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//===-- function_call_trie_test.cc ----------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file is a part of XRay, a function call tracing system.
//
//===----------------------------------------------------------------------===//
#include "gtest/gtest.h"
#include "xray_function_call_trie.h"
namespace __xray {
namespace {
TEST(FunctionCallTrieTest, ConstructWithTLSAllocators) {
// FIXME: Support passing in configuration for allocators in the allocator
// constructors.
profilingFlags()->setDefaults();
FunctionCallTrie::Allocators Allocators = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(Allocators);
}
TEST(FunctionCallTrieTest, EnterAndExitFunction) {
profilingFlags()->setDefaults();
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
Trie.enterFunction(1, 1);
Trie.exitFunction(1, 2);
// We need a way to pull the data out. At this point, until we get a data
// collection service implemented, we're going to export the data as a list of
// roots, and manually walk through the structure ourselves.
const auto &R = Trie.getRoots();
ASSERT_EQ(R.size(), 1u);
ASSERT_EQ(R.front()->FId, 1);
ASSERT_EQ(R.front()->CallCount, 1);
ASSERT_EQ(R.front()->CumulativeLocalTime, 1u);
}
TEST(FunctionCallTrieTest, MissingFunctionEntry) {
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
Trie.exitFunction(1, 1);
const auto &R = Trie.getRoots();
ASSERT_TRUE(R.empty());
}
TEST(FunctionCallTrieTest, NoMatchingEntersForExit) {
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
Trie.enterFunction(2, 1);
Trie.enterFunction(3, 3);
Trie.exitFunction(1, 5);
const auto &R = Trie.getRoots();
ASSERT_TRUE(R.empty());
}
TEST(FunctionCallTrieTest, MissingFunctionExit) {
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
Trie.enterFunction(1, 1);
const auto &R = Trie.getRoots();
ASSERT_TRUE(R.empty());
}
TEST(FunctionCallTrieTest, MultipleRoots) {
profilingFlags()->setDefaults();
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
// Enter and exit FId = 1.
Trie.enterFunction(1, 1);
Trie.exitFunction(1, 2);
// Enter and exit FId = 2.
Trie.enterFunction(2, 3);
Trie.exitFunction(2, 4);
const auto &R = Trie.getRoots();
ASSERT_FALSE(R.empty());
ASSERT_EQ(R.size(), 2u);
// Make sure the roots have different IDs.
const auto R0 = R[0];
const auto R1 = R[1];
ASSERT_NE(R0->FId, R1->FId);
// Inspect the roots that they have the right data.
ASSERT_NE(R0, nullptr);
EXPECT_EQ(R0->CallCount, 1u);
EXPECT_EQ(R0->CumulativeLocalTime, 1u);
ASSERT_NE(R1, nullptr);
EXPECT_EQ(R1->CallCount, 1u);
EXPECT_EQ(R1->CumulativeLocalTime, 1u);
}
// While missing an intermediary entry may be rare in practice, we still enforce
// that we can handle the case where we've missed the entry event somehow, in
// between call entry/exits. To illustrate, imagine the following shadow call
// stack:
//
// f0@t0 -> f1@t1 -> f2@t2
//
// If for whatever reason we see an exit for `f2` @ t3, followed by an exit for
// `f0` @ t4 (i.e. no `f1` exit in between) then we need to handle the case of
// accounting local time to `f2` from d = (t3 - t2), then local time to `f1`
// as d' = (t3 - t1) - d, and then local time to `f0` as d'' = (t3 - t0) - d'.
TEST(FunctionCallTrieTest, MissingIntermediaryExit) {
profilingFlags()->setDefaults();
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
Trie.enterFunction(1, 0);
Trie.enterFunction(2, 100);
Trie.enterFunction(3, 200);
Trie.exitFunction(3, 300);
Trie.exitFunction(1, 400);
// What we should see at this point is all the functions in the trie in a
// specific order (1 -> 2 -> 3) with the appropriate count(s) and local
// latencies.
const auto &R = Trie.getRoots();
ASSERT_FALSE(R.empty());
ASSERT_EQ(R.size(), 1u);
const auto &F1 = *R[0];
ASSERT_EQ(F1.FId, 1);
ASSERT_FALSE(F1.Callees.empty());
const auto &F2 = *F1.Callees[0].NodePtr;
ASSERT_EQ(F2.FId, 2);
ASSERT_FALSE(F2.Callees.empty());
const auto &F3 = *F2.Callees[0].NodePtr;
ASSERT_EQ(F3.FId, 3);
ASSERT_TRUE(F3.Callees.empty());
// Now that we've established the preconditions, we check for specific aspects
// of the nodes.
