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fuchsia / fuchsia / c46e161d2d61e35b4d90ed962fa02839309831bb / . / tools / fidlcat / lib / comparator_test.cc
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// Copyright 2019 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "tools/fidlcat/lib/comparator.h"
#include <array>
#include <fstream>
#include <string>
#include <gtest/gtest.h>
#include "tools/fidlcat/lib/message_graph.h"
namespace fidlcat {
class TestComparator : public Comparator {
public:
TestComparator(std::string_view expected_output) : Comparator(os_) {
ParseGolden(expected_output);
}
TestComparator() : Comparator(os_) {}
std::shared_ptr<GoldenMessageNode> InsertMessage(std::string process_name, uint64_t pid,
uint64_t tid, std::string_view cur_msg) {
return golden_message_graph_.InsertMessage(process_name, pid, tid, cur_msg);
}
std::shared_ptr<GoldenMessageNode> UniqueMatchToGoldenTest(
std::shared_ptr<ActualMessageNode> actual_message_node) {
return UniqueMatchToGolden(actual_message_node);
}
bool PropagateMatchTest(std::shared_ptr<ActualNode> actual_node,
std::shared_ptr<GoldenNode> golden_node) {
return PropagateMatch(actual_node, golden_node, false);
}
bool ReversePropagateMatchTest(std::shared_ptr<ActualNode> actual_node) {
return ReversePropagateMatch(actual_node);
}
std::string output_string() {
std::string res = os_.str();
os_.clear();
os_.str("");
return res;
}
// We use a null terminated string for easy use in ASSERT_EQ.
std::string GetMessageAsStr(std::string_view messages, size_t* number_char_processed) {
return std::string(GetMessage(messages, number_char_processed));
}
const GoldenMessageGraph& golden_message_graph() { return golden_message_graph_; }
private:
std::ostringstream os_;
};
// Test checking that GetMessage works: it returns one syscall input or output per call.
TEST(Comparator, GetMessage) {
std::string messages = R"(
Launched run fuchsia-pkg
echo_client 28777:28779 zx_channel_create(options:uint32: 0)
-> ZX_OK (out0:handle: 6d3e0273, out1:handle: 6c2e0347)
echo_client 287283:287285 zx_channel_write(handle:handle: b84b2b47, options:uint32: 0)
sent request fuchsia.sys/Launcher.CreateComponent = {
launch_info: fuchsia.sys/LaunchInfo = {
flat_namespace: fuchsia.sys/FlatNamespace = null
additional_services: fuchsia.sys/ServiceList = null
}
controller: handle = b6bb28d3
}
josh 30539:30541 zx_channel_call(handle:handle: e1d252ab, options:uint32: 0)
sent request fuchsia.io/File.Write = { data: vector<uint8> = [
] }
-> ZX_OK
received response fuchsia.io/File.Read = {
s: int32 = 0
data: vector<uint8> = [
// Copyright 2019 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
/**
* @fileoverview Utilities for printing objects nicely.
*/
]
}
)";
std::string message1 = "echo_client 28777:28779 zx_channel_create(options:uint32: 0)\n";
std::string message2 = " -> ZX_OK (out0:handle: 6d3e0273, out1:handle: 6c2e0347)\n";
std::string message3 =
R"(echo_client 287283:287285 zx_channel_write(handle:handle: b84b2b47, options:uint32: 0)
sent request fuchsia.sys/Launcher.CreateComponent = {
launch_info: fuchsia.sys/LaunchInfo = {
flat_namespace: fuchsia.sys/FlatNamespace = null
additional_services: fuchsia.sys/ServiceList = null
}
controller: handle = b6bb28d3
}
)";
std::string message4 =
R"(josh 30539:30541 zx_channel_call(handle:handle: e1d252ab, options:uint32: 0)
sent request fuchsia.io/File.Write = { data: vector<uint8> = [
] }
)";
std::string message5 =
R"( -> ZX_OK
received response fuchsia.io/File.Read = {
s: int32 = 0
data: vector<uint8> = [
// Copyright 2019 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
/**
* @fileoverview Utilities for printing objects nicely.
