This supports the lowering of copyin clause initially. The pointer,
allocatable, common block, polymorphic varaibles will be supported
later.
This also includes the following changes:
1. Resolve the COPYIN clause and make the entity as host associated.
2. Fix collectSymbolSet by adding one option to control collecting the
symbol itself or ultimate symbol of it so that it can be used
explicitly differentiate the host and associated variables in
host-association.
3. Add one helper function `lookupOneLevelUpSymbol` to differentiate the
usage of host and associated variables explicitly. The previous
lowering of firstprivate depends on the order of
`createHostAssociateVarClone` and `lookupSymbol` of host symbol. With
this fix, this dependence is removed.
4. Reuse `copyHostAssociateVar` for copying operation of COPYIN clause.
Reviewed By: kiranchandramohan, NimishMishra
Differential Revision: https://reviews.llvm.org/D127468
Some I/O control statements are no-ops when attempted on a bad or
unconnected UNIT=, but the standard says that FLUSH is an error
in that case.
Differential Revision: https://reviews.llvm.org/D128392
While it is indeed an error to use SIZE, SHAPE, or UBOUND on an
assumed-shape dummy argument without also supplying a DIM= argument
to the intrinsic function, it is *not* an error to use these intrinsic
functions on sections or expressions of such arrays. Refine the test
used for the error message.
Differential Revision: https://reviews.llvm.org/D128391
* Make Semantics test doconcurrent01.f90 an expected failure pending a fix
for a problem in recognizing a PURE prefix specifier for a specific procedure
that occurs in new intrinsic module source code,
* review update
* review update
* Increase support for intrinsic module procedures
The f18 standard defines 5 intrinsic modules that define varying numbers
of procedures, including several operators:
2 iso_fortran_env
55 ieee_arithmetic
10 ieee_exceptions
0 ieee_features
6 iso_c_binding
There are existing fortran source files for each of these intrinsic modules.
This PR adds generic procedure declarations to these files for procedures
that do not already have them, together with associated specific procedure
declarations. It also adds the capability of recognizing intrinsic module
procedures in lowering code, making it possible to use existing language
intrinsic code generation for intrinsic module procedures for both scalar
and elemental calls. Code can then be generated for intrinsic module
procedures using existing options, including front end folding, direct
inlining, and calls to runtime support routines. Detailed code generation
is provided for several procedures in this PR, with others left to future PRs.
Procedure calls that reach lowering and don't have detailed implementation
support will generate a "not yet implemented" message with a recognizable name.
The generic procedures in these modules may each have as many as 36 specific
procedures. Most specific procedures are generated via macros that generate
type specific interface declarations. These specific declarations provide
detailed argument information for each individual procedure call, similar
to what is done via other means for standard language intrinsics. The
modules only provide interface declarations. There are no procedure
definitions, again in keeping with how language intrinsics are processed.
This patch is part of the upstreaming effort from fir-dev branch.
Reviewed By: jeanPerier, PeteSteinfeld
Differential Revision: https://reviews.llvm.org/D128431
Co-authored-by: V Donaldson <vdonaldson@nvidia.com>
During the upstreaming process, it was decided to move contents
of the FIR CSE pass to the MLIR pass. Most of the FIR CSE changes
that are used are already moved to the MLIR pass. This patch calls
the MLIR CSE pass in places where the FIR CSE pass is called in the
pass pipeline.
Note: This is part of upstreaming from the fir-dev branch of
https://github.com/flang-compiler/f18-llvm-project.
Reviewed By: awarzynski, clementval
Differential Revision: https://reviews.llvm.org/D128365
Co-authored-by: Eric Schweitz <eschweitz@nvidia.com>
Co-authored-by: Valentin Clement <clementval@gmail.com>
Co-authored-by: Andrzej Warzynski <andrzej.warzynski@arm.com>
This patch refines //when// driver diagnostics are formatted so that
`flang-new` and `flang-new -fc1` behave consistently with `clang` and
`clang -cc1`, respectively. This change only applies to driver diagnostics.
