Dialect specific types are registered similarly to operations, i.e. registerType<...> within the dialect. Unlike operations, there is no notion of a "verbose" type, that is *all* types must be registered to a dialect. Casting support(isa/dyn_cast/etc.) is implemented by reserving a range of type kinds in the top level Type class as opposed to string comparison like operations.
To support derived types a few hooks need to be implemented:
In the concrete type class:
- static char typeID;
* A unique identifier for the type used during registration.
In the Dialect:
- typeParseHook and typePrintHook must be implemented to provide parser support.
The syntax for dialect extended types is as follows:
dialect-type: '!' dialect-namespace '<' '"' type-specific-data '"' '>'
The 'type-specific-data' is information used to identify different types within the dialect, e.g:
- !tf<"variant"> // Tensor Flow Variant Type
- !tf<"string"> // Tensor Flow String Type
TensorFlow/TensorFlowControl types are now implemented as dialect specific types as a proof
of concept.
PiperOrigin-RevId: 227580052
The entire compiler now looks at structural properties of the function (e.g.
does it have one block, does it contain an if/for stmt, etc) so the only thing
holding up this difference is round tripping through the parser/printer syntax.
Removing this shrinks the compile by ~140LOC.
This is step 31/n towards merging instructions and statements. The last step
is updating the docs, which I will do as a separate patch in order to split it
from this mostly mechanical patch.
PiperOrigin-RevId: 227540453
function pass, and eliminating the need to copy over code and do
interprocedural updates. While here, also improve it to make fewer empty
blocks, and rename it to "LowerIfAndFor" since that is what it does. This is
a net reduction of ~170 lines of code.
As drive-bys, change the splitBlock method to *not* insert an unconditional
branch, since that behavior is annoying for all clients. Also improve the
AsmPrinter to not crash when a block is referenced that isn't linked into a
function.
PiperOrigin-RevId: 227308856
Function::walk functionality into f->walkInsts/Ops which allows visiting all
instructions, not just ops. Eliminate Function::getBody() and
Function::getReturn() helpers which crash in CFG functions, and were only kept
around as a bridge.
This is step 25/n towards merging instructions and statements.
PiperOrigin-RevId: 227243966
printing the entry block in a CFG function's argument line. Since I'm touching
all of the testcases anyway, change the argument list from printing as
"%arg : type" to "%arg: type" which is more consistent with bb arguments.
In addition to being more consistent, this is a much nicer look for cfg functions.
PiperOrigin-RevId: 227240069
consistent and moving the using declarations over. Hopefully this is the last
truly massive patch in this refactoring.
This is step 21/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 227178245
The last major renaming is Statement -> Instruction, which is why Statement and
Stmt still appears in various places.
This is step 19/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 227163082
by about 100 LOC), without changing any existing behavior.
This is step 20/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 227155000
StmtResult -> InstResult, StmtOperand -> InstOperand, and remove the old names.
This is step 17/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 227121537
is the new base of the SSA value hierarchy. This CL also standardizes all the
nomenclature and comments to use 'Value' where appropriate. This also eliminates a large number of cast<MLValue>(x)'s, which is very soothing.
This is step 11/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 227064624
This *only* changes the internal data structures, it does not affect the user visible syntax or structure of MLIR code. Function gets new "isCFG()" sorts of predicates as a transitional measure.
This patch is gross in a number of ways, largely in an effort to reduce the amount of mechanical churn in one go. It introduces a bunch of using decls to keep the old names alive for now, and a bunch of stuff needs to be renamed.
This is step 10/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 227044402
making it more similar to the CFG side of things. It is true that in a deeply
nested case that this is not a guaranteed O(1) time operation, and that 'get'
could lead compiler hackers to think this is cheap, but we need to merge these
and we can look into solutions for this in the future if it becomes a problem
in practice.
This is step 9/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 226983931
BlockArgument arguments of the entry block instead. This makes MLFunctions and
CFGFunctions work more similarly.
This is step 7/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 226966975
The NameLoc can be used to represent a variable, node or method. The
CallSiteLoc has two fields, one represents the concrete location and another
one represents the caller's location. Multiple CallSiteLocs can be chained as
a call stack.
