We already parse boolean "true"/"false" as ElementsAttr elements.
This CL makes it round-trippable that we are printing the same way.
PiperOrigin-RevId: 258784962
This allows for the attribute to hold symbolic references to other operations than FuncOp. This also allows for removing the dependence on FuncOp from the base Builder.
PiperOrigin-RevId: 257650017
This changes the top-level module parser to handle the case where the top-level module is defined with the module operation syntax, i.e:
module ... {
}
The printer is also updated to always print the top-level module in this form. This allows for cleanly round-tripping the location and attributes of the top-level module.
PiperOrigin-RevId: 257492069
The ModulePrinter prints the newline now for children of the top-level module. This also fixes the location printing for functions as the location used to be printed on a different line.
PiperOrigin-RevId: 257447633
This was an arbitrary restriction caused by the way that modules were printed. Now that that has been fixed, this restriction can be removed.
PiperOrigin-RevId: 257240329
Change the AsmPrinter to number values breadth-first so that values in adjacent regions can have the same name. This allows for ModuleOp to contain operations that produce results. This also standardizes the special name of region entry arguments to "arg[0-9+]" now that Functions are also operations.
PiperOrigin-RevId: 257225069
These methods assume that a function is a valid builtin top-level operation, and removing these methods allows for decoupling FuncOp and IR/. Utility "getParentOfType" methods have been added to Operation/OpState to allow for querying the first parent operation of a given type.
PiperOrigin-RevId: 257018913
This is an important step in allowing for the top-level of the IR to be extensible. FuncOp and ModuleOp contain all of the necessary functionality, while using the existing operation infrastructure. As an interim step, many of the usages of Function and Module, including the name, will remain the same. In the future, many of these will be relaxed to allow for many different types of top-level operations to co-exist.
PiperOrigin-RevId: 256427100
As with Functions, Module will soon become an operation, which are value-typed. This eases the transition from Module to ModuleOp. A new class, OwningModuleRef is provided to allow for owning a reference to a Module, and will auto-delete the held module on destruction.
PiperOrigin-RevId: 256196193
Move the data members out of Function and into a new impl storage class 'FunctionStorage'. This allows for Function to become value typed, which will greatly simplify the transition of Function to FuncOp(given that FuncOp is also value typed).
PiperOrigin-RevId: 255983022
Remove the ability to print an attribute without a type, but allow for attributes to elide the type under certain circumstances. This fixes a bug where attributes within ArrayAttr, and other collection attributes, would never print the type.
PiperOrigin-RevId: 255306974
The current syntax separates the name and value with ':', but ':' is already overloaded by several other things(e.g. trailing types). This makes the syntax difficult to parse in some situtations:
Old:
"foo: 10 : i32"
New:
"foo = 10 : i32"
PiperOrigin-RevId: 255097928
This is the standard syntax for types on operations, and is also already used by IntegerAttr and FloatAttr.
Example:
dense<5> : tensor<i32>
dense<[3]> : tensor<1xi32>
PiperOrigin-RevId: 255069157
The new operations affine.load and affine.store will take composed affine maps by construction.
These operations will eventually replace load and store operations currently used in affine regions and operated on by affine transformation and analysis passes.
PiperOrigin-RevId: 254754048
This will allow for locations to be used in the same contexts as attributes. Given that attributes are nullable types, the 'Location' class now represents a non-nullable wrapper around a 'LocationAttr'. This preserves the desired semantics we have for non-optional locations.
PiperOrigin-RevId: 254505278
MemRefs have the same notion of shape, rank, and fixed element type. This allows us to reuse utilities based on shape for memref.
All dyn_cast and isa calls for ShapedType have been checked and either modified to explicitly check for vector or tensor, or confirmed to not depend on the result being a vector or tensor.
Discussion in https://groups.google.com/a/tensorflow.org/forum/#!topic/mlir/cHLoyfGu8y8
--
PiperOrigin-RevId: 250945184
* There is no longer a need to explicitly remap function attrs.
- This removes a potentially expensive call from the destructor of Function.
- This will enable some interprocedural transformations to now run intraprocedurally.