Scanning, parsing and semantic diagnostics are separate and not covered here.
**NEW BEHAVIOUR**
To illustrate the new behaviour, consider the following input file:
```! file.f90
program m
integer :: i = k
end
```
In the following invocations, "error: Semantic errors in file.f90" _will be_
formatted:
```
$ flang-new file.f90
error: Semantic errors in file.f90
./file.f90:2:18: error: Must be a constant value
integer :: i = k
$ flang-new -fc1 -fcolor-diagnostics file.f90
error: Semantic errors in file.f90
./file.f90:2:18: error: Must be a constant value
integer :: i = k
```
However, in the following invocations, "error: Semantic errors in file.f90"
_will not be_ formatted:
```
$ flang-new -fno-color-diagnostics file.f90
error: Semantic errors in file.f90
./file.f90:2:18: error: Must be a constant value
integer :: i = k
$ flang-new -fc1 file.f90
error: Semantic errors in file.f90
./file.f90:2:18: error: Must be a constant value
integer :: i = k
```
Before this change, none of the above would be formatted. Note also that the
default behaviour in `flang-new` is different to `flang-new -fc1` (this is
consistent with Clang).
**NOTES ON IMPLEMENTATION**
Note that the diagnostic options are parsed in `createAndPopulateDiagOpt`s in
driver.cpp. That's where the driver's `DiagnosticEngine` options are set. Like
most command-line compiler driver options, these flags are "claimed" in
Flang.cpp (i.e. when creating a frontend driver invocation) by calling
`getLastArg` rather than in driver.cpp.
In Clang's Options.td, `defm color_diagnostics` is replaced with two separate
definitions: `def fcolor_diagnostics` and def fno_color_diagnostics`. That's
because originally `color_diagnostics` derived from `OptInCC1FFlag`, which is a
multiclass for opt-in options in CC1. In order to preserve the current
behaviour in `clang -cc1` (i.e. to keep `-fno-color-diagnostics` unavailable in
`clang -cc1`) and to implement similar behaviour in `flang-new -fc1`, we can't
re-use `OptInCC1FFlag`.
Formatting is only available in consoles that support it and will normally mean that
the message is printed in bold + color.
Co-authored-by: Andrzej Warzynski <andrzej.warzynski@arm.com>
Reviewed By: rovka
Differential Revision: https://reviews.llvm.org/D126164
Add more diagnostics to fir.coordinate_of to provide better checking
that the IR is sane.
This patch is part of the upstreaming effort from fir-dev branch.
Reviewed By: PeteSteinfeld
Differential Revision: https://reviews.llvm.org/D128255
Co-authored-by: Eric Schweitz <eschweitz@nvidia.com>
This patch is part of the upstreaming effort from fir-dev branch.
Reviewed By: jeanPerier
Differential Revision: https://reviews.llvm.org/D128186
Co-authored-by: Peter Steinfeld <psteinfeld@nvidia.com>
Overflow detection in the folding of int/nint/ceiling is
incorrectly signalling overflow when a negative argument yields
a zero result.
Differential Revision: https://reviews.llvm.org/D127785
Fortran does have negative unit numbers -- they show up in child I/O
subroutines for defined I/O and for OPEN(NEWUNIT=) -- but the runtime
needs to catch the cases where a negative unit number that wasn't
generated by the runtime is passed in for OPEN or for an I/O statement
that would ordinarily create an anonymous "fort.NNN" file for a
hitherto unseen unit.
Differential Revision: https://reviews.llvm.org/D127788
NCOPIES= is currently a std::size_t in the API. If a negative value is
used, the memory allocation will fail. Change it to be a signed integer,
and crash with a message instead if it be negative.
Differential Revision: https://reviews.llvm.org/D127795
When an unconnected unit number is used in a BACKSPACE statement
with ERR=, IOSTAT=, &/or IOMSG= control specifiers, don't crash,
but let the program deal with the error.