For example, the following call stack
```
AAA
at file1:1
at file2:135
at file3:34
```
can be formed by call0:
```
auto name = NameLoc::get("AAA");
auto file1 = FileLineColLoc::get("file1", 1);
auto file2 = FileLineColLoc::get("file2", 135);
auto file3 = FileLineColLoc::get("file3", 34);
auto call2 = CallSiteLoc::get(file2, file3);
auto call1 = CallSiteLoc::get(file1, call2);
auto call0 = CallSiteLoc::get(name, call1);
```
PiperOrigin-RevId: 226941797
from it. This is necessary progress to squaring away the parent relationship
that a StmtBlock has with its enclosing if/for/fn, and makes room for functions
to have more than one block in the future. This also removes IfClause and ForStmtBody.
This is step 5/n towards merging instructions and statements, NFC.
PiperOrigin-RevId: 226936541
StmtBlock. This is more consistent with IfStmt and also conceptually makes
more sense - a forstmt "isn't" its body, it contains its body.
This is step 1/N towards merging BasicBlock and StmtBlock. This is required
because in the new regime StmtBlock will have a use list (just like BasicBlock
does) of operands, and ForStmt already has a use list for its induction
variable.
This is a mechanical patch, NFC.
PiperOrigin-RevId: 226684158
As MLIR moves towards dialect-specific types, a generic Type::getBitWidth does
not make sense for all of them. Even with the current type system, the bit
width is not defined (and causes the method in question to abort) for all
TensorFlow types.
This commit restricts the bit width definition to primitive standard types that
have a number of bits appearing verbatim in their type, i.e., integers and
floats. As a side effect, it delegates the decision on the bit width of the
`index` to the backends. Existing backends currently hardcode it to 64 bits.
The Type::getBitWidth method is replaced by Type::getIntOrFloatBitWidth that
only applies to integers and floats. The call sites are updated to use the new
method, where applicable, or rewritten so as not rely on it. Incidentally,
this fixes a utility method that did not account for memrefs being allowed to
have vectors as element types in the size computation.
As an observation, several places in the code use Type in places where a more
specific type could be used instead. Some of those are fixed by this commit.
PiperOrigin-RevId: 225844792
Store FloatAttr using more appropriate fltSemantics (mostly fixing up F32/F64 storage, F16/BF16 pending). Previously F32 type was used incorrectly for double (the storage was double). Also add query method that returns fltSemantics for IEEE fp types and use that to verify that the APfloat given matches the type:
* FloatAttr created using APFloat is verified that the semantics of the type and APFloat matches;
* FloatAttr created using double has the APFloat created to match the semantics of the type;
Change parsing of tensor negative splat element to pass in the element type expected. Misc other changes to account for the storage type matching the attribute.
PiperOrigin-RevId: 225821834
We do some limited renaming here but define an alias for OperationInst so that a follow up cl can solely perform the large scale renaming.
PiperOrigin-RevId: 221726963
* Optionally attach the type of integer and floating point attributes to the attributes, this allows restricting a int/float to specific width.
- Currently this allows suffixing int/float constant with type [this might be revised in future].
- Default to i64 and f32 if not specified.
* For index types the APInt width used is 64.
* Change callers to request a specific attribute type.
* Store iN type with APInt of width N.
* This change does not handle the folding of constants of different types (e.g., doing int type promotions to support constant folding i3 and i32), and instead restricts the constant folding to only operate on the same types.
PiperOrigin-RevId: 221722699
Branch instruction arguments were defined and used inconsistently across
different instructions, in both the spec and the implementation. In
particular, conditional and unconditional branch instructions were using
different syntax in the implementation. This led to the IR we produce not
being accepted by the parser. Update the printer to use common syntax: `(`
list-of-SSA-uses `:` list-of-types `)`. The motivation for choosing this
syntax as opposed to the one in the spec, `(` list-of-SSA-uses `)` `:`
list-of-types is double-fold. First, it is tricky to differentiate the label
of the false branch from the type while parsing conditional branches (which is
what apparently motivated the implementation to diverge from the spec in the
first place). Second, the ongoing convergence between terminator instructions
and other operations prompts for consistency between their operand list syntax.
After this change, the only remaining difference between the two is the use of
parentheses. Update the comment of the parser that did not correspond to the
code. Remove the unused isParenthesized argument from parseSSAUseAndTypeList.
Update the spec accordingly. Note that the examples in the spec were _not_
using the EBNF defined a couple of lines above them, but were using the current
syntax. Add a supplementary example of a branch to a basic block with multiple
arguments.
PiperOrigin-RevId: 221162655
These are locations that form a collection of other source locations with an optional metadata attribute.
