blob: 4ff84c60f3cea58b0ac8a1b0a105e1ebaf20bc16 [file] [log] [blame]
// Copyright (c) 2013 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 "chrome/test/chromedriver/util.h"
#include <stddef.h>
#include <stdint.h>
#include "base/base64.h"
#include "base/files/file_enumerator.h"
#include "base/files/file_util.h"
#include "base/files/scoped_temp_dir.h"
#include "base/format_macros.h"
#include "base/rand_util.h"
#include "base/strings/string16.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "base/third_party/icu/icu_utf.h"
#include "base/values.h"
#include "chrome/test/chromedriver/chrome/browser_info.h"
#include "chrome/test/chromedriver/chrome/chrome.h"
#include "chrome/test/chromedriver/chrome/status.h"
#include "chrome/test/chromedriver/chrome/ui_events.h"
#include "chrome/test/chromedriver/chrome/web_view.h"
#include "chrome/test/chromedriver/command_listener.h"
#include "chrome/test/chromedriver/key_converter.h"
#include "chrome/test/chromedriver/session.h"
#include "third_party/zlib/google/zip.h"
std::string GenerateId() {
uint64_t msb = base::RandUint64();
uint64_t lsb = base::RandUint64();
return base::StringPrintf("%016" PRIx64 "%016" PRIx64, msb, lsb);
}
namespace {
Status FlattenStringArray(const base::ListValue* src, base::string16* dest) {
base::string16 keys;
for (size_t i = 0; i < src->GetSize(); ++i) {
base::string16 keys_list_part;
if (!src->GetString(i, &keys_list_part))
return Status(kUnknownError, "keys should be a string");
for (size_t j = 0; j < keys_list_part.size(); ++j) {
if (CBU16_IS_SURROGATE(keys_list_part[j])) {
return Status(kUnknownError,
"ChromeDriver only supports characters in the BMP");
}
}
keys.append(keys_list_part);
}
*dest = keys;
return Status(kOk);
}
} // namespace
Status SendKeysOnWindow(
WebView* web_view,
const base::ListValue* key_list,
bool release_modifiers,
int* sticky_modifiers) {
base::string16 keys;
Status status = FlattenStringArray(key_list, &keys);
if (status.IsError())
return status;
std::list<KeyEvent> events;
int sticky_modifiers_tmp = *sticky_modifiers;
status = ConvertKeysToKeyEvents(
keys, release_modifiers, &sticky_modifiers_tmp, &events);
if (status.IsError())
return status;
status = web_view->DispatchKeyEvents(events);
if (status.IsOk())
*sticky_modifiers = sticky_modifiers_tmp;
return status;
}
bool Base64Decode(const std::string& base64,
std::string* bytes) {
std::string copy = base64;
// Some WebDriver client base64 encoders follow RFC 1521, which require that
// 'encoded lines be no more than 76 characters long'. Just remove any
// newlines.
base::RemoveChars(copy, "\n", &copy);
return base::Base64Decode(copy, bytes);
}
namespace {
Status UnzipArchive(const base::FilePath& unzip_dir,
const std::string& bytes) {
base::ScopedTempDir dir;
if (!dir.CreateUniqueTempDir())
return Status(kUnknownError, "unable to create temp dir");
base::FilePath archive = dir.GetPath().AppendASCII("temp.zip");
int length = bytes.length();
if (base::WriteFile(archive, bytes.c_str(), length) != length)
return Status(kUnknownError, "could not write file to temp dir");
if (!zip::Unzip(archive, unzip_dir))
return Status(kUnknownError, "could not unzip archive");
return Status(kOk);
}
// Stream for writing binary data.
class DataOutputStream {
public:
DataOutputStream() {}
~DataOutputStream() {}
void WriteUInt16(uint16_t data) { WriteBytes(&data, sizeof(data)); }
void WriteUInt32(uint32_t data) { WriteBytes(&data, sizeof(data)); }
void WriteString(const std::string& data) {
WriteBytes(data.c_str(), data.length());
}
void WriteBytes(const void* bytes, int size) {
if (!size)
return;
size_t next = buffer_.length();
buffer_.resize(next + size);
memcpy(&buffer_[next], bytes, size);
}
const std::string& buffer() const { return buffer_; }
private:
std::string buffer_;
};
// Stream for reading binary data.
