static Variant xml_call_handler(XmlParser *parser, CVarRef handler,
CArrRef args) {
if (parser && handler) {
Variant retval;
if (handler.isString()) {
if (!parser->object.isObject()) {
retval = invoke(handler.toString().c_str(), args, -1);
} else {
retval = parser->object.toObject()->
o_invoke(handler.toString(), args, -1);
}
} else if (handler.isArray() && handler.getArrayData()->size() == 2 &&
(handler[0].isString() || handler[0].isObject()) &&
handler[1].isString()) {
if (handler[0].isString()) {
// static method
retval = ObjectData::os_invoke(handler[0].toString(),
handler[1].toString(), args, -1);
} else {
// instance method
retval = handler[0].toObject()->o_invoke(handler[1].toString(),
args, -1);
}
} else {
raise_warning("Handler is invalid");
}
return retval;
}
return null;
}
bool ArrayData::hasInternalReference(PointerSet &vars) const {
if (supportValueRef()) {
for (ArrayIter iter(this); iter; ++iter) {
CVarRef var = iter.secondRef();
if (var.isReferenced()) {
Variant *pvar = var.getVariantData();
if (vars.find(pvar) != vars.end()) {
return true;
}
vars.insert(pvar);
}
if (var.isObject()) {
ObjectData *pobj = var.getObjectData();
if (vars.find(pobj) != vars.end()) {
return true;
}
vars.insert(pobj);
if (pobj->o_toArray().get()->hasInternalReference(vars)) {
return true;
}
} else if (var.isArray() &&
var.getArrayData()->hasInternalReference(vars)) {
return true;
}
}
}
return false;
}
bool ArrayData::hasInternalReference(PointerSet &vars,
bool ds /* = false */) const {
if (isSharedMap()) return false;
for (ArrayIter iter(this); iter; ++iter) {
CVarRef var = iter.secondRef();
if (var.isReferenced()) {
Variant *pvar = var.getRefData();
if (vars.find(pvar) != vars.end()) {
return true;
}
vars.insert(pvar);
}
if (var.isObject()) {
ObjectData *pobj = var.getObjectData();
if (vars.find(pobj) != vars.end()) {
return true;
}
vars.insert(pobj);
if (ds && pobj->o_instanceof("Serializable")) {
return true;
}
if (pobj->hasInternalReference(vars, ds)) {
return true;
}
} else if (var.isArray() &&
var.getArrayData()->hasInternalReference(vars, ds)) {
return true;
}
}
return false;
}
int64_t f_count(CVarRef var, bool recursive /* = false */) {
switch (var.getType()) {
case KindOfUninit:
case KindOfNull:
return 0;
case KindOfObject:
{
Object obj = var.toObject();
if (obj->isCollection()) {
return obj->getCollectionSize();
}
if (obj.instanceof(SystemLib::s_CountableClass)) {
return obj->o_invoke_few_args(s_count, 0).toInt64();
}
}
break;
case KindOfArray:
if (recursive) {
CArrRef arr_var = var.toCArrRef();
return php_count_recursive(arr_var);
}
return var.getArrayData()->size();
default:
break;
}
return 1;
}
static void url_encode_array(StringBuffer &ret, CVarRef varr,
std::set<void*> &seen_arrs,
CStrRef num_prefix, CStrRef key_prefix,
CStrRef key_suffix, CStrRef arg_sep) {
void *id = varr.is(KindOfArray) ?
(void*)varr.getArrayData() : (void*)varr.getObjectData();
if (!seen_arrs.insert(id).second) {
return; // recursive
}
Array arr = varr.toArray();
for (ArrayIter iter(arr); iter; ++iter) {
Variant data = iter.second();
if (data.isNull() || data.isResource()) continue;
String key = iter.first();
bool numeric = key.isNumeric();
if (data.is(KindOfArray) || data.is(KindOfObject)) {
String encoded;
if (numeric) {
encoded = key;
} else {
encoded = StringUtil::UrlEncode(key);
}
StringBuffer new_prefix(key_prefix.size() + num_prefix.size() +
encoded.size() + key_suffix.size() + 4);
new_prefix += key_prefix;
if (numeric) new_prefix += num_prefix;
new_prefix += encoded;
new_prefix += key_suffix;
new_prefix += "%5B";
url_encode_array(ret, data, seen_arrs, String(),
new_prefix.detach(), String("%5D", AttachLiteral),
arg_sep);
} else {
if (!ret.empty()) {
ret += arg_sep;
}
ret += key_prefix;
if (numeric) {
ret += num_prefix;
ret += key;
} else {
ret += StringUtil::UrlEncode(key);
}
ret += key_suffix;
ret += "=";
if (data.isInteger() || data.is(KindOfBoolean)) {
ret += String(data.toInt64());
} else if (data.is(KindOfDouble)) {
ret += String(data.toDouble());
} else {
ret += StringUtil::UrlEncode(data.toString());
}
}
}
}
bool same(CVarRef v1, CArrRef v2) {
bool null1 = v1.isNull();
bool null2 = v2.isNull();
if (null1 && null2) return true;
if (null1 || null2) return false;
if (!v1.isArray()) return false;
auto const ad = v1.getArrayData();
return v2->equal(ad, true);
}
static void xml_set_handler(Variant * handler, CVarRef data) {
if (same(data, false) || data.isString() ||
