blob: 28699c45480f716cf744256a5364149c9f91c92e [file] [log] [blame]
// Copyright 2016 The Chromium 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 "net/socket/socket_bio_adapter.h"
#include <string.h>
#include <memory>
#include "base/containers/span.h"
#include "base/location.h"
#include "base/logging.h"
#include "base/macros.h"
#include "base/run_loop.h"
#include "base/test/scoped_feature_list.h"
#include "crypto/openssl_util.h"
#include "net/base/address_list.h"
#include "net/base/completion_once_callback.h"
#include "net/base/net_errors.h"
#include "net/log/net_log_source.h"
#include "net/socket/socket_test_util.h"
#include "net/socket/stream_socket.h"
#include "net/ssl/openssl_ssl_util.h"
#include "net/test/test_with_scoped_task_environment.h"
#include "starboard/memory.h"
#include "starboard/types.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "third_party/boringssl/src/include/openssl/bio.h"
#include "third_party/boringssl/src/include/openssl/err.h"
#include "third_party/boringssl/src/include/openssl/ssl.h"
namespace net {
enum ReadIfReadySupport {
// ReadIfReady() field trial is enabled, and ReadyIfReady() is implemented.
READ_IF_READY_ENABLED_SUPPORTED,
// ReadIfReady() field trial is enabled, but ReadyIfReady() is unimplemented.
READ_IF_READY_ENABLED_NOT_SUPPORTED,
// ReadIfReady() field trial is disabled.
READ_IF_READY_DISABLED,
};
class SocketBIOAdapterTest : public testing::TestWithParam<ReadIfReadySupport>,
public SocketBIOAdapter::Delegate,
public WithScopedTaskEnvironment {
protected:
void SetUp() override {
if (GetParam() == READ_IF_READY_DISABLED) {
scoped_feature_list_.InitAndDisableFeature(
Socket::kReadIfReadyExperiment);
} else if (GetParam() == READ_IF_READY_ENABLED_SUPPORTED) {
factory_.set_enable_read_if_ready(true);
}
}
std::unique_ptr<StreamSocket> MakeTestSocket(SocketDataProvider* data) {
data->set_connect_data(MockConnect(SYNCHRONOUS, OK));
factory_.AddSocketDataProvider(data);
std::unique_ptr<StreamSocket> socket = factory_.CreateTransportClientSocket(
AddressList(), nullptr, nullptr, NetLogSource());
CHECK_EQ(OK, socket->Connect(CompletionOnceCallback()));
return socket;
}
void set_reset_on_write_ready(
std::unique_ptr<SocketBIOAdapter>* reset_on_write_ready) {
reset_on_write_ready_ = reset_on_write_ready;
}
void ExpectReadError(BIO* bio,
int error,
const crypto::OpenSSLErrStackTracer& tracer) {
// BIO_read should fail.
char buf;
EXPECT_EQ(-1, BIO_read(bio, &buf, 1));
EXPECT_EQ(error, MapOpenSSLError(SSL_ERROR_SSL, tracer));
EXPECT_FALSE(BIO_should_read(bio));
// Repeating the operation should replay the error.
EXPECT_EQ(-1, BIO_read(bio, &buf, 1));
EXPECT_EQ(error, MapOpenSSLError(SSL_ERROR_SSL, tracer));
EXPECT_FALSE(BIO_should_read(bio));
}
void ExpectBlockingRead(BIO* bio, void* buf, int len) {
// BIO_read should return a retryable error.
EXPECT_EQ(-1, BIO_read(bio, buf, len));
EXPECT_TRUE(BIO_should_read(bio));
EXPECT_EQ(0u, ERR_peek_error());
// Repeating the operation has the same result.
EXPECT_EQ(-1, BIO_read(bio, buf, len));
EXPECT_TRUE(BIO_should_read(bio));
EXPECT_EQ(0u, ERR_peek_error());
}
void ExpectWriteError(BIO* bio,
int error,
const crypto::OpenSSLErrStackTracer& tracer) {
// BIO_write should fail.
char buf = '?';
EXPECT_EQ(-1, BIO_write(bio, &buf, 1));
EXPECT_EQ(error, MapOpenSSLError(SSL_ERROR_SSL, tracer));
EXPECT_FALSE(BIO_should_write(bio));
// Repeating the operation should replay the error.