class DataInputStream {
public:
DataInputStream(const char* data, int size)
: data_(data), size_(size), iter_(0) {}
~DataInputStream() {}
bool ReadUInt16(uint16_t* data) { return ReadBytes(data, sizeof(*data)); }
bool ReadUInt32(uint32_t* data) { return ReadBytes(data, sizeof(*data)); }
bool ReadString(std::string* data, int length) {
if (length < 0)
return false;
// Check here to make sure we don't allocate wastefully.
if (iter_ + length > size_)
return false;
data->resize(length);
if (length == 0)
return true;
return ReadBytes(&(*data)[0], length);
}
bool ReadBytes(void* bytes, int size) {
if (iter_ + size > size_)
return false;
memcpy(bytes, &data_[iter_], size);
iter_ += size;
return true;
}
int remaining() const { return size_ - iter_; }
private:
const char* data_;
int size_;
int iter_;
};
// A file entry within a zip archive. This may be incomplete and is not
// guaranteed to be able to parse all types of zip entries.
// See http://www.pkware.com/documents/casestudies/APPNOTE.TXT for the zip
// file format.
struct ZipEntry {
// The given bytes must contain the whole zip entry and only the entry,
// although the entry may include a data descriptor.
static bool FromBytes(const std::string& bytes, ZipEntry* zip,
std::string* error_msg) {
DataInputStream stream(bytes.c_str(), bytes.length());
uint32_t signature;
if (!stream.ReadUInt32(&signature) || signature != kFileHeaderSignature) {
*error_msg = "invalid file header signature";
return false;
}
if (!stream.ReadUInt16(&zip->version_needed)) {
*error_msg = "invalid version";
return false;
}
if (!stream.ReadUInt16(&zip->bit_flag)) {
*error_msg = "invalid bit flag";
return false;
}
if (!stream.ReadUInt16(&zip->compression_method)) {
*error_msg = "invalid compression method";
return false;
}
if (!stream.ReadUInt16(&zip->mod_time)) {
*error_msg = "invalid file last modified time";
return false;
}
if (!stream.ReadUInt16(&zip->mod_date)) {
*error_msg = "invalid file last modified date";
return false;
}
if (!stream.ReadUInt32(&zip->crc)) {
*error_msg = "invalid crc";
return false;
}
uint32_t compressed_size;
if (!stream.ReadUInt32(&compressed_size)) {
*error_msg = "invalid compressed size";
return false;
}
if (!stream.ReadUInt32(&zip->uncompressed_size)) {
*error_msg = "invalid compressed size";
return false;
}
uint16_t name_length;
if (!stream.ReadUInt16(&name_length)) {
*error_msg = "invalid name length";
return false;
}
uint16_t field_length;
if (!stream.ReadUInt16(&field_length)) {
*error_msg = "invalid field length";
return false;
}
if (!stream.ReadString(&zip->name, name_length)) {
*error_msg = "invalid name";
return false;
}
if (!stream.ReadString(&zip->fields, field_length)) {
*error_msg = "invalid fields";
return false;
}
if (zip->bit_flag & 0x8) {
// Has compressed data and a separate data descriptor.
if (stream.remaining() < 16) {
*error_msg = "too small for data descriptor";
return false;
}
compressed_size = stream.remaining() - 16;
if (!stream.ReadString(&zip->compressed_data, compressed_size)) {
*error_msg = "invalid compressed data before descriptor";
return false;
}
if (!stream.ReadUInt32(&signature) ||
signature != kDataDescriptorSignature) {
*error_msg = "invalid data descriptor signature";
return false;
}
if (!stream.ReadUInt32(&zip->crc)) {
*error_msg = "invalid crc";
return false;
}
if (!stream.ReadUInt32(&compressed_size)) {
*error_msg = "invalid compressed size";
return false;
}
if (compressed_size != zip->compressed_data.length()) {
*error_msg = "compressed data does not match data descriptor";
return false;
}
if (!stream.ReadUInt32(&zip->uncompressed_size)) {
*error_msg = "invalid compressed size";
return false;
}
} else {
// Just has compressed data.
if (!stream.ReadString(&zip->compressed_data, compressed_size)) {
*error_msg = "invalid compressed data";
return false;
}
if (stream.remaining() != 0) {
*error_msg = "leftover data after zip entry";
return false;
}
}
return true;
}
// Returns bytes for a valid zip file that just contains this zip entry.
std::string ToZip() {
// Write zip entry with no data descriptor.