- Add initial support for print/dump for locations.
Location Printing Examples:
* Unknown : [unknown-location]
* FileLineColLoc : third_party/llvm/llvm/projects/google-mlir/test/TensorFlowLite/legalize.mlir:6:8
* FusedLoc : <"tfl-legalize">[third_party/llvm/llvm/projects/google-mlir/test/TensorFlowLite/legalize.mlir:6:8, third_party/llvm/llvm/projects/google-mlir/test/TensorFlowLite/legalize.mlir:7:8]
- Add diagnostic support for fused locs.
* Prints the first location as the main location and the remaining as "fused from here" notes:
e.g.
third_party/llvm/llvm/projects/google-mlir/test/TensorFlowLite/legalize.mlir:6:8: error: This is an error.
%1 = "tf.add"(%arg0, %0) : (i32, i32) -> i32
^
third_party/llvm/llvm/projects/google-mlir/test/TensorFlowLite/legalize.mlir:7:8: error: Fused from here.
%2 = "tf.relu"(%1) : (i32) -> i32
^
PiperOrigin-RevId: 220835552
This is done by changing Type to be a POD interface around an underlying pointer storage and adding in-class support for isa/dyn_cast/cast.
PiperOrigin-RevId: 219372163
This is done by changing Attribute to be a POD interface around an underlying pointer storage and adding in-class support for isa/dyn_cast/cast.
PiperOrigin-RevId: 218764173
For some of the constant vector / tesor, if the compiler doesn't need to
interpret their elements content, they can be stored in this class to save the
serialize / deserialize cost.
syntax:
`opaque<` tensor-type `,` opaque-string `>`
opaque-string ::= `0x` [0-9a-fA-F]*
PiperOrigin-RevId: 218399426
- Change AllocOp to have a getType() that always returns a MemRefType, since
that is what it requires.
- Rename StandardOps/StandardOpRegistration.cpp ->
StandardOps/OpRegistration.cpp to align with other op sets.
- Add AffineMap::getContext() helper and use it in the asmprinter.
PiperOrigin-RevId: 218205527
a step forward because now every AbstractOperation knows which Dialect it is
associated with, enabling things in the future like "constant folding
hooks" which will be important for layering. This is also a bit nicer on
the registration side of things.
PiperOrigin-RevId: 218104230
We should be able to represent arbitrary precision Float-point values inside
the IR, so compiler optimizations, such as constant folding can be done
independently on the compiling platform.
This CL also added a new field, AttrValueGetter, to the Attr class definition
for TableGen. This field is used to customize which mlir::Attr getter method to
get the defined PrimitiveType.
PiperOrigin-RevId: 218034983
Also rename Operation::is to Operation::isa
Introduce Operation::cast
All of these are for consistency with global dyn_cast/cast/isa operators.
PiperOrigin-RevId: 217878786
The SparseElementsAttr uses (COO) Coordinate List encoding to represents a
sparse tensor / vector. Specifically, the coordinates and values are stored as
two dense elements attributes. The first dense elements attribute is a 2-D
attribute with shape [N, ndims], which contains the indices of the elements
with nonzero values in the constant vector/tensor. The second elements
attribute is a 1-D attribute list with shape [N], which supplies the values for
each element in the first elements attribute. ndims is the rank of the
vector/tensor and N is the total nonzero elements.
The syntax is:
`sparse<` (tensor-type | vector-type)`, ` indices-attribute-list, values-attribute-list `>`
Example: a sparse tensor
sparse<vector<3x4xi32>, [[0, 0], [1, 2]], [1, 2]> represents the dense tensor
[[1, 0, 0, 0]
[0, 0, 2, 0]
[0, 0, 0, 0]]
PiperOrigin-RevId: 217764319
The syntax of dense vecor/tensor attribute value is
`dense<` (tensor-type | vector-type)`,` attribute-list`>`
and
attribute-list ::= `[` attribute-list (`, ` attribute-list)* `]`.
The construction of the dense vector/tensor attribute takes a vector/tensor
type and a character array as arguments. The size of the input array should be
larger than the size specified by the type argument. It also assumes the
elements of the vector or tensor have been trunked to the data type sizes in
the input character array, so it extends the trunked data to 64 bits when it is
retrieved.
