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llvm / llvm / 2a9e5ad32e9df64f89df4f58f5b49c74ee3e07f4 / . / unittests / XRay / GraphTest.cpp
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//===- llvm/unittest/XRay/GraphTest.cpp - XRay Graph unit tests -*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/XRay/Graph.h"
#include "gtest/gtest.h"
#include <iostream>
#include <set>
#include <type_traits>
using namespace llvm;
using namespace xray;
namespace {
struct VAttr {
unsigned VA;
};
struct EAttr {
unsigned EA;
};
typedef Graph<VAttr, EAttr, unsigned> GraphT;
typedef typename GraphT::VertexIdentifier VI;
typedef typename GraphT::EdgeIdentifier EI;
// Test Fixture
template <typename T> class GraphTest : public testing::Test {
protected:
T Graph = getTestGraph();
private:
static T getTestGraph() {
using std::make_pair;
typename std::remove_const<T>::type G;
G.insert(make_pair(1u, VAttr({3u})));
G.insert(make_pair(2u, VAttr({5u})));
G.insert(make_pair(3u, VAttr({7u})));
G.insert(make_pair(4u, VAttr({11u})));
G.insert(make_pair(5u, VAttr({13u})));
G.insert(make_pair(6u, VAttr({17u})));
G.insert(std::make_pair(EI(1u, 2u), EAttr({3u * 5u})));
G.insert(std::make_pair(EI(2u, 3u), EAttr({5u * 7u})));
G.insert(std::make_pair(EI(6u, 3u), EAttr({2u * 7u * 17u})));
G.insert(std::make_pair(EI(4u, 6u), EAttr({11u * 17u})));
G.insert(std::make_pair(EI(2u, 4u), EAttr({5u * 11u})));
G.insert(std::make_pair(EI(2u, 5u), EAttr({5u * 13u})));
G.insert(std::make_pair(EI(4u, 5u), EAttr({11u * 13u})));
return G;
}
};
typedef ::testing::Types<GraphT, const GraphT> GraphTestTypes;
using VVT = typename GraphT::VertexValueType;
using EVT = typename GraphT::EdgeValueType;
TYPED_TEST_CASE(GraphTest, GraphTestTypes);
template <typename T> void graphVertexTester(T &G) {
std::set<unsigned> V({1u, 2u, 3u, 4u, 5u, 6u});
std::vector<unsigned> VA({0u, 3u, 5u, 7u, 11u, 13u, 17u});
EXPECT_EQ(V.size(), G.vertices().size());
EXPECT_FALSE(G.vertices().empty());
for (unsigned u : V) {
auto EVV = G.at(u);
ASSERT_TRUE(!!EVV);
EXPECT_EQ(1u, G.count(u));
EXPECT_EQ(VA[u], EVV->VA);
EXPECT_NE(G.vertices().end(),
std::find_if(G.vertices().begin(), G.vertices().end(),
[&](const VVT &VV) { return VV.first == u; }));
consumeError(EVV.takeError());
}
for (auto &VVT : G.vertices()) {
EXPECT_EQ(1u, V.count(VVT.first));
EXPECT_EQ(VA[VVT.first], VVT.second.VA);
}
}
template <typename T> void graphEdgeTester(T &G) {
std::set<unsigned> V({1u, 2u, 3u, 4u, 5u, 6u});
std::set<std::pair<unsigned, unsigned>> E(
{{1u, 2u}, {2u, 3u}, {6u, 3u}, {4u, 6u}, {2u, 4u}, {2u, 5u}, {4u, 5u}});
std::vector<unsigned> VA({0u, 3u, 5u, 7u, 11u, 13u, 17u});
EXPECT_EQ(E.size(), G.edges().size());
EXPECT_FALSE(G.edges().empty());
for (std::pair<unsigned, unsigned> u : E) {
auto EEV = G.at(u);
ASSERT_TRUE(!!EEV);
EXPECT_EQ(1u, G.count(u));
EXPECT_EQ(VA[u.first] * VA[u.second] * ((u.first > u.second) ? 2 : 1),
EEV->EA);
auto Pred = [&](const EVT &EV) { return EV.first == u; };
EXPECT_NE(G.edges().end(),
std::find_if(G.edges().begin(), G.edges().end(), Pred));
consumeError(EEV.takeError());
}
for (auto &EV : G.edges()) {
EXPECT_EQ(1u, E.count(EV.first));
EXPECT_EQ(VA[EV.first.first] * VA[EV.first.second] *
((EV.first.first > EV.first.second) ? 2 : 1),
EV.second.EA);
const auto &IE = G.inEdges(EV.first.second);
const auto &OE = G.outEdges(EV.first.first);
EXPECT_NE(IE.size(), 0u);
EXPECT_NE(OE.size(), 0u);
EXPECT_NE(IE.begin(), IE.end());
EXPECT_NE(OE.begin(), OE.end());
{
auto It = std::find_if(
G.inEdges(EV.first.second).begin(), G.inEdges(EV.first.second).end(),
[&](const EVT &EVI) { return EVI.first == EV.first; });
EXPECT_NE(G.inEdges(EV.first.second).end(), It);
}
{
auto It = std::find_if(