DataOutputStream stream;
stream.WriteUInt32(kFileHeaderSignature);
stream.WriteUInt16(version_needed);
stream.WriteUInt16(bit_flag);
stream.WriteUInt16(compression_method);
stream.WriteUInt16(mod_time);
stream.WriteUInt16(mod_date);
stream.WriteUInt32(crc);
stream.WriteUInt32(compressed_data.length());
stream.WriteUInt32(uncompressed_size);
stream.WriteUInt16(name.length());
stream.WriteUInt16(fields.length());
stream.WriteString(name);
stream.WriteString(fields);
stream.WriteString(compressed_data);
uint32_t entry_size = stream.buffer().length();
// Write central directory.
stream.WriteUInt32(kCentralDirSignature);
stream.WriteUInt16(0x14); // Version made by. Unused at version 0.
stream.WriteUInt16(version_needed);
stream.WriteUInt16(bit_flag);
stream.WriteUInt16(compression_method);
stream.WriteUInt16(mod_time);
stream.WriteUInt16(mod_date);
stream.WriteUInt32(crc);
stream.WriteUInt32(compressed_data.length());
stream.WriteUInt32(uncompressed_size);
stream.WriteUInt16(name.length());
stream.WriteUInt16(fields.length());
stream.WriteUInt16(0); // Comment length.
stream.WriteUInt16(0); // Disk number where file starts.
stream.WriteUInt16(0); // Internal file attr.
stream.WriteUInt32(0); // External file attr.
stream.WriteUInt32(0); // Offset to file.
stream.WriteString(name);
stream.WriteString(fields);
uint32_t cd_size = stream.buffer().length() - entry_size;
// End of central directory.
stream.WriteUInt32(kEndOfCentralDirSignature);
stream.WriteUInt16(0); // num of this disk
stream.WriteUInt16(0); // disk where cd starts
stream.WriteUInt16(1); // number of cds on this disk
stream.WriteUInt16(1); // total cds
stream.WriteUInt32(cd_size); // size of cd
stream.WriteUInt32(entry_size); // offset of cd
stream.WriteUInt16(0); // comment len
return stream.buffer();
}
static const uint32_t kFileHeaderSignature;
static const uint32_t kDataDescriptorSignature;
static const uint32_t kCentralDirSignature;
static const uint32_t kEndOfCentralDirSignature;
uint16_t version_needed;
uint16_t bit_flag;
uint16_t compression_method;
uint16_t mod_time;
uint16_t mod_date;
uint32_t crc;
uint32_t uncompressed_size;
std::string name;
std::string fields;
std::string compressed_data;
};
const uint32_t ZipEntry::kFileHeaderSignature = 0x04034b50;
const uint32_t ZipEntry::kDataDescriptorSignature = 0x08074b50;
const uint32_t ZipEntry::kCentralDirSignature = 0x02014b50;
const uint32_t ZipEntry::kEndOfCentralDirSignature = 0x06054b50;
Status UnzipEntry(const base::FilePath& unzip_dir,
const std::string& bytes) {
ZipEntry entry;
std::string zip_error_msg;
if (!ZipEntry::FromBytes(bytes, &entry, &zip_error_msg))
return Status(kUnknownError, zip_error_msg);
std::string archive = entry.ToZip();
return UnzipArchive(unzip_dir, archive);
}
} // namespace
Status UnzipSoleFile(const base::FilePath& unzip_dir,
const std::string& bytes,
base::FilePath* file) {
std::string archive_error, entry_error;
Status status = UnzipArchive(unzip_dir, bytes);
if (status.IsError()) {
Status entry_status = UnzipEntry(unzip_dir, bytes);
if (entry_status.IsError()) {
return Status(kUnknownError, base::StringPrintf(
"archive error: (%s), entry error: (%s)",
status.message().c_str(), entry_status.message().c_str()));
}
}
base::FileEnumerator enumerator(unzip_dir, false /* recursive */,
base::FileEnumerator::FILES | base::FileEnumerator::DIRECTORIES);
base::FilePath first_file = enumerator.Next();
if (first_file.empty())
return Status(kUnknownError, "contained 0 files");
base::FilePath second_file = enumerator.Next();
if (!second_file.empty())
return Status(kUnknownError, "contained multiple files");
*file = first_file;
return Status(kOk);
}
Status NotifyCommandListenersBeforeCommand(Session* session,
const std::string& command_name) {
for (const auto& listener : session->command_listeners) {
Status status = listener->BeforeCommand(command_name);
if (status.IsError()) {
// Do not continue if an error is encountered. Mark session for deletion,
// quit Chrome if necessary, and return a detailed error.