PiperOrigin-RevId: 217762811
* Move Return, Constant and AffineApply out into BuiltinOps;
* BuiltinOps are always registered, while StandardOps follow the same dynamic registration;
* Kept isValidX in MLValue as we don't have a verify on AffineMap so need to keep it callable from Parser (I wanted to move it to be called in verify instead);
PiperOrigin-RevId: 216592527
This CL applies the same pattern as AffineMap to IntegerSet: a simple struct
that acts as the storage is allocated in the bump pointer. The IntegerSet is
immutable and accessed everywhere by value.
Note that unlike AffineMap, it is not possible to remove the MLIRContext
parameter when constructing an IntegerSet for now. One possible way to achieve
this would be to add an enum to distinguish between the mathematically empty
set, the universe set and other sets.
This is left for future discussion.
PiperOrigin-RevId: 216545361
This attribute represents a reference to a splat vector or tensor, where all
the elements have the same value. The syntax of the attribute is:
`splat<` (tensor-type | vector-type)`,` attribute-value `>`
PiperOrigin-RevId: 216537997
AbstractOperation* or an Identifier. This makes it possible to get to stuff in
AbstractOperation faster than going through a hash table lookup. This makes
constant folding a bit faster now, but will become more important with
subsequent changes.
PiperOrigin-RevId: 216476772
This CL applies the same pattern as AffineExpr to AffineMap: a simple struct
that acts as the storage is allocated in the bump pointer. The AffineMap is
immutable and accessed everywhere by value.
PiperOrigin-RevId: 216445930
This CL sketches what it takes for AffineExpr to fully have by-value semantics
and not be a not-so-smart pointer anymore.
This essentially makes the underyling class a simple storage struct and
implements the operations on the value type directly. Since there is no
forwarding of operations anymore, we can full isolate the storage class and
make a hard visibility barrier by moving detail::AffineExpr into
AffineExprDetail.h.
AffineExprDetail.h is only included where storage-related information is
needed.
PiperOrigin-RevId: 216385459
This CL:
1. performs the global codemod AffineXExpr->AffineXExprClass and
AffineXExprRef -> AffineXExpr;
2. simplifies function calls by removing the redundant MLIRContext parameter;
3. adds missing binary operator versions of scalar op AffineExpr where it
makes sense.
PiperOrigin-RevId: 216242674
This CL introduces a series of cleanups for AffineExpr value types:
1. to make it clear that the value types should be used, the pointer
AffineExpr types are put in the detail namespace. Unfortunately, since the
value type operator-> only forwards to the underlying pointer type, we
still
need to expose this in the include file for now;
2. AffineExprKind is ok to use, it thus comes out of detail and thus of
AffineExpr
3. getAffineDimExpr, getAffineSymbolExpr, getAffineConstantExpr are
similarly
extracted as free functions and their naming is mande consistent across
Builder, MLContext and AffineExpr
4. AffineBinaryOpEx::simplify functions are made into static free
functions.
In particular it is moved away from AffineMap.cpp where it does not belong
5. operator AffineExprType is made explicit
6. uses the binary operators everywhere possible
7. drops the pointer usage everywhere outside of AffineExpr.cpp,
MLIRContext.cpp and AsmPrinter.cpp
PiperOrigin-RevId: 216207212
This CL makes AffineExprRef into a value type.
Notably:
1. drops llvm isa, cast, dyn_cast on pointer type and uses member functions on
the value type. It may be possible to still use classof (in a followup CL)
2. AffineBaseExprRef aggressively casts constness away: if we mean the type is
immutable then let's jump in with both feet;
3. Drop implicit casts to the underlying pointer type because that always
results in surprising behavior and is not needed in practice once enough
cleanup has been applied.
The remaining negative I see is that we still need to mix operator. and
operator->. There is an ugly solution that forwards the methods but that ends
up duplicating the class hierarchy which I tried to avoid as much as
possible. But maybe it's not that bad anymore since AffineExpr.h would still
contain a single class hierarchy (the duplication would be impl detail in.cpp)
PiperOrigin-RevId: 216188003
1) affineint (as it is named) is not a type suitable for general computation (e.g. the multiply/adds in an integer matmul). It has undefined width and is undefined on overflow. They are used as the indices for forstmt because they are intended to be used as indexes inside the loop.
2) It can be used in both cfg and ml functions, and in cfg functions. As you mention, “symbols” are not affine, and we use affineint values for symbols.
3) Integers aren’t affine, the algorithms applied to them can be. :)
4) The only suitable use for affineint in MLIR is for indexes and dimension sizes (i.e. the bounds of those indexes).