Differential Revision: https://reviews.llvm.org/D127782
FIR models Fortran intrinsic types with deliberate KIND values. Like
Fortran, COMPLEX and REAL have related KINDs in FIR. Lowering now
converts REAL types to floating point (MLIR) up front. This patch moves
the code to convert from FIR RealType to MLIR FloatType out of codegen
and into the builder, allowing FIR ComplexTypes to have their element
type returned as an MLIR FloatType.
We should consider whether to replace fir::ComplexType with
mlir::ComplexType at some point. I believe these types are presently
used to convey distinctins in the target ABIs in the Tilikum bridge
however.
This patch is part of the upstreaming effort from fir-dev branch.
Reviewed By: PeteSteinfeld
Differential Revision: https://reviews.llvm.org/D127636
Co-authored-by: Eric Schweitz <eschweitz@nvidia.com>
Track pending "asynchronous" I/O operation IDs so that WAIT statements can
report errors about bad ID numbers.
Lowering will need to extended to call GetAsynchronousId() for a READ or
WRITE statement with ID=n.
Differential Revision: https://reviews.llvm.org/D127421
system_clock intrinsic calls with dynamically optional arguments
Modify intrinsic system_clock calls to allow for an argument that is optional
or a disassociated pointer or an unallocated allocatable. A call with such an
argument is the same as a call that does not specify that argument.
Rename (genIsNotNull -> genIsNotNullAddr) and (genIsNull -> genIsNullAddr)
and add a use of genIsNotNullAddr.
This patch is part of the upstreaming effort from fir-dev branch.
Reviewed By: PeteSteinfeld
Differential Revision: https://reviews.llvm.org/D127616
Co-authored-by: V Donaldson <vdonaldson@nvidia.com>
This relatively small change will allow Flang's frontend driver,
`flang-new -fc1`, to consume and parse MLIR files. Semantically (i.e.
from user's perspective) this is identical to reading LLVM IR files.
Two file extensions are associated with MLIR files: .fir and .mlir. Note
that reading MLIR files makes only sense when running one of the
code-generation actions, i.e. when using one of the following action
flags: -S, -emit-obj, -emit-llvm, -emit-llvm-bc.
The majority of tests that required `tco` to run are updated to also run
with `flang-new -fc1`. A few tests are updated to use `fir-opt` instead
of `tco` (that's the preferred choice when testing a particular MLIR
pass). basic-program.fir is not updated as that test is intended to
verify the behaviour of `tco` specifically.
Differential Revision: https://reviews.llvm.org/D126890
Remove a backwards dependence from Optimizer -> Lower by moving Todo.h
to the optimizer and out of lowering.
This patch is part of the upstreaming effort from fir-dev branch.
Co-authored-by: Eric Schweitz <eschweitz@nvidia.com>
Reviewed By: jeanPerier
Differential Revision: https://reviews.llvm.org/D127292
Move tthe function to allow its usage in the Optimizer/Builder functions.
This patch is part of the upstreaming effort from fir-dev branch.
Reviewed By: jeanPerier
Differential Revision: https://reviews.llvm.org/D127295
This supports lowering parse-tree to MLIR for threadprivate directive
following the OpenMP 5.1 [2.21.2] standard. Take the following as an
example:
```
program m
integer, save :: i
!$omp threadprivate(i)
call sub(i)
!$omp parallel
call sub(i)
!$omp end parallel
end
```
```
func.func @_QQmain() {
%0 = fir.address_of(@_QFEi) : !fir.ref<i32>
%1 = omp.threadprivate %0 : !fir.ref<i32> -> !fir.ref<i32>
fir.call @_QPsub(%1) : (!fir.ref<i32>) -> ()
omp.parallel {
%2 = omp.threadprivate %0 : !fir.ref<i32> -> !fir.ref<i32>
fir.call @_QPsub(%2) : (!fir.ref<i32>) -> ()
omp.terminator
}
return
}
```
A threadprivate operation (omp.threadprivate) is created for all
references to a threadprivate variable. The runtime will appropriately
return a threadprivate var (%1 as above) or its copy (%2 as above)
depending on whether it is outside or inside a parallel region. For
threadprivate access outside the parallel region, the threadprivate
operation is created in instantiateVar. Inside the parallel region, it
is created in createBodyOfOp.