G.inEdges(EV.first.first).begin(), G.inEdges(EV.first.first).end(),
[&](const EVT &EVI) { return EVI.first == EV.first; });
EXPECT_EQ(G.inEdges(EV.first.first).end(), It);
}
{
auto It =
std::find_if(G.outEdges(EV.first.second).begin(),
G.outEdges(EV.first.second).end(),
[&](const EVT &EVI) { return EVI.first == EV.first; });
EXPECT_EQ(G.outEdges(EV.first.second).end(), It);
}
{
auto It = std::find_if(
G.outEdges(EV.first.first).begin(), G.outEdges(EV.first.first).end(),
[&](const EVT &EVI) { return EVI.first == EV.first; });
EXPECT_NE(G.outEdges(EV.first.first).end(), It);
}
}
}
TYPED_TEST(GraphTest, TestGraphEdge) {
auto &G = this->Graph;
graphEdgeTester(G);
}
TYPED_TEST(GraphTest, TestGraphVertex) {
auto &G = this->Graph;
graphVertexTester(G);
}
TYPED_TEST(GraphTest, TestCopyConstructor) {
TypeParam G(this->Graph);
graphEdgeTester(G);
graphVertexTester(G);
}
TYPED_TEST(GraphTest, TestCopyAssign) {
TypeParam G = this->Graph;
graphEdgeTester(G);
graphVertexTester(G);
}
TYPED_TEST(GraphTest, TestMoveConstructor) {
TypeParam G(std::move(this->Graph));
graphEdgeTester(G);
graphVertexTester(G);
}
// Tests the incremental Construction of a graph
TEST(GraphTest, TestConstruction) {
GraphT MG;
const GraphT &G = MG;
EXPECT_EQ(0u, G.count(0u));
EXPECT_EQ(0u, G.count({0u, 1u}));
auto VE = G.at(0);
auto EE = G.at({0, 0});
EXPECT_FALSE(VE); // G.at[0] returns an error
EXPECT_FALSE(EE); // G.at[{0,0}] returns an error
consumeError(VE.takeError());
consumeError(EE.takeError());
EXPECT_TRUE(G.vertices().empty());
EXPECT_TRUE(G.edges().empty());
EXPECT_EQ(G.vertices().begin(), G.vertices().end());
EXPECT_EQ(G.edges().begin(), G.edges().end());
}
TEST(GraphTest, TestiVertexAccessOperator) {
GraphT MG;
const GraphT &G = MG;
MG[0u] = {1u};
EXPECT_EQ(1u, MG[0u].VA);
EXPECT_EQ(1u, G.count(0u));
EXPECT_EQ(0u, G.count(1u));
EXPECT_EQ(1u, MG[0u].VA);
auto T = G.at(0u);
EXPECT_TRUE(!!T);
EXPECT_EQ(1u, T->VA);
EXPECT_EQ(1u, G.vertices().size());
EXPECT_EQ(0u, G.edges().size());
EXPECT_FALSE(G.vertices().empty());
EXPECT_TRUE(G.edges().empty());
EXPECT_NE(G.vertices().begin(), G.vertices().end());
EXPECT_EQ(G.edges().begin(), G.edges().end());
EXPECT_EQ(1u, G.vertices().begin()->second.VA);
EXPECT_EQ(0u, G.vertices().begin()->first);
EXPECT_EQ(0u, G.outEdges(0u).size());
EXPECT_TRUE(G.outEdges(0u).empty());
EXPECT_EQ(G.outEdges(0u).begin(), G.outEdges(0u).end());
EXPECT_EQ(0u, G.inEdges(0u).size());
EXPECT_TRUE(G.inEdges(0u).empty());
EXPECT_EQ(G.inEdges(0u).begin(), G.inEdges(0u).end());
}
TEST(GraphTest, TestEdgeAccessOperator) {
GraphT MG;
const GraphT &G = MG;
MG[{0u, 0u}] = {2u};
EI EdgeIdent({0u, 0u});
EXPECT_EQ(2u, MG[EdgeIdent].EA);
EXPECT_EQ(1u, G.count({0u, 0u}));
EXPECT_EQ(0u, G.count({0u, 1u}));
EXPECT_EQ(1u, G.count(0u));
EXPECT_NE(1u, G.count(1u));
auto T = G.at({0u, 0u});
EXPECT_TRUE(T && T->EA == 2u);
EXPECT_EQ(1u, G.edges().size());
EXPECT_EQ(1u, G.vertices().size());
EXPECT_FALSE(G.edges().empty());
EXPECT_FALSE(G.vertices().empty());
EXPECT_NE(G.edges().begin(), G.edges().end());
EXPECT_EQ(EI(0u, 0u), G.edges().begin()->first);
EXPECT_EQ(2u, G.edges().begin()->second.EA);
EXPECT_EQ(1u, G.outEdges(0u).size());
EXPECT_FALSE(G.outEdges(0u).empty());
EXPECT_NE(G.outEdges(0u).begin(), G.outEdges(0u).end());
EXPECT_EQ(EI(0u, 0u), G.outEdges(0u).begin()->first);
EXPECT_EQ(2u, G.outEdges(0u).begin()->second.EA);
EXPECT_EQ(++(G.outEdges(0u).begin()), G.outEdges(0u).end());
EXPECT_EQ(1u, G.inEdges(0u).size());
EXPECT_FALSE(G.inEdges(0u).empty());
EXPECT_NE(G.inEdges(0u).begin(), G.inEdges(0u).end());
EXPECT_EQ(EI(0u, 0u), G.inEdges(0u).begin()->first);
EXPECT_EQ(2u, G.inEdges(0u).begin()->second.EA);
EXPECT_EQ(++(G.inEdges(0u).begin()), G.inEdges(0u).end());
}
}