PiperOrigin-RevId: 216057974
This CL starts by replacing AffineExpr* with value-type AffineExprRef in a few
places in the IR. By a domino effect that is pretty telling of the
inconsistencies in the codebase, const is removed where it makes sense.
The rationale is that the decision was concisously made that unique'd types
have pointer semantics without const specifier. This is fine but we should be
consistent. In the end, the only logical invariant is that there should never
be such a thing as a const AffineExpr*, const AffineMap* or const IntegerSet*
in our codebase.
This CL takes a number of shortcuts to killing const with fire, in particular
forcing const AffineExprRef to return the underlying non-const
AffineExpr*. This will be removed once AffineExpr* has disappeared in
containers but for now such shortcuts allow a bit of sanity in this long quest
for cleanups.
The **only** places where const AffineExpr*, const AffineMap* or const
IntegerSet* may still appear is by transitive needs from containers,
comparison operators etc.
There is still one major thing remaining here: figure out why cast/dyn_cast
return me a const AffineXXX*, which in turn requires a bunch of ugly
const_casts. I suspect this is due to the classof
taking const AffineXXXExpr*. I wonder whether this is a side effect of 1., if
it is coming from llvm itself (I'd doubt it) or something else (clattner@?)
In light of this, the whole discussion about const makes total sense to me now
and I would systematically apply the rule that in the end, we should never
have any const XXX in our codebase for unique'd types (assuming we can remove
them all in containers and no additional constness constraint is added on us
from the outside world).
PiperOrigin-RevId: 215811554
This CL uniformizes the uses of AffineExprWrap outside of IR.
The public API of AffineExpr builder is modified to only use AffineExprWrap.
A few places access AffineExprWrap.expr, this is only while the API is in
transition to easily keep track (i.e. make expr private and let the compiler
track the errors).
Parser.cpp exhibits patterns that are dependent on nullptr values so
converting it is left for another CL.
PiperOrigin-RevId: 215642005
This CL retricts shorthand notation printing to only the bounds that can
be roundtripped unambiguously; i.e.:
1. ()[]->(%some_cst) ()[]
2. ()[s0]->(s0) ()[%some_symbol]
Upon inspection it turns out that the constant case was lossy so this CL also
updates it.
Note however that fixing this issue exhibits a potential issues in unroll.mlir.
L488 exhibits a map ()[s0] -> (1)()[%arg0] which could be simplified down to
()[]->(1)()[].
This does not seem like a bug but maybe an undesired complexity in the maps
generated by unrolling.
bondhugula@, care to take a look?
PiperOrigin-RevId: 214531410
The AsmPrinter wrongly assumes that all single ssa-id AffineMap
are the identity map for the purpose of printing.
This CL adds the missing level of indirection as well as a test.
This bug was originally shaken off by the experimental TC->MLIR path.
Before this CL, the test would print:
```
mlfunc @mlfuncsimplemap(%arg0 : affineint, %arg1 : affineint, %arg2 : affineint) {
for %i0 = 0 to %arg0 {
for %i1 = 0 to %i0 {
~~~ should be %arg1
%c42_i32 = constant 42 : i32
}
}
return
}
```
PiperOrigin-RevId: 214120817
verifier. We get most of this infrastructure directly from LLVM, we just
need to adapt it to our CFG abstraction.
This has a few unrelated changes engangled in it:
- getFunction() in various classes was const incorrect, fix it.
- This moves Verifier.cpp to the analysis library, since Verifier depends on
dominance and these are both really analyses.
- IndexedAccessorIterator::reference was defined wrong, leading to really
exciting template errors that were fun to diagnose.
- This flips the boolean sense of the foldOperation() function in constant
folding pass in response to previous patch feedback.
PiperOrigin-RevId: 214046593
Alternatively, we can defined a TFComplexType with a width parameter in the
mlir, then both types can be converted to the same mlir type with different width (like IntegerType).
We chose to use a direct mapping because there are only two TF Complex types.
PiperOrigin-RevId: 213856651
unroll/unroll-and-jam more powerful; add additional affine expr builder methods
- use previously added analysis/simplification to infer multiple of unroll
factor trip counts, making loop unroll/unroll-and-jam more general.
- for loop unroll, support bounds that are single result affine map's with the
same set of operands. For unknown loop bounds, loop unroll will now work as
long as trip count can be determined to be a multiple of unroll factor.