One new utility function collectSymbolSet is created for collecting
all the variables with a property within a evaluation, which may be one
Fortran, or OpenMP, or OpenACC construct.
Reviewed By: kiranchandramohan
Differential Revision: https://reviews.llvm.org/D124226
The previous semantic analysis does not consider when the last part-ref
is scalar or complex part. Refactor the previous code and bring all the
checks into one place. The check starts from the designator by
extracting the dataref wrapped including the substring and complex part
and recursively check the base objects.
Co-authored-by: Peter Klausler <pklausler@nvidia.com>
Reviewed By: klausler
Differential Revision: https://reviews.llvm.org/D126595
OpenMP 5.0 adds a new clause `in_reduction` on OpenMP directives.
This patch adds parser support for the same.
Reviewed By: kiranchandramohan
Differential Revision: https://reviews.llvm.org/D124156
On targets with __float128 available and distinct from long double,
use it to support more kind=16 entry points. This affects mostly
x86-64 targets. This means that more runtime entry points are
defined for lowering to call.
Delete Common/long-double.h and its LONG_DOUBLE macro in favor of
testing the standard macro LDBL_MANT_DIG.
Differential Revision: https://reviews.llvm.org/D127025
Diagnose OPEN(FILE=f) when f is already connected by the same name to
a distinct external I/O unit.
Differential Revision: https://reviews.llvm.org/D127035
Add extra arguments and checks to the runtime support library so that
a call to the intrinsic functions MOD and MODULO with "denominator"
argument P of zero will cause a crash with a source location rather
than an uninformative floating-point error or integer division by
zero signal.
Additional work is required in lowering to (1) pass source file path and
source line number arguments and (2) actually call these runtime
library APIs instead of emitting inline code for MOD &/or MODULO.
Differential Revision: https://reviews.llvm.org/D127034
For example, FINDLOC(A,X) should convert both A and X to COMPLEX(8)
if the operands are REAL(8) and COMPLEX(4), so that comparisons
can be done without losing inforation. The current implementation
unconditionally converts X to the type of the array A.
Differential Revision: https://reviews.llvm.org/D127030
Avoid calls to memcpy with zero byte counts if their address argument
calculations may not be valid expressions.
Differential Revision: https://reviews.llvm.org/D127027
Besides raising the IEEE floating-point overflow exception, treat
a floating-point overflow on input as an I/O error catchable with
ERR=, IOSTAT=, &/or IOMSG=.
Differential Revision: https://reviews.llvm.org/D127022
As an extension for REAL literals, we allow an exponent letter which
matches an explicit kind-param. The standard requires the exponent
to be 'E' if a kind-param is present. This patch
- documents this extension in Extensions.md
- enables a portability warning if it is used with -pedantic
The test case for this, kinds05.f90, needs D125804, which makes
test_errors.py test warnings as well, to actually test the warnings.
I include it already now to keep things together, it will do no harm
(I hope ...).
We also add WARNING-directives to the test kinds04.f90 in preparation
for D125804. As the exponent-letter 'Q' does not imply the same kind
on all platforms, the emitted warnings are platform-dependent.
Therefore, the test is duplicated into two variants which are run
conditionally.
Finally, we promote the portability warning for when the exponent letter
is neither 'E' nor matching the kind-param to a standard warning.
Reviewed By: klausler
Differential Revision: https://reviews.llvm.org/D126459
When two or more generic interfaces are available by declaration or
by USE association at different scoping levels, we need to search
the outer generic interfaces as well as the inner ones, but only after
the inner ones have failed to produce a specific procedure that matches
a given set of actual arguments. This means that it is possible for
a specific procedure of a generic interface of an inner scope to override
a conflicting specific procedure of a generic interface of an outer
scope.