- This wasn't scalable and forces dialect defined attributes to override
a virtual function.
* Replacing a function is now a trivial operation.
* This is a necessary first step to representing functions as operations.
--
PiperOrigin-RevId: 249510802
This is in preparation for making it also support/be a parent class of MemRefType. MemRefs have similar shape/rank/element semantics and it would be useful to be able to use these same utilities for them.
This CL should not change any semantics and only change variables, types, string literals, and comments. In follow-up CLs I will prepare all callers to handle MemRef types or remove their dependence on ShapedType.
Discussion/Rationale in https://groups.google.com/a/tensorflow.org/forum/#!topic/mlir/cHLoyfGu8y8
--
PiperOrigin-RevId: 248476449
`#` alias `=` attribute-value
This also allows for dialects to define aliases for attributes in the AsmPrinter. The printer supports two types of attribute aliases, 'direct' and 'kind'.
* Direct aliases are synonymous with the current support for type aliases, i.e. this maps an alias to a specific instance of an attribute.
// A direct alias ("foo_str") for the string attribute "foo".
#foo_str = "foo"
* Kind aliases generates unique names for all instances of a given attribute kind. The generated aliases are of the form: `alias[0-9]+`.
// A kind alias ("strattr") for all string attributes could generate.
#strattr0 = "foo"
#strattr1 = "bar"
...
#strattrN = "baz"
--
PiperOrigin-RevId: 246851916
The generic form of operations currently supports optional regions to be
located after the operation type. As we are going to add a type to each
region in a leading position in the region syntax, similarly to functions, it
becomes ambiguous to have regions immediately after the operation type. Put
regions between operands the optional list of successors in the generic
operation syntax and wrap them in parentheses. The effect on the exisitng IR
syntax is minimal since only three operations (`affine.for`, `affine.if` and
`gpu.kernel`) currently use regions.
--
PiperOrigin-RevId: 246787087
none-type ::= `none`
The `none` type is a unit type, i.e. a type with exactly one possible value, where its value does not have a defined dynamic representation.
--
PiperOrigin-RevId: 245599248
A unit attribute is an attribute that represents a value of `unit` type. The
`unit` type allows only one value forming a singleton set. This attribute value
is used to represent attributes that only have meaning from their existence.
One example of such an attribute could be the `swift.self` attribute. This attribute indicates that a function parameter is the self/context
parameter. It could be represented as a boolean attribute(true or false), but a
value of false doesn't really bring any value. The parameter either is the
self/context or it isn't.
```mlir {.mlir}
// A unit attribute defined with the `unit` value specifier.
func @verbose_form(i1 {unitAttr : unit})
// A unit attribute can also be defined without the `unit` value specifier.
func @simple_form(i1 {unitAttr})
```
--
PiperOrigin-RevId: 245254045
The per-layer format is now like:
!quant.uniform<i8<-8:7>:f32, 9.987200e-01:127>
and per-axis is:
!quant.uniform<i8:f32:1, {2.0e+2,0.99872:120}>
I used the following sed script to update the unit tests (invoked with commands like `sed -i -r -f fix_quant.sed $(find . -name '*.mlir')`).
---
# Per-layer
s|\!quant<"uniform\[([iu][0-9]+):([fb]+[0-9]+)\]\{([^\}]+)\}\s*">|!quant.uniform<\1:\2, \3>|g
s|\!quant<"uniform\[([iu][0-9]+)\(([^\)]+)\):([fb]+[0-9]+)\]\{([^\}]+)\}\s*">|!quant.uniform<\1<\2>:\3, \4>|g
# Per-axis
s|\!quant<"uniform\[([iu][0-9]+):([fb]+[0-9]+)(:[0-9]+)?\]\{([^\}]+)\}\s*">|!quant.uniform<\1:\2\3, {\4}>|g
s|\!quant<"uniform\[([iu][0-9]+)\(([^\)]+)\):([fb]+[0-9]+)(:[0-9]+)?\]\{([^\}]+)\}\s*">|!quant.uniform<\1<\2>:\3\4, {\5}>|g
---
I fixed up the one file of error cases manually.