*/
]
}
)";
TestComparator comparator("");
size_t number_char_processed = 0;
ASSERT_EQ(comparator.GetMessageAsStr(messages, &number_char_processed), message1);
ASSERT_EQ(number_char_processed, messages.find(message1) + message1.length());
messages = messages.substr(number_char_processed);
ASSERT_EQ(comparator.GetMessageAsStr(messages, &number_char_processed), message2);
ASSERT_EQ(number_char_processed, message2.length());
messages = messages.substr(number_char_processed);
ASSERT_EQ(comparator.GetMessageAsStr(messages, &number_char_processed), message3);
// + 1 for the ignored \n before message 3
ASSERT_EQ(number_char_processed, message3.length() + 1);
messages = messages.substr(number_char_processed);
ASSERT_EQ(comparator.GetMessageAsStr(messages, &number_char_processed), message4);
// + 1 for the ignored \n before message 4
ASSERT_EQ(number_char_processed, message4.length() + 1);
messages = messages.substr(number_char_processed);
ASSERT_EQ(comparator.GetMessageAsStr(messages, &number_char_processed), message5);
ASSERT_EQ(number_char_processed, message5.length());
}
// Checks that the golden graph construction is correct, even for interleaved syscalls, or syscalls
// without a return.
TEST(Comparator, ParseGolden) {
std::string messages = R"(
Launched run fuchsia-pkg
echo_client 1:1 zx_process_exit(retcode:uint64: 0)
echo_client 1:1 zx_channel_create(options:uint32: 0)
echo_client 1:2 zx_channel_write(handle:handle: a1, options:uint32: 0)
sent request fuchsia.io/Directory.Open = {
flags: uint32 = 3
mode: uint32 = 493
path: string = "fuchsia.sys.Launcher"
object: handle = a2
}
-> ZX_OK
echo_client 1:1 -> ZX_OK (out0:handle: a1, out1:handle: a2)
)";
std::string message1 = "zx_process_exit(retcode:uint64: 0)\n";
std::string message2 = "zx_channel_create(options:uint32: 0)\n";
std::string message3 =
R"(zx_channel_write(handle:handle: 0, options:uint32: 0)
sent request fuchsia.io/Directory.Open = {
flags: uint32 = 3
mode: uint32 = 493
path: string = "fuchsia.sys.Launcher"
object: handle = 1
}
)";
std::string message4 = " -> ZX_OK\n";
std::string message5 = " -> ZX_OK (out0:handle: 0, out1:handle: 1)\n";
TestComparator comparator(messages);
GoldenMessageGraph golden_message_graph = comparator.golden_message_graph();
// Check tid to pid dependencies.
auto tid_node1 = golden_message_graph.get_tid_node(1);
auto tid_node2 = golden_message_graph.get_tid_node(2);
auto pid_node1 = golden_message_graph.get_pid_node(1);
ASSERT_EQ(tid_node1->get_dependency_by_type(DependencyType(kTidNode, kPidNode)), pid_node1);
ASSERT_EQ(tid_node2->get_dependency_by_type(DependencyType(kTidNode, kPidNode)), pid_node1);
// Check dependencies for messages.
auto message_nodes = golden_message_graph.message_nodes();
// message1
auto message_node1 = message_nodes[message1][0];
ASSERT_EQ(message_node1->get_dependency_by_type(DependencyType(kMessageNode, kTidNode)),
tid_node1);
// message2
auto message_node2 = message_nodes[message2][0];
ASSERT_EQ(message_node2->get_dependency_by_type(DependencyType(kMessageNode, kTidNode)),
tid_node1);
// message 3
auto message_node3 = message_nodes[message3][0];
auto handle_nodea1 = golden_message_graph.get_handle_node(0xa1);
auto handle_nodea2 = golden_message_graph.get_handle_node(0xa2);
ASSERT_EQ(message_node3->get_dependency_by_type(DependencyType(kZxWriteMessageNode, kTidNode)),
tid_node2);
ASSERT_EQ(
message_node3->get_dependency_by_type(DependencyType(kZxWriteMessageNode, kHandleNode + 0)),
handle_nodea1);
ASSERT_EQ(
message_node3->get_dependency_by_type(DependencyType(kZxWriteMessageNode, kHandleNode + 1)),
handle_nodea2);
// message 4
auto message_node4 = message_nodes[message4][0];
ASSERT_EQ(message_node4->get_dependency_by_type(DependencyType(kMessageNode, kTidNode)),
tid_node2);
ASSERT_EQ(message_node4->get_dependency_by_type(DependencyType(kMessageNode, kMessageInputNode)),
message_node3);
// message 5
auto message_node5 = message_nodes[message5][0];
ASSERT_EQ(message_node5->get_dependency_by_type(DependencyType(kMessageNode, kTidNode)),
tid_node1);
ASSERT_EQ(message_node5->get_dependency_by_type(DependencyType(kMessageNode, kMessageInputNode)),
message_node2);
ASSERT_EQ(message_node5->get_dependency_by_type(DependencyType(kMessageNode, kHandleNode + 0)),
handle_nodea1);
