// Copyright (c) 2012 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 "base/win/registry.h" #include #include #include "base/logging.h" #include "base/strings/string_util.h" #include "base/threading/thread_restrictions.h" #pragma comment(lib, "shlwapi.lib") // for SHDeleteKey namespace base { namespace win { namespace { // RegEnumValue() reports the number of characters from the name that were // written to the buffer, not how many there are. This constant is the maximum // name size, such that a buffer with this size should read any name. const DWORD MAX_REGISTRY_NAME_SIZE = 16384; // Registry values are read as BYTE* but can have wchar_t* data whose last // wchar_t is truncated. This function converts the reported |byte_size| to // a size in wchar_t that can store a truncated wchar_t if necessary. inline DWORD to_wchar_size(DWORD byte_size) { return (byte_size + sizeof(wchar_t) - 1) / sizeof(wchar_t); } } // namespace // RegKey ---------------------------------------------------------------------- RegKey::RegKey() : key_(NULL), watch_event_(0) { } RegKey::RegKey(HKEY key) : key_(key), watch_event_(0) { } RegKey::RegKey(HKEY rootkey, const wchar_t* subkey, REGSAM access) : key_(NULL), watch_event_(0) { if (rootkey) { if (access & (KEY_SET_VALUE | KEY_CREATE_SUB_KEY | KEY_CREATE_LINK)) Create(rootkey, subkey, access); else Open(rootkey, subkey, access); } else { DCHECK(!subkey); } } RegKey::~RegKey() { Close(); } LONG RegKey::Create(HKEY rootkey, const wchar_t* subkey, REGSAM access) { DWORD disposition_value; return CreateWithDisposition(rootkey, subkey, &disposition_value, access); } LONG RegKey::CreateWithDisposition(HKEY rootkey, const wchar_t* subkey, DWORD* disposition, REGSAM access) { DCHECK(rootkey && subkey && access && disposition); Close(); LONG result = RegCreateKeyEx(rootkey, subkey, 0, NULL, REG_OPTION_NON_VOLATILE, access, NULL, &key_, disposition); return result; } LONG RegKey::CreateKey(const wchar_t* name, REGSAM access) { DCHECK(name && access); HKEY subkey = NULL; LONG result = RegCreateKeyEx(key_, name, 0, NULL, REG_OPTION_NON_VOLATILE, access, NULL, &subkey, NULL); Close(); key_ = subkey; return result; } LONG RegKey::Open(HKEY rootkey, const wchar_t* subkey, REGSAM access) { DCHECK(rootkey && subkey && access); Close(); LONG result = RegOpenKeyEx(rootkey, subkey, 0, access, &key_); return result; } LONG RegKey::OpenKey(const wchar_t* relative_key_name, REGSAM access) { DCHECK(relative_key_name && access); HKEY subkey = NULL; LONG result = RegOpenKeyEx(key_, relative_key_name, 0, access, &subkey); // We have to close the current opened key before replacing it with the new // one. Close(); key_ = subkey; return result; } void RegKey::Close() { StopWatching(); if (key_) { ::RegCloseKey(key_); key_ = NULL; } } void RegKey::Set(HKEY key) { if (key_ != key) { Close(); key_ = key; } } HKEY RegKey::Take() { StopWatching(); HKEY key = key_; key_ = NULL; return key; } bool RegKey::HasValue(const wchar_t* name) const { return RegQueryValueEx(key_, name, 0, NULL, NULL, NULL) == ERROR_SUCCESS; } DWORD RegKey::GetValueCount() const { DWORD count = 0; LONG result = RegQueryInfoKey(key_, NULL, 0, NULL, NULL, NULL, NULL, &count, NULL, NULL, NULL, NULL); return (result == ERROR_SUCCESS) ? count : 0; } LONG RegKey::GetValueNameAt(int index, std::wstring* name) const { wchar_t buf[256]; DWORD bufsize = arraysize(buf); LONG r = ::RegEnumValue(key_, index, buf, &bufsize, NULL, NULL, NULL, NULL); if (r == ERROR_SUCCESS) *name = buf; return r; } LONG RegKey::DeleteKey(const wchar_t* name) { DCHECK(key_); DCHECK(name); LONG result = SHDeleteKey(key_, name); return result; } LONG RegKey::DeleteValue(const wchar_t* value_name) { DCHECK(key_); LONG result = RegDeleteValue(key_, value_name); return result; } LONG RegKey::ReadValueDW(const wchar_t* name, DWORD* out_value) const { DCHECK(out_value); DWORD type = REG_DWORD; DWORD