- extend getConstantTripCount to deal with single result affine map's with the
same operands. move it to mlir/Analysis/LoopAnalysis.cpp
- add additional builder utility methods for affine expr arithmetic
(difference, mod/floordiv/ceildiv w.r.t postitive constant). simplify code to
use the utility methods.
- move affine analysis routines to AffineAnalysis.cpp/.h from
AffineStructures.cpp/.h.
- Rename LoopUnrollJam to LoopUnrollAndJam to match class name.
- add an additional simplification for simplifyFloorDiv, simplifyCeilDiv
- Rename AffineMap::getNumOperands() getNumInputs: an affine map by itself does
not have operands. Operands are passed to it through affine_apply, from loop
bounds/if condition's, etc., operands are stored in the latter.
This should be sufficiently powerful for now as far as unroll/unroll-and-jam go for TPU
code generation, and can move to other analyses/transformations.
Loop nests like these are now unrolled without any cleanup loop being generated.
for %i = 1 to 100 {
// unroll factor 4: no cleanup loop will be generated.
for %j = (d0) -> (d0) (%i) to (d0) -> (5*d0 + 3) (%i) {
%x = "foo"(%j) : (affineint) -> i32
}
}
for %i = 1 to 100 {
// unroll factor 4: no cleanup loop will be generated.
for %j = (d0) -> (d0) (%i) to (d0) -> (d0 - d mod 4 - 1) (%i) {
%y = "foo"(%j) : (affineint) -> i32
}
}
for %i = 1 to 100 {
for %j = (d0) -> (d0) (%i) to (d0) -> (d0 + 128) (%i) {
%x = "foo"() : () -> i32
}
}
TODO(bondhugula): extend this to LoopUnrollAndJam as well in the next CL (with minor
changes).
PiperOrigin-RevId: 212661212
- Make the tf-lower-control flow handle error cases better. Add a testcase
that (currently) fails due to type mismatches.
- Factor more code in the verifier for basic block argument checking, and
check more invariants.
- Fix a crasher in the asmprinter on null instructions (which only occurs on
invalid code).
- Fix a bug handling conditional branches with no block operands, it would
access &operands[0] instead of using operands.data().
- Enhance the mlir-opt driver to use the verifier() in a non-crashing mode,
allowing issues to be reported as diagnostics.
PiperOrigin-RevId: 211818291
This CL also includes two other minor changes:
- change the implemented syntax from 'if (cond)' to 'if cond', as specified by MLIR spec.
- a minor fix to the implementation of the ForStmt.
PiperOrigin-RevId: 210618122
This revamps implementation of the loop bounds in the ForStmt, using general representation that supports operands. The frequent case of constant bounds is supported
via special access methods.
This also includes:
- Operand iterators for the Statement class.
- OpPointer::is() method to query the class of the Operation.
- Support for the bound shorthand notation parsing and printing.
- Validity checks for the bound operands used as dim ids and symbols
I didn't mean this CL to be so large. It just happened this way, as one thing led to another.
PiperOrigin-RevId: 210204858
resolver support.
Still TODO are verifier support (to make sure you don't use an attribute for a
function in another module) and the TODO in ModuleParser::finalizeModule that I
will handle in the next patch.
PiperOrigin-RevId: 209361648
print floating point in a structured form that we know can round trip,
enumerate attributes in the visitor so we print affine mapping attributes
symbolically (the majority of the testcase updates).
We still have an issue where the hexadecimal floating point syntax is reparsed
as an integer, but that can evolve in subsequent patches.
PiperOrigin-RevId: 208828876
Prior to this CL, return statement had no explicit representation in MLIR. Now, it is represented as ReturnOp standard operation and is pretty printed according to the return statement syntax. This way statement walkers can process ML function return operands without making special case for them.
PiperOrigin-RevId: 208092424
an operand mapping, which simplifies it a bit. Implement cloning for IfStmt,
rename getThenClause() to getThen() which is unambiguous and less repetitive in
use cases.
PiperOrigin-RevId: 207915990
- introduce affine integer sets into the IR
- parse and print affine integer sets (both inline or outlined) similar to
affine maps
- use integer set for IfStmt's conditional, and implement parsing of IfStmt's
conditional
- fixed an affine expr paren omission bug while one this.
TODO: parse/represent/print MLValue operands to affine integer set references.
PiperOrigin-RevId: 207779408
Unrelated minor change - remove OperationStmt::dropReferences(). Since MLFunction does not have cyclic operand references (it's an AST) destruction can be safely done w/o a special pass to drop references.