ASSERT_EQ(message_node5->get_dependency_by_type(DependencyType(kMessageNode, kHandleNode + 1)),
handle_nodea2);
}
TEST(Comparator, UniqueMatchToGolden) {
std::string messages = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
-> ZX_OK (out0:handle: 111a, out1:handle: 111b)
echo_client 2:21 zx_channel_write(handle:handle: 221a, options:uint32: 0)
echo_client 1:12 zx_channel_write(handle:handle: 112a, options:uint32: 0)
echo_client 2:21 -> ZX_OK (out0:handle: 221b, out1:handle: 221c)
)";
TestComparator comparator(messages);
std::string message1 = "zx_channel_create(options:uint32: 0)\n";
ActualMessageGraph message_graph1;
auto message_node1 = message_graph1.InsertMessage("echo_client", 1, 1, message1);
ASSERT_TRUE(comparator.UniqueMatchToGoldenTest(message_node1));
std::string message2 = "zx_channel_write(handle:handle: 6, options:uint32: 0)\n";
ActualMessageGraph message_graph2;
auto message_node2 = message_graph2.InsertMessage("echo_client", 1, 1, message2);
ASSERT_FALSE(comparator.UniqueMatchToGoldenTest(message_node2));
std::string message3 = "zx_channel_read(handle:handle: 6, options:uint32: 0)\n";
ActualMessageGraph message_graph3;
auto message_node3 = message_graph3.InsertMessage("echo_client", 1, 1, message3);
ASSERT_FALSE(comparator.UniqueMatchToGoldenTest(message_node3));
}
TEST(Comparator, PropagateMatch) {
// A propagation that should work
std::string golden_message1 = "echo_client 1:11 zx_channel_create(options:uint32: 0)\n";
TestComparator comparator1(golden_message1);
std::string message1 = "zx_channel_create(options:uint32: 0)\n";
ActualMessageGraph message_graph1;
auto message_node1 = message_graph1.InsertMessage("echo_client", 2, 22, message1);
auto matching_golden1 = comparator1.UniqueMatchToGoldenTest(message_node1);
ASSERT_TRUE(matching_golden1);
ASSERT_TRUE(comparator1.PropagateMatchTest(message_node1, matching_golden1));
auto golden_tid = comparator1.golden_message_graph().get_tid_node(11);
auto actual_tid = message_graph1.get_tid_node(22);
ASSERT_EQ(actual_tid->matching_golden_node(), golden_tid);
auto golden_pid = comparator1.golden_message_graph().get_pid_node(1);
auto actual_pid = message_graph1.get_pid_node(2);
ASSERT_EQ(actual_pid->matching_golden_node(), golden_pid);
std::string golden_message2 = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
-> ZX_OK (out0:handle: 111a, out1:handle: 111b)
echo_client 1:21 zx_channel_write(handle:handle: 221a, options:uint32: 0)
)";
TestComparator comparator2(golden_message2);
std::string message2a = "zx_channel_create(options:uint32: 0)\n";
ActualMessageGraph message_graph2;
auto message_node2a = message_graph2.InsertMessage("echo_client", 2, 22, message2a);
auto matching_golden2a = comparator2.UniqueMatchToGoldenTest(message_node2a);
ASSERT_TRUE(matching_golden2a);
ASSERT_TRUE(comparator2.PropagateMatchTest(message_node2a, matching_golden2a));
std::string message2b = " -> ZX_OK (out0:handle: 111a, out1:handle: 111b)\n";
auto message_node2b =
message_graph2.InsertMessage("echo_client", 2, 22, message2b, message_node2a);
auto matching_golden2b = comparator2.UniqueMatchToGoldenTest(message_node2b);
ASSERT_TRUE(matching_golden2b);
ASSERT_TRUE(comparator2.PropagateMatchTest(message_node2b, matching_golden2b));
std::string message2c = "zx_channel_write(handle:handle: 221a, options:uint32: 0)\n";
auto message_node2c = message_graph2.InsertMessage("echo_client", 2, 22, message2c);
auto matching_golden2c = comparator2.UniqueMatchToGoldenTest(message_node2c);
ASSERT_TRUE(matching_golden2c);
ASSERT_FALSE(comparator2.PropagateMatchTest(message_node2c, matching_golden2c));
}
TEST(Comparator, ReversePropagateMatch) {
// A reverse propagation that should work
std::string golden_message1 = "echo_client 1:11 zx_channel_create(options:uint32: 0)\n";
TestComparator comparator1(golden_message1);
std::string message1 = "zx_channel_create(options:uint32: 0)\n";
ActualMessageGraph message_graph1;
auto message_node1 = message_graph1.InsertMessage("echo_client", 2, 22, message1);
auto actual_pid = message_graph1.get_pid_node(2);
auto golden_pid = comparator1.golden_message_graph().get_pid_node(1);
actual_pid->set_matching_golden_node(golden_pid);
ASSERT_TRUE(comparator1.ReversePropagateMatchTest(actual_pid));