EXPECT_EQ(-1, BIO_write(bio, &buf, 1));
EXPECT_EQ(error, MapOpenSSLError(SSL_ERROR_SSL, tracer));
EXPECT_FALSE(BIO_should_write(bio));
}
void ExpectBlockingWrite(BIO* bio, const void* buf, int len) {
// BIO_write should return a retryable error.
EXPECT_EQ(-1, BIO_write(bio, buf, len));
EXPECT_TRUE(BIO_should_write(bio));
EXPECT_EQ(0u, ERR_peek_error());
// Repeating the operation has the same result.
EXPECT_EQ(-1, BIO_write(bio, buf, len));
EXPECT_TRUE(BIO_should_write(bio));
EXPECT_EQ(0u, ERR_peek_error());
}
void WaitForReadReady() {
expect_read_ready_ = true;
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(expect_read_ready_);
}
void WaitForWriteReady(SequencedSocketData* to_resume) {
expect_write_ready_ = true;
if (to_resume) {
to_resume->Resume();
}
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(expect_write_ready_);
}
void WaitForBothReady() {
expect_read_ready_ = true;
expect_write_ready_ = true;
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(expect_read_ready_);
EXPECT_FALSE(expect_write_ready_);
}
// SocketBIOAdapter::Delegate implementation:
void OnReadReady() override {
EXPECT_TRUE(expect_read_ready_);
expect_read_ready_ = false;
}
void OnWriteReady() override {
EXPECT_TRUE(expect_write_ready_);
expect_write_ready_ = false;
if (reset_on_write_ready_)
reset_on_write_ready_->reset();
}
private:
bool expect_read_ready_ = false;
bool expect_write_ready_ = false;
MockClientSocketFactory factory_;
std::unique_ptr<SocketBIOAdapter>* reset_on_write_ready_ = nullptr;
base::test::ScopedFeatureList scoped_feature_list_;
};
INSTANTIATE_TEST_CASE_P(/* no prefix */,
SocketBIOAdapterTest,
testing::Values(READ_IF_READY_ENABLED_SUPPORTED,
READ_IF_READY_ENABLED_NOT_SUPPORTED,
READ_IF_READY_DISABLED));
// Test that data can be read synchronously.
TEST_P(SocketBIOAdapterTest, ReadSync) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(SYNCHRONOUS, 0, "hello"), MockRead(SYNCHRONOUS, 1, "world"),
MockRead(SYNCHRONOUS, ERR_CONNECTION_RESET, 2),
};
SequencedSocketData data(reads, base::span<MockWrite>());
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
BIO* bio = adapter->bio();
EXPECT_FALSE(adapter->HasPendingReadData());
// Read the data synchronously. Although the buffer has room for both,
// BIO_read only reports one socket-level Read.
char buf[10];
EXPECT_EQ(5, BIO_read(bio, buf, sizeof(buf)));
EXPECT_EQ(0, memcmp("hello", buf, 5));
EXPECT_FALSE(adapter->HasPendingReadData());
// Consume the next portion one byte at a time.
EXPECT_EQ(1, BIO_read(bio, buf, 1));
EXPECT_EQ('w', buf[0]);
EXPECT_TRUE(adapter->HasPendingReadData());
EXPECT_EQ(1, BIO_read(bio, buf, 1));
EXPECT_EQ('o', buf[0]);
EXPECT_TRUE(adapter->HasPendingReadData());
// The remainder may be consumed in a single BIO_read.
EXPECT_EQ(3, BIO_read(bio, buf, sizeof(buf)));
EXPECT_EQ(0, memcmp("rld", buf, 3));
EXPECT_FALSE(adapter->HasPendingReadData());
// The error is available synchoronously.
ExpectReadError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that data can be read asynchronously.
TEST_P(SocketBIOAdapterTest, ReadAsync) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(ASYNC, 0, "hello"), MockRead(ASYNC, 1, "world"),
MockRead(ASYNC, ERR_CONNECTION_RESET, 2),
};
SequencedSocketData data(reads, base::span<MockWrite>());
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
BIO* bio = adapter->bio();
EXPECT_FALSE(adapter->HasPendingReadData());
// Attempt to read data. It will fail but schedule a Read.
char buf[10];
ExpectBlockingRead(bio, buf, sizeof(buf));
EXPECT_FALSE(adapter->HasPendingReadData());
// After waiting, the data is available if Read() is used.