PiperOrigin-RevId: 207583024
- deal with non-operation stmt's (if/for stmt's) in loops being unrolled
(unrolling of non-innermost loops works).
- update uses in unrolled bodies to use results of new operations that may be
introduced in the unrolled bodies.
Unrolling now works for all kinds of loop nests - perfect nests, imperfect
nests, loops at any depth, and with any kind of operation in the body. (IfStmt
support not done, hence untested there).
Added missing dump/print method for StmtBlock.
TODO: add test case for outer loop unrolling.
PiperOrigin-RevId: 207314286
- simplify operations with identity elements (multiply by 1, add with 0).
- simplify successive add/mul: fold constants, propagate constants to the
right.
- simplify floordiv and ceildiv when divisors are constants, and the LHS is a
multiply expression with RHS constant.
- fix an affine expression printing bug on paren emission.
- while on this, fix affine-map test cases file (memref's using layout maps
that were duplicates of existing ones should be emitted pointing to the
unique'd one).
PiperOrigin-RevId: 207046738
generalize the asmprinters handling of pretty names to allow arbitrary sugar to
be dumped on various constructs. Give CFG function arguments nice "arg0" names
like MLFunctions get, and give constant integers pretty names like %c37 for a
constant 377
PiperOrigin-RevId: 206953080
Fix b/112039912 - we were recording 'i' instead of '%i' for loop induction variables causing "use of undefined SSA value" error.
PiperOrigin-RevId: 206884644
Two problems: 1) we didn't visit the types in ops correctly, and 2) the
general "T" version of the OpAsmPrinter inserter would match things like
MemRefType& and print it directly.
PiperOrigin-RevId: 206863642
This is still (intentionally) generating redundant parens for nested tightly
binding expressions, but I think that is reasonable for readability sake.
This also print x-y instead of x-(y*1)
PiperOrigin-RevId: 206847212
Induction variables are implemented by inheriting ForStmt from MLValue. ForStmt provides APIs that make this design decision invisible to the ForStmt users.
This CL in combination with cl/206253643 resolves http://b/111769060.
PiperOrigin-RevId: 206655937
* Add tf_control as primitive type;
* Allow $ in bare-id to allow attributes with $ (to make it trivially to mangle a TF attribute);
PiperOrigin-RevId: 206342642
- Update InnermostLoopGatherer to use a post order traversal (linear
time/single traversal).
- Drop getNumNestedLoops().
- Update isInnermost() to use the StmtWalker.
When using return values in conjunction with walkers, the StmtWalker CRTP
pattern doesn't appear to be of any use. It just requires overriding nearly all
of the methods, which is what InnermostLoopGatherer currently does. Please see
FIXME/ENLIGHTENME comments. TODO: figure this out from this CL discussion.
Note
- Comments on visitor/walker base class are out of date; will update when this
CL is finalized.
PiperOrigin-RevId: 206340901
pointer, and ensure that functions are deleted when the module is destroyed.
This exposed the fact that MLFunction had no dtor, and that the dtor in
CFGFunction was broken with cyclic references. Fix both of these problems.
PiperOrigin-RevId: 206051666
- Enhance memref type to allow omission of mappings and address
spaces (implying a default mapping).
- Fix printing of function types to properly recurse with printType
so mappings are printed by name.
- Simplify parsing of AffineMaps a bit now that we have
isSymbolicOrConstant()
PiperOrigin-RevId: 206039755
This looks heavyweight but most of the code is in the massive number of operand accessors!
We need to be able to iterate over all operands to the condbr (all live-outs) but also just
the true/just the false operands too.
PiperOrigin-RevId: 205897704
While fixing this the parser-affine-map.mlir test started failing due to ordering of the printed affine maps. Even the existing CHECK-DAGs weren't enough to disambiguate; a partial match on one line precluded a total match on a following line.
The fix for this was easy - print the affine maps in reference order rather than in DenseMap iteration order.
PiperOrigin-RevId: 205843770
details, returning things in terms of values (which is what most clients want).
Implement support for operands and results on Operation, and simplify the
asmprinter to use it.
PiperOrigin-RevId: 205608853
This patch adds support for basic block arguments including parsing and printing.
In doing so noticed that `ssa-id-and-type` is undefined in the MLIR spec; suggested an implementation in the spec doc.