auto golden_tid = comparator1.golden_message_graph().get_tid_node(11);
auto actual_tid = message_graph1.get_tid_node(22);
ASSERT_EQ(actual_tid->matching_golden_node(), golden_tid);
ASSERT_TRUE(message_node1->matching_golden_node());
std::string golden_message2 = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
-> ZX_OK (out0:handle: 111a, out1:handle: 111b)
)";
TestComparator comparator2(golden_message2);
std::string message2 = "zx_channel_create(options:uint32: 0)\n";
ActualMessageGraph message_graph2;
auto message_node2 = message_graph2.InsertMessage("echo_client", 2, 22, message2);
actual_pid = message_graph2.get_pid_node(2);
golden_pid = comparator2.golden_message_graph().get_pid_node(1);
actual_pid->set_matching_golden_node(golden_pid);
ASSERT_FALSE(comparator1.ReversePropagateMatchTest(actual_pid));
}
TEST(Comparator, CompareInputOutput) {
std::string messages = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
-> ZX_OK (out0:handle: 6d3e0273, out1:handle: 6c2e0347)
echo_client 1:12 zx_channel_write(handle:handle: 6d1e0003, options:uint32: 0)
)";
fidlcat::TestComparator comparator(messages);
std::string process_name = "echo_client";
std::string input_1 = "echo_client 2:21 zx_channel_create(options:uint32: 0)\n";
comparator.CompareInput(input_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
std::string output_1 = " -> ZX_OK (out0:handle: 6d3e0273, out1:handle: 6c2e0347)\n";
comparator.CompareOutput(output_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
std::string input_2 =
"echo_client 2:21 zx_channel_write(handle:handle: 6d1e0003, options:uint32: 0)\n";
comparator.CompareInput(input_2, process_name, 2, 21);
ASSERT_EQ(
"Conflicting matches for actual tid node: 21 matched to golden tid node: 12 and golden "
"tid node: 11 \n",
comparator.output_string());
}
TEST(Comparator, CompareUnmatchedGoldenMessages) {
std::string messages = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
-> ZX_OK (out0:handle: 6d3e0273, out1:handle: 6c2e0347)
echo_client 2:12 zx_channel_write(handle:handle: 6d1e0003, options:uint32: 0)
)";
fidlcat::TestComparator comparator(messages);
std::string process_name = "echo_client";
std::string input_1 = "echo_client 2:21 zx_channel_create(options:uint32: 0)\n";
comparator.CompareInput(input_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
std::string output_1 = " -> ZX_OK (out0:handle: 6d3e0273, out1:handle: 6c2e0347)\n";
comparator.CompareOutput(output_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
comparator.FinishComparison();
ASSERT_EQ("Unmatched golden message zx_channel_write(handle:handle: 0, options:uint32: 0)\n",
comparator.output_string());
}
TEST(Comparator, CompareUnmatchedActualMessages) {
std::string messages = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
echo_client 1:11 zx_channel_create(options:uint32: 0)
)";
fidlcat::TestComparator comparator(messages);
std::string process_name = "echo_client";
std::string input_1 = "echo_client 2:21 zx_channel_create(options:uint32: 0)\n";
comparator.CompareInput(input_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
std::string input_2 = "echo_client 2:21 zx_channel_create(options:uint32: 0)\n";
comparator.CompareInput(input_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
comparator.FinishComparison();
ASSERT_EQ(
"Unmatched actual message zx_channel_create(options:uint32: 0)\n"
"Unmatched actual message zx_channel_create(options:uint32: 0)\n"
"Unmatched golden message zx_channel_create(options:uint32: 0)\n"
"Unmatched golden message zx_channel_create(options:uint32: 0)\n",
comparator.output_string());
}
TEST(Comparator, MultipleActualMessagesForSameGolden) {
std::string messages = R"(
echo_client 1:11 zx_channel_create(options:uint32: 0)
)";
fidlcat::TestComparator comparator(messages);
std::string process_name = "echo_client";
std::string input_1 = "echo_client 2:21 zx_channel_create(options:uint32: 0)\n";
comparator.CompareInput(input_1, process_name, 2, 21);
ASSERT_EQ("", comparator.output_string());
std::string input_2 = "echo_client 2:21 zx_channel_create(options:uint32: 0)\n";
comparator.CompareInput(input_1, process_name, 2, 21);
ASSERT_EQ(" golden message node: zx_channel_create(options:uint32: 0)\n was matched twice.\n",
comparator.output_string());
}
} // namespace fidlcat