EXPECT_EQ(F3.CallCount, 1);
EXPECT_EQ(F2.CallCount, 1);
EXPECT_EQ(F1.CallCount, 1);
EXPECT_EQ(F3.CumulativeLocalTime, 100);
EXPECT_EQ(F2.CumulativeLocalTime, 300);
EXPECT_EQ(F1.CumulativeLocalTime, 100);
}
TEST(FunctionCallTrieTest, DeepCallStack) {
// Simulate a relatively deep call stack (32 levels) and ensure that we can
// properly pop all the way up the stack.
profilingFlags()->setDefaults();
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
for (int i = 0; i < 32; ++i)
Trie.enterFunction(i + 1, i);
Trie.exitFunction(1, 33);
// Here, validate that we have a 32-level deep function call path from the
// root (1) down to the leaf (33).
const auto &R = Trie.getRoots();
ASSERT_EQ(R.size(), 1u);
auto F = R[0];
for (int i = 0; i < 32; ++i) {
EXPECT_EQ(F->FId, i + 1);
EXPECT_EQ(F->CallCount, 1);
if (F->Callees.empty() && i != 31)
FAIL() << "Empty callees for FId " << F->FId;
if (i != 31)
F = F->Callees[0].NodePtr;
}
}
// TODO: Test that we can handle cross-CPU migrations, where TSCs are not
// guaranteed to be synchronised.
TEST(FunctionCallTrieTest, DeepCopy) {
profilingFlags()->setDefaults();
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie Trie(A);
Trie.enterFunction(1, 0);
Trie.enterFunction(2, 1);
Trie.exitFunction(2, 2);
Trie.enterFunction(3, 3);
Trie.exitFunction(3, 4);
Trie.exitFunction(1, 5);
// We want to make a deep copy and compare notes.
auto B = FunctionCallTrie::InitAllocators();
FunctionCallTrie Copy(B);
Trie.deepCopyInto(Copy);
ASSERT_NE(Trie.getRoots().size(), 0u);
ASSERT_EQ(Trie.getRoots().size(), Copy.getRoots().size());
const auto &R0Orig = *Trie.getRoots()[0];
const auto &R0Copy = *Copy.getRoots()[0];
EXPECT_EQ(R0Orig.FId, 1);
EXPECT_EQ(R0Orig.FId, R0Copy.FId);
ASSERT_EQ(R0Orig.Callees.size(), 2u);
ASSERT_EQ(R0Copy.Callees.size(), 2u);
const auto &F1Orig =
*R0Orig.Callees
.find_element(
[](const FunctionCallTrie::NodeIdPair &R) { return R.FId == 2; })
->NodePtr;
const auto &F1Copy =
*R0Copy.Callees
.find_element(
[](const FunctionCallTrie::NodeIdPair &R) { return R.FId == 2; })
->NodePtr;
EXPECT_EQ(&R0Orig, F1Orig.Parent);
EXPECT_EQ(&R0Copy, F1Copy.Parent);
}
TEST(FunctionCallTrieTest, MergeInto) {
profilingFlags()->setDefaults();
auto A = FunctionCallTrie::InitAllocators();
FunctionCallTrie T0(A);
FunctionCallTrie T1(A);
// 1 -> 2 -> 3
T0.enterFunction(1, 0);
T0.enterFunction(2, 1);
T0.enterFunction(3, 2);
T0.exitFunction(3, 3);
T0.exitFunction(2, 4);
T0.exitFunction(1, 5);
// 1 -> 2 -> 3
T1.enterFunction(1, 0);
T1.enterFunction(2, 1);
T1.enterFunction(3, 2);
T1.exitFunction(3, 3);
T1.exitFunction(2, 4);
T1.exitFunction(1, 5);
// We use a different allocator here to make sure that we're able to transfer
// data into a FunctionCallTrie which uses a different allocator. This
// reflects the inteded usage scenario for when we're collecting profiles that
// aggregate across threads.
auto B = FunctionCallTrie::InitAllocators();
FunctionCallTrie Merged(B);
T0.mergeInto(Merged);
T1.mergeInto(Merged);
ASSERT_EQ(Merged.getRoots().size(), 1u);
const auto &R0 = *Merged.getRoots()[0];
EXPECT_EQ(R0.FId, 1);
EXPECT_EQ(R0.CallCount, 2);
EXPECT_EQ(R0.CumulativeLocalTime, 10);
EXPECT_EQ(R0.Callees.size(), 1u);
const auto &F1 = *R0.Callees[0].NodePtr;
EXPECT_EQ(F1.FId, 2);
EXPECT_EQ(F1.CallCount, 2);
EXPECT_EQ(F1.CumulativeLocalTime, 6);
EXPECT_EQ(F1.Callees.size(), 1u);
const auto &F2 = *F1.Callees[0].NodePtr;
EXPECT_EQ(F2.FId, 3);
EXPECT_EQ(F2.CallCount, 2);
EXPECT_EQ(F2.CumulativeLocalTime, 2);
EXPECT_EQ(F2.Callees.size(), 0u);
}
} // namespace
} // namespace __xray
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