PiperOrigin-RevId: 205593369
there is now an explicit state class - which only has one instance per top
level FooThing::print call. The FunctionPrinter's now subclass ModulePrinter
so they can just call print on their types and other global stuff. This also
makes the contract strict that the global FooThing::print calls are the public
entrypoints and that the printer implementation is otherwise self contained.
No Functionality Change.
PiperOrigin-RevId: 205409317
is still limited in several ways, which i'll build out in subsequent patches.
Rename the accessor for inst operands/results to make the Operand/Result
versions of these more obscure, allowing getOperand/getResult to traffic
in values (which is what - by far - most clients actually care about).
PiperOrigin-RevId: 205408439
- Drop sub-classing of affine binary op expressions.
- Drop affine expr op kind sub. Represent it as multiply by -1 and add. This
will also be in line with the math form when we'll need to represent a system of
linear equalities/inequalities: the negative number goes into the coefficient
of an affine form. (For eg. x_1 + (-1)*x_2 + 3*x_3 + (-2) >= 0). The folding
simplification will transparently deal with multiplying the -1 with any other
constants. This also means we won't need to simplify a multiply expression
like in x_1 + (-2)*x_2 to a subtract expression (x_1 - 2*x_2) for
canonicalization/uniquing.
- When we print the IR, we will still pretty print to a subtract when possible.
PiperOrigin-RevId: 205298958
Loop bounds and presumed to be constants for now and are stored in ForStmt as affine constant expressions. ML function arguments, return statement operands and loop variable name are dropped for now.
PiperOrigin-RevId: 205256208
- This introduces a new FunctionParser base class to handle logic common
between the kinds of functions we have, e.g. ssa operand/def parsing.
- This introduces a basic symbol table (without support for forward
references!) and links defs and uses.
- CFG functions now parse and build operand lists for operations. The printer
isn't set up for them yet tho.
PiperOrigin-RevId: 205246110
the instruction side of the house.
This has a number of limitations, including that we are still dropping
operands on the floor in the parser. Also, most of the convenience methods
aren't wired up yet. This is enough to get result type lists round tripping
through.
PiperOrigin-RevId: 205148223
Refactors operation parsing to share functionality between CFG and ML functions. ML function construction now goes through a builder, similar to the way it is done for
CFG functions.
PiperOrigin-RevId: 204779279
Allows printing the instruction to string without trailing newline. Making it easier to reuse print to annotate instructions during lowering. And removes need for newline in the print functions of ops.
PiperOrigin-RevId: 204630791
use it.
This also removes "operand" from the affine expr classes: it is unnecessary
verbosity and "operand" will mean something very specific for SSA stuff (we
will have an Operand type).
PiperOrigin-RevId: 203976504
- check for non-affine expressions
- handle negative numbers and negation of id's, expressions
- functions to check if a map is pure affine or semi-affine
- simplify/clean up affine map parsing code
- report more errors messages, more accurate error messages
PiperOrigin-RevId: 203773633
properties:
- They allow type checked dynamic casting from their base Operation.
- They allow nice accessors for C++ clients, e.g. a "getIndex()" method on
'dim' that returns an unsigned.
- They work with both OperationInst/OperationStmt (once OperationStmt is
implemented).
- They get custom printing logic. They will eventually get custom parsing,
verifier, and builder logic as well.
- Out of tree clients can register their own operation set without having to
change MLIR core, e.g. for TensorFlow or custom target instructions.
This registers addf and dim as examples.
PiperOrigin-RevId: 203382993
A recursive descent parser for affine maps/expressions with operator precedence and
associativity. (While on this, sketch out uniqui'ing functionality for affine maps
and affine binary op expressions (partly).)
PiperOrigin-RevId: 203222063
in a container automatically maintain their parent pointers, and change storage
from std::vector to the proper llvm::iplist type.
PiperOrigin-RevId: 202889037
Run test case:
$ mlir-opt test/IR/parser-affine-map.mlir
test/IR/parser-affine-map.mlir:3:30: error: expect '(' at start of map range
#hello_world2 (i, j) [s0] -> i+s0, j)
^
PiperOrigin-RevId: 202736856
class.
Introduce an Identifier class to MLIRContext to represent uniqued identifiers,
introduce string literal support to the lexer, introducing parser and printer
support etc.
PiperOrigin-RevId: 202592007
This is pretty much minimal scaffolding for this step. Basic block arguments,
instructions, other terminators, a proper IR representation for
blocks/instructions, etc are all coming.
PiperOrigin-RevId: 201826439
River Riddle