if (!session->quit) {
session->quit = true;
std::string message = base::StringPrintf("session deleted because "
"error encountered when notifying listeners of '%s' command",
command_name.c_str());
if (session->chrome && !session->detach) {
Status quit_status = session->chrome->Quit();
if (quit_status.IsError())
message += ", but failed to kill browser:" + quit_status.message();
}
status = Status(kUnknownError, message, status);
}
if (session->chrome) {
const BrowserInfo* browser_info = session->chrome->GetBrowserInfo();
status.AddDetails("Session info: " + browser_info->browser_name + "=" +
browser_info->browser_version);
}
return status;
}
}
return Status(kOk);
}
namespace {
template <typename T>
bool GetOptionalValue(const base::DictionaryValue* dict,
base::StringPiece path,
T* out_value,
bool* has_value,
bool (base::Value::*getter)(T*) const) {
if (has_value != nullptr)
*has_value = false;
const base::Value* value;
if (!dict->Get(path, &value))
return true;
if ((value->*getter)(out_value)) {
if (has_value != nullptr)
*has_value = true;
return true;
}
return false;
}
} // namespace
bool GetOptionalBool(const base::DictionaryValue* dict,
base::StringPiece path,
bool* out_value,
bool* has_value) {
return GetOptionalValue(dict, path, out_value, has_value,
&base::Value::GetAsBoolean);
}
bool GetOptionalInt(const base::DictionaryValue* dict,
base::StringPiece path,
int* out_value,
bool* has_value) {
if (GetOptionalValue(dict, path, out_value, has_value,
&base::Value::GetAsInteger)) {
return true;
}
// See if we have a double that contains an int value.
double d;
if (!dict->GetDouble(path, &d))
return false;
int i = static_cast<int>(d);
if (i == d) {
*out_value = i;
if (has_value != nullptr)
*has_value = true;
return true;
}
return false;
}
bool GetOptionalDouble(const base::DictionaryValue* dict,
base::StringPiece path,
double* out_value,
bool* has_value) {
// base::Value::GetAsDouble already converts int to double if needed.
return GetOptionalValue(dict, path, out_value, has_value,
&base::Value::GetAsDouble);
}
bool GetOptionalString(const base::DictionaryValue* dict,
base::StringPiece path,
std::string* out_value,
bool* has_value) {
return GetOptionalValue(dict, path, out_value, has_value,
&base::Value::GetAsString);
}
bool GetOptionalSafeInt(const base::DictionaryValue* dict,
base::StringPiece path,
int64_t* out_value,
bool* has_value) {
// Check if we have a normal int, which is always a safe int.
int temp_int;
bool temp_has_value;
if (GetOptionalValue(dict, path, &temp_int, &temp_has_value,
&base::Value::GetAsInteger)) {
if (has_value != nullptr)
*has_value = temp_has_value;
if (temp_has_value)
*out_value = temp_int;
return true;
}
// Check if we have a double, which may or may not contain a safe int value.
double temp_double;
if (!dict->GetDouble(path, &temp_double))
return false;
// Verify that the value is an integer.
int64_t temp_int64 = static_cast<int64_t>(temp_double);
if (temp_int64 != temp_double)
return false;
// Verify that the value is in the range for safe integer.
if (temp_int64 >= (1ll << 53) || temp_int64 <= -(1ll << 53))
return false;
// Got a good value.
*out_value = temp_int64;
if (has_value != nullptr)
*has_value = true;
return true;
}
bool SetSafeInt(base::DictionaryValue* dict,
const base::StringPiece path,
int64_t in_value_64) {
int int_value = static_cast<int>(in_value_64);
if (in_value_64 == int_value)
return dict->SetInteger(path, in_value_64);
else
return dict->SetDouble(path, in_value_64);
}