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llvm-mirror/unittests/ADT/SparseBitVectorTest.cpp
Roman Lebedev f69ee08c94 [unittests] ADT: silence -Wself-assign diagnostics
Summary:
D44883 extends -Wself-assign to also work on C++ classes.
In it's current state (as suggested by @rjmccall), it is not under it's own sub-group.
Since that diag is enabled by `-Wall`, stage2 testing showed that:
* It does not fire on any llvm code
* It does fire for these 3 unittests
* It does fire for libc++ tests

This diff simply silences those new warnings in llvm's unittests.
A similar diff will be needed for libcxx. (`libcxx/test/std/language.support/support.types/byteops/`, maybe something else)

Since i don't think we want to repeat rL322901, let's talk about it.
I've subscribed everyone who i think might be interested...

There are several ways forward:
* Not extend -Wself-assign, close D44883. Not very productive outcome i'd say.
* Keep D44883 in it's current state.
  Unless your custom overloaded operators do something unusual for when self-assigning,
  the warning is no less of a false-positive than the current -Wself-assign.
  Except for tests of course, there you'd want to silence it. The current suggestion is:
  ```
  S a;
  a = (S &)a;
  ```
* Split the diagnostic in two - `-Wself-assign-builtin` (i.e. what is `-Wself-assign` in trunk),
  and `-Wself-assign-overloaded` - the new part in D44883.
  Since, as i said, i'm not really sure why it would be less of a error than the current `-Wself-assign`,
  both would still be in `-Wall`. That way one could simply pass `-Wno-self-assign-overloaded` for all the tests.
  Pretty simple to do, and will surely work.
* Split the diagnostic in two - `-Wself-assign-trivial`, and `-Wself-assign-nontrivial`.
  The choice of which diag to emit would depend on trivial-ness of that particular operator.
  The current `-Wself-assign` would be `-Wself-assign-trivial`.
  https://godbolt.org/g/gwDASe - `A`, `B` and `C` case would be treated as trivial, and `D`, `E` and `F` as non-trivial.
  Will be the most complicated to implement.

Thoughts?

Reviewers: aaron.ballman, rsmith, rtrieu, rjmccall, dblaikie, atrick, gottesmm

Reviewed By: dblaikie

Subscribers: lebedev.ri, phosek, vsk, rnk, thakis, sammccall, mclow.lists, llvm-commits, rjmccall

Differential Revision: https://reviews.llvm.org/D45082

llvm-svn: 329491
2018-04-07 10:37:18 +00:00

170 lines
3.5 KiB
C++

//===- llvm/unittest/ADT/SparseBitVectorTest.cpp - SparseBitVector tests --===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/ADT/SparseBitVector.h"
#include "gtest/gtest.h"
using namespace llvm;
namespace {
TEST(SparseBitVectorTest, TrivialOperation) {
SparseBitVector<> Vec;
EXPECT_EQ(0U, Vec.count());
EXPECT_FALSE(Vec.test(17));
Vec.set(5);
EXPECT_TRUE(Vec.test(5));
EXPECT_FALSE(Vec.test(17));
Vec.reset(6);
EXPECT_TRUE(Vec.test(5));
EXPECT_FALSE(Vec.test(6));
Vec.reset(5);
EXPECT_FALSE(Vec.test(5));
EXPECT_TRUE(Vec.test_and_set(17));
EXPECT_FALSE(Vec.test_and_set(17));
EXPECT_TRUE(Vec.test(17));
Vec.clear();
EXPECT_FALSE(Vec.test(17));
}
TEST(SparseBitVectorTest, IntersectWith) {
SparseBitVector<> Vec, Other;
Vec.set(1);
Other.set(1);
EXPECT_FALSE(Vec &= Other);
EXPECT_TRUE(Vec.test(1));
Vec.clear();
Vec.set(5);
Other.clear();
Other.set(6);
EXPECT_TRUE(Vec &= Other);
EXPECT_TRUE(Vec.empty());
Vec.clear();
Vec.set(5);
Other.clear();
Other.set(225);
EXPECT_TRUE(Vec &= Other);
EXPECT_TRUE(Vec.empty());
Vec.clear();
Vec.set(225);
Other.clear();
Other.set(5);
EXPECT_TRUE(Vec &= Other);
EXPECT_TRUE(Vec.empty());
}
TEST(SparseBitVectorTest, SelfAssignment) {
SparseBitVector<> Vec, Other;
Vec.set(23);
Vec.set(234);
Vec = static_cast<SparseBitVector<> &>(Vec);
EXPECT_TRUE(Vec.test(23));
EXPECT_TRUE(Vec.test(234));
Vec.clear();
Vec.set(17);
Vec.set(256);
EXPECT_FALSE(Vec |= Vec);
EXPECT_TRUE(Vec.test(17));
EXPECT_TRUE(Vec.test(256));
Vec.clear();
Vec.set(56);
Vec.set(517);
EXPECT_FALSE(Vec &= Vec);
EXPECT_TRUE(Vec.test(56));
EXPECT_TRUE(Vec.test(517));
Vec.clear();
Vec.set(99);
Vec.set(333);
EXPECT_TRUE(Vec.intersectWithComplement(Vec));
EXPECT_TRUE(Vec.empty());
EXPECT_FALSE(Vec.intersectWithComplement(Vec));
Vec.clear();
Vec.set(28);
Vec.set(43);
Vec.intersectWithComplement(Vec, Vec);
EXPECT_TRUE(Vec.empty());
Vec.clear();
Vec.set(42);
Vec.set(567);
Other.set(55);
Other.set(567);
Vec.intersectWithComplement(Vec, Other);
EXPECT_TRUE(Vec.test(42));
EXPECT_FALSE(Vec.test(567));
Vec.clear();
Vec.set(19);
Vec.set(21);
Other.clear();
Other.set(19);
Other.set(31);
Vec.intersectWithComplement(Other, Vec);
EXPECT_FALSE(Vec.test(19));
EXPECT_TRUE(Vec.test(31));
Vec.clear();
Vec.set(1);
Other.clear();
Other.set(59);
Other.set(75);
Vec.intersectWithComplement(Other, Other);
EXPECT_TRUE(Vec.empty());
}
TEST(SparseBitVectorTest, Find) {
SparseBitVector<> Vec;
Vec.set(1);
EXPECT_EQ(1, Vec.find_first());
EXPECT_EQ(1, Vec.find_last());
Vec.set(2);
EXPECT_EQ(1, Vec.find_first());
EXPECT_EQ(2, Vec.find_last());
Vec.set(0);
Vec.set(3);
EXPECT_EQ(0, Vec.find_first());
EXPECT_EQ(3, Vec.find_last());
Vec.reset(1);
Vec.reset(0);
Vec.reset(3);
EXPECT_EQ(2, Vec.find_first());
EXPECT_EQ(2, Vec.find_last());
// Set some large bits to ensure we are pulling bits from more than just a
// single bitword.
Vec.set(500);
Vec.set(2000);
Vec.set(3000);
Vec.set(4000);
Vec.reset(2);
EXPECT_EQ(500, Vec.find_first());
EXPECT_EQ(4000, Vec.find_last());
Vec.reset(500);
Vec.reset(3000);
Vec.reset(4000);
EXPECT_EQ(2000, Vec.find_first());
EXPECT_EQ(2000, Vec.find_last());
Vec.clear();
}
}