size = sizeof(DWORD); DWORD local_value = 0; LONG result = ReadValue(name, &local_value, &size, &type); if (result == ERROR_SUCCESS) { if ((type == REG_DWORD || type == REG_BINARY) && size == sizeof(DWORD)) *out_value = local_value; else result = ERROR_CANTREAD; } return result; } LONG RegKey::ReadInt64(const wchar_t* name, int64* out_value) const { DCHECK(out_value); DWORD type = REG_QWORD; int64 local_value = 0; DWORD size = sizeof(local_value); LONG result = ReadValue(name, &local_value, &size, &type); if (result == ERROR_SUCCESS) { if ((type == REG_QWORD || type == REG_BINARY) && size == sizeof(local_value)) *out_value = local_value; else result = ERROR_CANTREAD; } return result; } LONG RegKey::ReadValue(const wchar_t* name, std::wstring* out_value) const { DCHECK(out_value); const size_t kMaxStringLength = 1024; // This is after expansion. // Use the one of the other forms of ReadValue if 1024 is too small for you. wchar_t raw_value[kMaxStringLength]; DWORD type = REG_SZ, size = sizeof(raw_value); LONG result = ReadValue(name, raw_value, &size, &type); if (result == ERROR_SUCCESS) { if (type == REG_SZ) { *out_value = raw_value; } else if (type == REG_EXPAND_SZ) { wchar_t expanded[kMaxStringLength]; size = ExpandEnvironmentStrings(raw_value, expanded, kMaxStringLength); // Success: returns the number of wchar_t's copied // Fail: buffer too small, returns the size required // Fail: other, returns 0 if (size == 0 || size > kMaxStringLength) { result = ERROR_MORE_DATA; } else { *out_value = expanded; } } else { // Not a string. Oops. result = ERROR_CANTREAD; } } return result; } LONG RegKey::ReadValue(const wchar_t* name, void* data, DWORD* dsize, DWORD* dtype) const { LONG result = RegQueryValueEx(key_, name, 0, dtype, reinterpret_cast(data), dsize); return result; } LONG RegKey::ReadValues(const wchar_t* name, std::vector* values) { values->clear(); DWORD type = REG_MULTI_SZ; DWORD size = 0; LONG result = ReadValue(name, NULL, &size, &type); if (FAILED(result) || size == 0) return result; if (type != REG_MULTI_SZ) return ERROR_CANTREAD; std::vector buffer(size / sizeof(wchar_t)); result = ReadValue(name, &buffer[0], &size, NULL); if (FAILED(result) || size == 0) return result; // Parse the double-null-terminated list of strings. // Note: This code is paranoid to not read outside of |buf|, in the case where // it may not be properly terminated. const wchar_t* entry = &buffer[0]; const wchar_t* buffer_end = entry + (size / sizeof(wchar_t)); while (entry < buffer_end && entry[0] != '\0') { const wchar_t* entry_end = std::find(entry, buffer_end, L'\0'); values->push_back(std::wstring(entry, entry_end)); entry = entry_end + 1; } return 0; } LONG RegKey::WriteValue(const wchar_t* name, DWORD in_value) { return WriteValue( name, &in_value, static_cast(sizeof(in_value)), REG_DWORD); } LONG RegKey::WriteValue(const wchar_t * name, const wchar_t* in_value) { return WriteValue(name, in_value, static_cast(sizeof(*in_value) * (wcslen(in_value) + 1)), REG_SZ); } LONG RegKey::WriteValue(const wchar_t* name, const void* data, DWORD dsize, DWORD dtype) { DCHECK(data || !dsize); LONG result = RegSetValueEx(key_, name, 0, dtype, reinterpret_cast(const_cast(data)), dsize); return result; } LONG RegKey::StartWatching() { DCHECK(key_); if (!watch_event_) watch_event_ = CreateEvent(NULL, TRUE, FALSE, NULL); DWORD filter = REG_NOTIFY_CHANGE_NAME | REG_NOTIFY_CHANGE_ATTRIBUTES | REG_NOTIFY_CHANGE_LAST_SET | REG_NOTIFY_CHANGE_SECURITY; // Watch the registry key for a change of value. LONG result = RegNotifyChangeKeyValue(key_, TRUE, filter, watch_event_, TRUE); if (result != ERROR_SUCCESS) { CloseHandle(watch_event_); watch_event_ = 0; } return result; } bool RegKey::HasChanged() { if (watch_event_) { if (WaitForSingleObject(watch_event_, 0) == WAIT_OBJECT_0) { StartWatching(); return true; } } return false; } LONG RegKey::StopWatching() { LONG