Also cope with forward references to derived types when a generic
interface is also in scope.
Fixes LLVM bug https://github.com/llvm/llvm-project/issues/55240 and
LLVM bug https://github.com/llvm/llvm-project/issues/55300.
Differential Revision: https://reviews.llvm.org/D126587
When processing the literal constants of the various kinds of
INTEGER that are too large by 1 (e.g., 2147483648_4) in expression
analysis, emit a portability warning rather than a fatal error if
the literal constant appears as the operand to a unary minus, since
the folded result will be in range. And don't emit any warning if
the negated literal is coming from a module file -- f18 wrote the
module file and the warning would simply be confusing, especially to
the programmer that wrote (-2147483647_4-1) in the first place.
Further, emit portability warnings for the canonical expressions for
infinities and NaN (-1./0., 0./0., & 1./0.), but not when they appear
in a module file, for the same reason. The Fortran language has no
syntax for these special values so we have to emit expressions that
fold to them.
Fixes LLVM bugs https://github.com/llvm/llvm-project/issues/55086 and
https://github.com/llvm/llvm-project/issues/55081.
Differential Revision: https://reviews.llvm.org/D126584
B/O/Z input overflow is already caught, and real input overflow
is signalled as an IEEE arithmetic exception, but regular decimal
integer overflow was silent.
Differential Revision: https://reviews.llvm.org/D126155
A dummy argument in an entry point of a subprogram with multiple
entry points need not be defined in other entry points. It is only
legal to reference such an argument when calling an entry point that
does have a definition. An entry point without such a definition
needs a local "substitute" definition sufficient to generate code.
It is nonconformant to reference such a definition at runtime.
Most such definitions and associated code will be deleted as dead
code at compile time. However, that is not always possible, as in
the following code. This code is conformant if all calls to entry
point ss set m=3, and all calls to entry point ee set n=3.
subroutine ss(a, b, m, d, k) ! no x, y, n
integer :: a(m), b(a(m)), m, d(k)
integer :: x(n), y(x(n)), n
integer :: k
1 print*, m, k
print*, a
print*, b
print*, d
if (m == 3) return
entry ee(x, y, n, d, k) ! no a, b, m
print*, n, k
print*, x
print*, y
print*, d
if (n /= 3) goto 1
end
integer :: xx(3), yy(5), zz(3)
xx = 5
yy = 7
zz = 9
call ss(xx, yy, 3, zz, 3)
call ss(xx, yy, 3, zz, 3)
end
Lowering currently generates fir::UndefOp's for all unused arguments.
This is usually ok, but cases such as the one here incorrectly access
unused UndefOp arguments for m and n from an entry point that doesn't
have a proper definition.
The problem is addressed by creating a more complete definition of an
unused argument in most cases. This is implemented in large part by
moving the definition of an unused argument from mapDummiesAndResults
to mapSymbolAttributes. The code in mapSymbolAttributes then chooses
one of three code generation options, depending on information
available there.
This patch deals with dummy procedures in alternate entries, and adds
a TODO for procedure pointers (the PFTBuilder is modified to analyze
procedure pointer symbol so that they are not silently ignored, and
instead hits proper TODOs).
BoxAnalyzer is also changed because assumed-sized arrays were wrongfully
categorized as constant shape arrays. This had no impact, except when
there were unused entry points.
Co-authored-by: jeanPerier <jperier@nvidia.com>
Differential Revision: https://reviews.llvm.org/D125867
When a Hollerith (or short character) literal is presented as an actual
argument that corresponds to a dummy argument for which a BOZ literal
would be acceptable, treat the Hollerith as if it had been a BOZ
literal in the same way -- and with the same code -- as f18 already
does for the similar extension in DATA statements.
Differential Revision: https://reviews.llvm.org/D126144
Now that the requirements and implementation of asynchronous I/O are
better understood, adjust their I/O runtime APIs. In particular:
1) Remove the BeginAsynchronousOutput/Input APIs; they're not needed,
since any data transfer statement might have ASYNCHRONOUS= and
(if ASYNCHRONOUS='YES') ID= control list specifiers that need to
at least be checked.