WaitForReadReady();
if (GetParam() == READ_IF_READY_ENABLED_SUPPORTED) {
EXPECT_FALSE(adapter->HasPendingReadData());
} else {
EXPECT_TRUE(adapter->HasPendingReadData());
}
// The first read is now available synchronously.
EXPECT_EQ(5, BIO_read(bio, buf, sizeof(buf)));
EXPECT_EQ(0, memcmp("hello", buf, 5));
EXPECT_FALSE(adapter->HasPendingReadData());
// The adapter does not schedule another Read until BIO_read is next called.
base::RunLoop().RunUntilIdle();
EXPECT_FALSE(adapter->HasPendingReadData());
// This time, under-request the data. The adapter should still read the full
// amount.
ExpectBlockingRead(bio, buf, 1);
EXPECT_FALSE(adapter->HasPendingReadData());
// After waiting, the data is available if Read() is used.
WaitForReadReady();
if (GetParam() == READ_IF_READY_ENABLED_SUPPORTED) {
EXPECT_FALSE(adapter->HasPendingReadData());
} else {
EXPECT_TRUE(adapter->HasPendingReadData());
}
// The next read is now available synchronously.
EXPECT_EQ(5, BIO_read(bio, buf, sizeof(buf)));
EXPECT_EQ(0, memcmp("world", buf, 5));
EXPECT_FALSE(adapter->HasPendingReadData());
// The error is not yet available.
ExpectBlockingRead(bio, buf, sizeof(buf));
WaitForReadReady();
// The error is now available synchoronously.
ExpectReadError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that synchronous EOF is mapped to ERR_CONNECTION_CLOSED.
TEST_P(SocketBIOAdapterTest, ReadEOFSync) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(SYNCHRONOUS, 0, 0),
};
SequencedSocketData data(reads, base::span<MockWrite>());
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
ExpectReadError(adapter->bio(), ERR_CONNECTION_CLOSED, tracer);
}
// Test that asynchronous EOF is mapped to ERR_CONNECTION_CLOSED.
TEST_P(SocketBIOAdapterTest, ReadEOFAsync) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(ASYNC, 0, 0),
};
SequencedSocketData data(reads, base::span<MockWrite>());
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
char buf;
ExpectBlockingRead(adapter->bio(), &buf, 1);
WaitForReadReady();
ExpectReadError(adapter->bio(), ERR_CONNECTION_CLOSED, tracer);
}
// Test that data can be written synchronously.
TEST_P(SocketBIOAdapterTest, WriteSync) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockWrite writes[] = {
MockWrite(SYNCHRONOUS, 0, "hello"),
MockWrite(SYNCHRONOUS, 1, "wor"),
MockWrite(SYNCHRONOUS, 2, "ld"),
MockWrite(SYNCHRONOUS, 3, "helloworld"),
MockWrite(SYNCHRONOUS, ERR_CONNECTION_RESET, 4),
};
SequencedSocketData data(base::span<MockRead>(), writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 10, 10, this);
BIO* bio = adapter->bio();
// Test data entering and leaving the buffer synchronously. The second write
// takes multiple iterations (events 0 to 2).
EXPECT_EQ(5, BIO_write(bio, "hello", 5));
EXPECT_EQ(5, BIO_write(bio, "world", 5));
// If writing larger than the buffer size, only part of the data is written
// (event 3).
EXPECT_EQ(10, BIO_write(bio, "helloworldhelloworld", 20));
// Writing "aaaaa" fails (event 4), but there is a write buffer, so errors
// are delayed.
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
// However once the error is registered, subsequent writes fail.
ExpectWriteError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that data can be written asynchronously.