Since this is a one time syntax fix, I am not persisting the script anywhere.
--
PiperOrigin-RevId: 244425331
other characters within the <>'s now that we can. This will allow quantized
types to use the pretty syntax (among others) after a few changes.
--
PiperOrigin-RevId: 243521268
making the IR dumps much nicer.
This is part 2/3 of the path to making dialect types more nice. Part 3/3 will
slightly generalize the set of characters allowed in pretty types and make it
more principled.
--
PiperOrigin-RevId: 242249955
have no standard ops for working with these yet, this is simply enough to
represent and round trip them in the printer and parser.
--
PiperOrigin-RevId: 241102728
Example:
%call:2 = call @multi_return() : () -> (f32, i32)
use(%calltensorflow/mlir#0, %calltensorflow/mlir#1)
This cl also adds parser support for uniquely named result values. This means that a test writer can now write something like:
%foo, %bar = call @multi_return() : () -> (f32, i32)
use(%foo, %bar)
Note: The printer will still print the collapsed form.
PiperOrigin-RevId: 240860058
Due to legacy reasons (ML/CFG function separation), regions in affine control
flow operations require contained blocks not to have terminators. This is
inconsistent with the notion of the block and may complicate code motion
between regions of affine control operations and other regions.
Introduce `affine.terminator`, a special terminator operation that must be used
to terminate blocks inside affine operations and transfers the control back to
he region enclosing the affine operation. For brevity and readability reasons,
allow `affine.for` and `affine.if` to omit the `affine.terminator` in their
regions when using custom printing and parsing format. The custom parser
injects the `affine.terminator` if it is missing so as to always have it
present in constructed operations.
Update transformations to account for the presence of terminator. In
particular, most code motion transformation between loops should leave the
terminator in place, and code motion between loops and non-affine blocks should
drop the terminator.
PiperOrigin-RevId: 240536998
tblgen be non-const. This requires introducing some const_cast's at the
moment, but those (and lots more stuff) will disappear in subsequent patches.
This significantly simplifies those patches because the various tblgen op emitters
get adjusted.
PiperOrigin-RevId: 239954566
This also eliminates some incorrect reinterpret_cast logic working around it, and numerous const-incorrect issues (like block argument iteration).
PiperOrigin-RevId: 239712029
Dialect attributes are defined as:
dialect-namespace `.` attr-name `:` attribute-value
Dialects can override any of the following hooks to verify the validity of a given attribute:
* verifyFunctionAttribute
* verifyFunctionArgAttribute
* verifyInstructionAttribute
PiperOrigin-RevId: 236507970
Associates opaque constants with a particular dialect. Adds general mechanism to register dialect-specific hooks defined in external components. Adds hooks to decode opaque tensor constant and extract an element of an opaque tensor constant.
This CL does not change the existing mechanism for registering constant folding hook yet. One thing at a time.
PiperOrigin-RevId: 233544757
Existing type syntax contains the following productions:
function-type ::= type-list-parens `->` type-list
type-list ::= type | type-list-parens
type ::= <..> | function-type
Due to these rules, when the parser sees `->` followed by `(`, it cannot
disambiguate if `(` starts a parenthesized list of function result types, or a
parenthesized list of operands of another function type, returned from the
current function. We would need an unknown amount of lookahead to try to find
the `->` at the right level of function nesting to differentiate between type
lists and singular function types.
Instead, require the result type of the function that is a function type itself
to be always parenthesized, at the syntax level. Update the spec and the
parser to correspond to the production rule names used in the spec (although it
would have worked without modifications). Fix the function type parsing bug in
the process, as it used to accept the non-parenthesized list of types for
arguments, disallowed by the spec.
PiperOrigin-RevId: 232528361
In optional attribute dictionary used, among others, in the generic form of the
ops, attribute types for integers and floats are omitted. This could lead to
inconsistencies when round-tripping the IR, in particular the attributes are
created with incorrect types after parsing (integers default to i64, floats
default to f64). Provide API to emit a trailing type after the attribute for
integers and floats. Use it while printing the optional attribute dictionary.
