index
|
|
%alloc = memref.alloc() {alignment = 64 : i64} : memref<3xf32>
|
|
memref.store %arg0, %alloc[%c0] : memref<3xf32>
|
|
memref.store %arg0, %alloc[%c1] : memref<3xf32>
|
|
memref.store %arg0, %alloc[%c2] : memref<3xf32>
|
|
%alloc_0 = memref.alloc() {alignment = 64 : i64} : memref<3xf32>
|
|
memref.copy %alloc, %alloc_0 : memref<3xf32> to memref<3xf32>
|
|
memref.store %arg1, %alloc_0[%arg2] : memref<3xf32>
|
|
%0 = memref.load %alloc[%arg3] : memref<3xf32>
|
|
return %0, %alloc_0 : f32, memref<3xf32>
|
|
}
|
|
```
|
|
|
|
To get a better understanding of the SSA Use-Def Chain Analysis and the RaW
|
|
conflict detection algorithm, interested users may want to refer to:
|
|
|
|
* [Original design document](https://discourse.llvm.org/uploads/short-url/5kckJ3DftYwQokG252teFgw3sYa.pdf)
|
|
* [ODM talk](https://youtu.be/TXEo59CYS9A), ([slides](https://mlir.llvm.org/OpenMeetings/2022-01-13-One-Shot-Bufferization.pdf)).
|
|
* [LLVM Dev Meeting 2023 tutorial slides](https://m-sp.org/downloads/llvm_dev_2023.pdf)
|