TEST_P(SocketBIOAdapterTest, WriteAsync) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockWrite writes[] = {
MockWrite(ASYNC, 0, "aaa"),
MockWrite(ASYNC, ERR_IO_PENDING, 1), // pause
MockWrite(ASYNC, 2, "aabbbbb"),
MockWrite(ASYNC, 3, "ccc"),
MockWrite(ASYNC, 4, "ddd"),
MockWrite(ASYNC, ERR_IO_PENDING, 5), // pause
MockWrite(ASYNC, 6, "dd"),
MockWrite(SYNCHRONOUS, 7, "e"),
MockWrite(SYNCHRONOUS, 8, "e"),
MockWrite(ASYNC, 9, "e"),
MockWrite(ASYNC, 10, "ee"),
MockWrite(ASYNC, ERR_IO_PENDING, 11), // pause
MockWrite(ASYNC, 12, "eff"),
MockWrite(ASYNC, 13, "ggggggg"),
MockWrite(ASYNC, ERR_CONNECTION_RESET, 14),
};
SequencedSocketData data(base::span<MockRead>(), writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 10, 10, this);
BIO* bio = adapter->bio();
// Data which fits in the buffer is returned synchronously, even if not
// flushed synchronously.
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
EXPECT_EQ(5, BIO_write(bio, "bbbbb", 5));
// The buffer contains:
//
// [aaaaabbbbb]
// ^
// The buffer is full now, so the next write will block.
ExpectBlockingWrite(bio, "zzzzz", 5);
// Let the first socket write complete (event 0) and pause (event 1).
WaitForWriteReady(nullptr);
EXPECT_TRUE(data.IsPaused());
// The buffer contains:
//
// [...aabbbbb]
// ^
// The ring buffer now has 3 bytes of space with "aabbbbb" still to be
// written. Attempting to write 3 bytes means 3 succeed.
EXPECT_EQ(3, BIO_write(bio, "cccccccccc", 10));
// The buffer contains:
//
// [cccaabbbbb]
// ^
// Drain the buffer (events 2 and 3).
WaitForWriteReady(&data);
// The buffer is now empty.
// Now test something similar but arrange for a BIO_write (the 'e's below) to
// wrap around the buffer. Write five bytes into the buffer, flush the first
// three (event 4), and pause (event 5). OnWriteReady is not signaled because
// the buffer was not full.
EXPECT_EQ(5, BIO_write(bio, "ddddd", 5));
base::RunLoop().RunUntilIdle();
EXPECT_TRUE(data.IsPaused());
// The buffer contains:
//
// [...dd.....]
// ^
// The adapter maintains a ring buffer, so 6 bytes fit.
EXPECT_EQ(6, BIO_write(bio, "eeeeee", 6));
// The buffer contains:
//
// [e..ddeeeee]
// ^
// The remaining space may be filled in.
EXPECT_EQ(2, BIO_write(bio, "ffffffffff", 10));
// The buffer contains:
//
// [effddeeeee]
// ^
// Drain to the end of the ring buffer, so it wraps around (events 6 to 10)
// and pause (event 11). Test that synchronous and asynchronous writes both
// drain. The start of the buffer has now wrapped around.
WaitForWriteReady(&data);
EXPECT_TRUE(data.IsPaused());
// The buffer contains:
//
// [eff.......]
// ^
// Test wrapping around works correctly and the buffer may be appended to.
EXPECT_EQ(7, BIO_write(bio, "gggggggggg", 10));
// The buffer contains:
//
// [effggggggg]
// ^
// The buffer is full now, so the next write will block.
ExpectBlockingWrite(bio, "zzzzz", 5);
// Drain the buffer to confirm the ring buffer's contents are as expected
// (events 12 and 13).
WaitForWriteReady(&data);
// Write again so the write error may be discovered.
EXPECT_EQ(5, BIO_write(bio, "hhhhh", 5));
// Release the write error (event 14). At this point future BIO_write calls
// fail. The buffer was not full, so OnWriteReady is not signalled.
base::RunLoop().RunUntilIdle();
ExpectWriteError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that a failed socket write is reported through BIO_read and prevents it
// from scheduling a socket read. See https://crbug.com/249848.
TEST_P(SocketBIOAdapterTest, WriteStopsRead) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockWrite writes[] = {
MockWrite(SYNCHRONOUS, ERR_CONNECTION_RESET, 0),
};
SequencedSocketData data(base::span<MockRead>(), writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
BIO* bio = adapter->bio();
// The write fails, but there is a write buffer, so errors are delayed.
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
// The write error is surfaced out of BIO_read. There are no MockReads, so
// this also tests that no socket reads are attempted.
ExpectReadError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that a synchronous failed socket write interrupts a blocked
// BIO_read. See https://crbug.com/249848.