Omitting types for i64 and f64 is a pragmatic decision that minimizes changes
in tests. We may want to reconsider in the future and always print types of
attributes in the generic form.
PiperOrigin-RevId: 232480116
The generic form may be more desirable even when there is a custom form
specified so add option to enable emitting it. This also exposes a current bug
when round tripping constant with function attribute.
PiperOrigin-RevId: 232350712
Use `-mlir-pretty-debuginfo` if the user wants line breaks between different callsite lines.
The print results before and after this CL are shown in the tests.
PiperOrigin-RevId: 231013812
Example inline notation:
trailing-location ::= 'loc' '(' location ')'
// FileLineCol Location.
%1 = "foo"() : () -> i1 loc("mysource.cc":10:8)
// Name Location
return loc("foo")
// CallSite Location
return loc(callsite("foo" at "mysource.cc":19:9))
// Fused Location
/// Without metadata
func @inline_notation() loc(fused["foo", "mysource.cc":10:8])
/// With metadata
return loc(fused<"myPass">["foo", "foo2"])
// Unknown location.
return loc(unknown)
Locations are currently only printed with inline notation at the line of each instruction. Further work is needed to allow for reference notation, e.g:
...
return loc 1
}
...
loc 1 = "source.cc":10:1
PiperOrigin-RevId: 230587621
This CL just changes various docs and comments to use the term "generic" and
"custom" when mentioning assembly forms. To be consist, several methods are
also renamed:
* FunctionParser::parseVerboseOperation() -> parseGenericOperation()
* ModuleState::hasShorthandForm() -> hasCustomForm()
* OpAsmPrinter::printDefaultOp() -> printGenericOp()
PiperOrigin-RevId: 230568819
- print multiplication by -1 as unary negate; expressions like s0 * -1, d0 * -1
+ d1 will now appear as -s0, -d0 + d1 resp.
- a minor cleanup while on printAffineExprInternal
PiperOrigin-RevId: 230222151
Originally, terminators were special kinds of operation and could not be
extended by dialects. Only builtin terminators were supported and they had
custom parsers and printers. Currently, "terminator" is a property of an
operation, making it possible for dialects to define custom terminators.
However, verbose forms of operation syntax were not designed to support
terminators that may have a list of successors (each successor contains a block
name and an optional operand list). Calling printDefaultOp on a terminator
drops all successor information. Dialects are thus required to provide custom
parsers and printers for their terminators.
Introduce the syntax for the list of successors in the verbose from of the
operation. Add support for printing and parsing verbose operations with
successors.
Note that this does not yet add support for unregistered terminators since
"terminator" is a property stored in AsbtractOperation and therefore is only
available for registered operations that have an instance of AbstractOperation.
Add tests for verbose parsing. It is currently impossible to test round-trip
for verbose terminators because none of the known dialects use verbose syntax
for printing terminators by default, however the printer was exercised on the
LLVM IR dialect prototype.
PiperOrigin-RevId: 228566453
- refactor toAffineFromEq and the code surrounding it; refactor code into
FlatAffineConstraints::getSliceBounds
- add FlatAffineConstraints methods to detect identifiers as mod's and div's of other
identifiers
- add FlatAffineConstraints::getConstantLower/UpperBound
- Address b/122118218 (don't assert on invalid fusion depths cmdline flags -
instead, don't do anything; change cmdline flags
src-loop-depth -> fusion-src-loop-depth
- AffineExpr/Map print method update: don't fail on null instances (since we have
a wrapper around a pointer, it's avoidable); rationale: dump/print methods should
never fail if possible.
- Update memref-dataflow-opt to add an optimization to avoid a unnecessary call to
IsRangeOneToOne when it's trivially going to be true.
- Add additional test cases to exercise the new support
- update a few existing test cases since the maps are now generated uniformly with
all destination loop operands appearing for the backward slice
- Fix projectOut - fix wrong range for getBestElimCandidate.
- Fix for getConstantBoundOnDimSize() - didn't show up in any test cases since
we didn't have any non-hyperrectangular ones.
PiperOrigin-RevId: 228265152
Lei Zhang