2) Add implementations for BeginWait(All) to check for the error
case of a bad unit number and nonzero ID=.
3) Rearrange and comment SetAsynchronous so that it's clear that
it can be called for READ/WRITE as well as for OPEN.
The implementation remains completely synchronous, but should be conforming.
Where opportunities make sense for true asynchronous implementations of
some big block transfers without SIZE= in the future, we'll need to add
a GetAsynchronousId API to capture ID= on a READ or WRITE; add sourceFile
and sourceLine arguments to BeginWait(All) for good error reporting;
track pending operations in unit.h; and add code to force synchronization
to non-asynchronous I/O operations.
Lowering should call SetAsynchronous when ASYNCHRONOUS= appears as
a control list specifier. It should also set ID=x variables to 0
until such time as we support asynchronous operations, if ever.
This patch only removes the removed APIs from lowering.
Differential Revision: https://reviews.llvm.org/D126143
Forward references to ENTRY names to pass them as actual procedure arguments
don't work in all cases, exposing some basic ordering problems in
name resolution for these symbols. Refactor; create all the
necessary procedure symbols, and either function result or host association
symbols (for subroutines), at the time that the subprogrma scope is
created, so that the names exist in the scope as text "before"
the ENTRY is processed in name resolution. Some processing
remains in PostEntryStmt() so that we can check that an ENTRY with
an explicit distinct RESULT doesn't also have declarations for the
ENTRY name.
Differential Revision: https://reviews.llvm.org/D126142
Convert Fortran parse-tree into MLIR for collapse-clause.
Includes simple Fortran to LLVM-IR test, with auto-generated
check-lines (some of which have been edited by hand).
Reviewed By: kiranchandramohan, shraiysh, peixin
Differential Revision: https://reviews.llvm.org/D125302
This is compiled as C code, so it's a good idea to be explicit about the
prototype. Clang complains about this when -Wstrict-prototypes is used.
Differential Revision: https://reviews.llvm.org/D125672
This was carry over from LLVM IR where the alias definition can
be ambiguous, but MLIR type aliases have no such problems.
Having the `type` keyword is superfluous and doesn't add anything.
This commit drops it, which also nicely aligns with the syntax for
attribute aliases (which doesn't have a keyword).
Differential Revision: https://reviews.llvm.org/D125501
This patch re-factors the driver code in LLVM Flang (frontend +
compiler) to use the MLIR style. For more context, please see:
https://discourse.llvm.org/t/rfc-coding-style-in-the-driver/
Most changes here are rather self-explanatory. Accessors are renamed to
be more consistent with the rest of LLVM (e.g. allSource -->
getAllSources). Additionally, MLIR clang-tidy files are added in the
affected directories.
clang-tidy and clang-format files were copied from MLIR. Small
additional changes are made to silence clang-tidy/clang-format
warnings.
[1] https://mlir.llvm.org/getting_started/DeveloperGuide/
Differential Revision: https://reviews.llvm.org/D125007
Complex component references (z%RE, z%IM) of complex named constants
should be evaluated at compilation time.
Differential Revision: https://reviews.llvm.org/D125341
Fortran 2018 requires that a compiler allow objects whose rank + corank
is 15, and that's our maximum; detect and diagnose violations.
Differential Revision: https://reviews.llvm.org/D125153
Evaluate real-valued references to the intrinsic functions MODULO
and MOD at compilation time without recourse to an external math
library.
Differential Revision: https://reviews.llvm.org/D125151
Fold references to the intrinsic function DIM with constant real
arguments. And clean up folding of comparisons with NaNs to address
a problem noticed in testing -- NaNs should successfully compare
unequal to all values, including themselves, instead of failing all
comparisons.
Differential Revision: https://reviews.llvm.org/D125146
Kiran Chandramohan