TEST_P(SocketBIOAdapterTest, SyncWriteInterruptsRead) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(SYNCHRONOUS, ERR_IO_PENDING, 0),
};
MockWrite writes[] = {
MockWrite(SYNCHRONOUS, ERR_CONNECTION_RESET, 1),
};
SequencedSocketData data(reads, writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
BIO* bio = adapter->bio();
// Attempt to read from the transport. It will block indefinitely.
char buf;
ExpectBlockingRead(adapter->bio(), &buf, 1);
// Schedule a socket write.
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
// The write error triggers OnReadReady.
WaitForReadReady();
// The write error is surfaced out of BIO_read.
ExpectReadError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that an asynchronous failed socket write interrupts a blocked
// BIO_read. See https://crbug.com/249848.
TEST_P(SocketBIOAdapterTest, AsyncWriteInterruptsRead) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(SYNCHRONOUS, ERR_IO_PENDING, 0),
};
MockWrite writes[] = {
MockWrite(ASYNC, ERR_CONNECTION_RESET, 1),
};
SequencedSocketData data(reads, writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
BIO* bio = adapter->bio();
// Attempt to read from the transport. It will block indefinitely.
char buf;
ExpectBlockingRead(adapter->bio(), &buf, 1);
// Schedule a socket write.
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
// The write error is signaled asynchronously and interrupts BIO_read, so
// OnReadReady is signaled. The write buffer was not full, so OnWriteReady is
// not signaled.
WaitForReadReady();
// The write error is surfaced out of BIO_read.
ExpectReadError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that an asynchronous failed socket write interrupts a blocked BIO_read,
// signaling both if the buffer was full. See https://crbug.com/249848.
TEST_P(SocketBIOAdapterTest, AsyncWriteInterruptsBoth) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(SYNCHRONOUS, ERR_IO_PENDING, 0),
};
MockWrite writes[] = {
MockWrite(ASYNC, ERR_CONNECTION_RESET, 1),
};
SequencedSocketData data(reads, writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 5, 5, this);
BIO* bio = adapter->bio();
// Attempt to read from the transport. It will block indefinitely.
char buf;
ExpectBlockingRead(adapter->bio(), &buf, 1);
// Schedule a socket write.
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
// The write error is signaled asynchronously and interrupts BIO_read, so
// OnReadReady is signaled. The write buffer was full, so both OnWriteReady is
// also signaled.
WaitForBothReady();
// The write error is surfaced out of BIO_read.
ExpectReadError(bio, ERR_CONNECTION_RESET, tracer);
}
// Test that SocketBIOAdapter handles OnWriteReady deleting itself when both
// need to be signaled.
TEST_P(SocketBIOAdapterTest, DeleteOnWriteReady) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
MockRead reads[] = {
MockRead(SYNCHRONOUS, ERR_IO_PENDING, 0),
};
MockWrite writes[] = {
MockWrite(ASYNC, ERR_CONNECTION_RESET, 1),
};
SequencedSocketData data(reads, writes);
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 5, 5, this);
BIO* bio = adapter->bio();
// Arrange for OnReadReady and OnWriteReady to both be signaled due to write
// error propagation (see the AsyncWriteInterruptsBoth test).
char buf;
ExpectBlockingRead(adapter->bio(), &buf, 1);
EXPECT_EQ(5, BIO_write(bio, "aaaaa", 5));
// Both OnWriteReady and OnReadReady would be signaled, but OnWriteReady
// deletes the adapter first.
set_reset_on_write_ready(&adapter);
WaitForWriteReady(nullptr);
EXPECT_FALSE(adapter);
}
// Test that using a BIO after the underlying adapter is destroyed fails
// gracefully.
TEST_P(SocketBIOAdapterTest, Detached) {
crypto::OpenSSLErrStackTracer tracer(FROM_HERE);
SequencedSocketData data;
std::unique_ptr<StreamSocket> socket = MakeTestSocket(&data);
std::unique_ptr<SocketBIOAdapter> adapter =
std::make_unique<SocketBIOAdapter>(socket.get(), 100, 100, this);
// Retain an additional reference to the BIO.
bssl::UniquePtr<BIO> bio = bssl::UpRef(adapter->bio());
// Release the adapter.
adapter.reset();
ExpectReadError(bio.get(), ERR_UNEXPECTED, tracer);
ExpectWriteError(bio.get(), ERR_UNEXPECTED, tracer);
}
} // namespace net