result = ERROR_INVALID_HANDLE; if (watch_event_) { CloseHandle(watch_event_); watch_event_ = 0; result = ERROR_SUCCESS; } return result; } // RegistryValueIterator ------------------------------------------------------ RegistryValueIterator::RegistryValueIterator(HKEY root_key, const wchar_t* folder_key) : name_(MAX_PATH, L'\0'), value_(MAX_PATH, L'\0') { LONG result = RegOpenKeyEx(root_key, folder_key, 0, KEY_READ, &key_); if (result != ERROR_SUCCESS) { key_ = NULL; } else { DWORD count = 0; result = ::RegQueryInfoKey(key_, NULL, 0, NULL, NULL, NULL, NULL, &count, NULL, NULL, NULL, NULL); if (result != ERROR_SUCCESS) { ::RegCloseKey(key_); key_ = NULL; } else { index_ = count - 1; } } Read(); } RegistryValueIterator::~RegistryValueIterator() { if (key_) ::RegCloseKey(key_); } DWORD RegistryValueIterator::ValueCount() const { DWORD count = 0; LONG result = ::RegQueryInfoKey(key_, NULL, 0, NULL, NULL, NULL, NULL, &count, NULL, NULL, NULL, NULL); if (result != ERROR_SUCCESS) return 0; return count; } bool RegistryValueIterator::Valid() const { return key_ != NULL && index_ >= 0; } void RegistryValueIterator::operator++() { --index_; Read(); } bool RegistryValueIterator::Read() { if (Valid()) { DWORD capacity = static_cast(name_.capacity()); DWORD name_size = capacity; // |value_size_| is in bytes. Reserve the last character for a NUL. value_size_ = static_cast((value_.size() - 1) * sizeof(wchar_t)); LONG result = ::RegEnumValue( key_, index_, WriteInto(&name_, name_size), &name_size, NULL, &type_, reinterpret_cast(vector_as_array(&value_)), &value_size_); if (result == ERROR_MORE_DATA) { // Registry key names are limited to 255 characters and fit within // MAX_PATH (which is 260) but registry value names can use up to 16,383 // characters and the value itself is not limited // (from http://msdn.microsoft.com/en-us/library/windows/desktop/ // ms724872(v=vs.85).aspx). // Resize the buffers and retry if their size caused the failure. DWORD value_size_in_wchars = to_wchar_size(value_size_); if (value_size_in_wchars + 1 > value_.size()) value_.resize(value_size_in_wchars + 1, L'\0'); value_size_ = static_cast((value_.size() - 1) * sizeof(wchar_t)); name_size = name_size == capacity ? MAX_REGISTRY_NAME_SIZE : capacity; result = ::RegEnumValue( key_, index_, WriteInto(&name_, name_size), &name_size, NULL, &type_, reinterpret_cast(vector_as_array(&value_)), &value_size_); } if (result == ERROR_SUCCESS) { DCHECK_LT(to_wchar_size(value_size_), value_.size()); value_[to_wchar_size(value_size_)] = L'\0'; return true; } } name_[0] = L'\0'; value_[0] = L'\0'; value_size_ = 0; return false; } // RegistryKeyIterator -------------------------------------------------------- RegistryKeyIterator::RegistryKeyIterator(HKEY root_key, const wchar_t* folder_key) { LONG result = RegOpenKeyEx(root_key, folder_key, 0, KEY_READ, &key_); if (result != ERROR_SUCCESS) { key_ = NULL; } else { DWORD count = 0; LONG result = ::RegQueryInfoKey(key_, NULL, 0, NULL, &count, NULL, NULL, NULL, NULL, NULL, NULL, NULL); if (result != ERROR_SUCCESS) { ::RegCloseKey(key_); key_ = NULL; } else { index_ = count - 1; } } Read(); } RegistryKeyIterator::~RegistryKeyIterator() { if (key_) ::RegCloseKey(key_); } DWORD RegistryKeyIterator::SubkeyCount() const { DWORD count = 0; LONG result = ::RegQueryInfoKey(key_, NULL, 0, NULL, &count, NULL, NULL, NULL, NULL, NULL, NULL, NULL); if (result != ERROR_SUCCESS) return 0; return count; } bool RegistryKeyIterator::Valid() const { return key_ != NULL && index_ >= 0; } void RegistryKeyIterator::operator++() { --index_; Read(); } bool RegistryKeyIterator::Read() { if (Valid()) { DWORD ncount = arraysize(name_); FILETIME written; LONG r = ::RegEnumKeyEx(key_, index_, name_, &ncount, NULL, NULL, NULL, &written); if (ERROR_SUCCESS == r) return true; } name_[0] = '\0'; return false; } } // namespace win } // namespace base