(data.isArray() && data.getArrayData()->size() == 2 &&
(data[0].isString() || data[0].isObject()) &&
data[1].isString())) {
*handler = data;
} else {
raise_warning("Handler is invalid");
}
}
static void compact(HPHP::VM::VarEnv* v, Array &ret, CVarRef var) {
if (var.isArray()) {
for (ArrayIter iter(var.getArrayData()); iter; ++iter) {
compact(v, ret, iter.second());
}
} else {
String varname = var.toString();
if (!varname.empty() && v->lookup(varname.get()) != NULL) {
ret.set(varname, *reinterpret_cast<Variant*>(v->lookup(varname.get())));
}
}
}
Array Array::intersect(CVarRef array, bool by_key, bool by_value,
PFUNC_CMP key_cmp_function /* = NULL */,
const void *key_data /* = NULL */,
PFUNC_CMP value_cmp_function /* = NULL */,
const void *value_data /* = NULL */) const {
if (!array.isArray()) {
throw_bad_array_exception();
return Array();
}
return diffImpl(array.getArrayData(), by_key, by_value, true,
key_cmp_function, key_data,
value_cmp_function, value_data);
}
int hphp_ffi_exportVariant(CVarRef v, void** result) {
switch (v.getType()) {
case KindOfNull: return 0;
case KindOfBoolean: *result = (void*)v.toBoolean(); return 1;
case KindOfByte:
case KindOfInt16:
case KindOfInt32:
case KindOfInt64: {
*result = (void*)v.toInt64();
return 2;
}
case KindOfDouble: {
union {
double d;
void* p;
} u;
u.d = v.toDouble();
*result = u.p;
return 3;
}
case LiteralString: *result = (void*)v.getLiteralString(); return 4;
case KindOfString: {
StringData *sd = v.getStringData();
sd->incRefCount();
*result = (void*)sd;
return 5;
}
case KindOfArray: {
ArrayData *ad = v.getArrayData();
ad->incRefCount();
*result = (void*)ad;
return 6;
}
case KindOfObject: {
ObjectData *od = v.getObjectData();
od->incRefCount();
*result = (void*)od;
return 7;
}
default:
ASSERT(false);
return 0;
}
}
String f_serialize(CVarRef value) {
switch (value.getType()) {
case KindOfUninit:
case KindOfNull:
return "N;";
case KindOfBoolean:
return value.getBoolean() ? "b:1;" : "b:0;";
case KindOfInt64: {
StringBuffer sb;
sb.append("i:");
sb.append(value.getInt64());
sb.append(';');
return sb.detach();
}
case KindOfStaticString:
case KindOfString: {
StringData *str = value.getStringData();
StringBuffer sb;
sb.append("s:");
sb.append(str->size());
sb.append(":\"");
sb.append(str->data(), str->size());
sb.append("\";");
return sb.detach();
}
case KindOfArray: {
ArrayData *arr = value.getArrayData();
if (arr->empty()) return "a:0:{}";
// fall-through
}
case KindOfObject:
case KindOfResource:
case KindOfDouble: {
VariableSerializer vs(VariableSerializer::Type::Serialize);
return vs.serialize(value, true);
}
default:
assert(false);
break;
}
return "";
}
static Variant xml_call_handler(XmlParser *parser, CVarRef handler,
CArrRef args) {
if (parser && handler) {
Variant retval;
if (handler.isString()) {
if (!parser->object.isObject()) {
retval = invoke(handler.toString().c_str(), args, -1);
} else {
retval = parser->object.toObject()->
o_invoke(handler.toString(), args);
}
} else if (handler.isArray() && handler.getArrayData()->size() == 2 &&
(handler[0].isString() || handler[0].isObject()) &&
handler[1].isString()) {
vm_call_user_func(handler, args);
} else {
raise_warning("Handler is invalid");
}
return retval;
}
return uninit_null();
}
bool ArrayData::hasInternalReference(PointerSet &vars,
bool ds /* = false */) const {
if (isSharedMap()) return false;
for (ArrayIter iter(this); iter; ++iter) {
CVarRef var = iter.secondRef();
if (var.isReferenced()) {
Variant *pvar = var.getVariantData();
if (vars.find(pvar) != vars.end()) {
return true;
}
vars.insert(pvar);
}
if (var.isObject()) {
ObjectData *pobj = var.getObjectData();
if (vars.find(pobj) != vars.end()) {
return true;
}
vars.insert(pobj);
if (pobj->o_instanceof("Serializable")) {
if (ds) {
// We want to detect Serializable object as well
return true;
} else {
// Serializable object does not have internal reference issue
return false;
}
}
if (pobj->o_toArray().get()->hasInternalReference(vars, ds)) {
return true;
}
} else if (var.isArray() &&
var.getArrayData()->hasInternalReference(vars, ds)) {
return true;
}
}
return false;
}
SharedVariant::SharedVariant(CVarRef source, bool serialized,
bool inner /* = false */,
bool unserializeObj /* = false */)
: m_shouldCache(false), m_flags(0) {
assert(!serialized || source.isString());
m_count = 1;
m_type = source.getType();
switch (m_type) {
case KindOfBoolean:
{
m_data.num = source.toBoolean();
break;
}
case KindOfInt64:
{
m_type = KindOfInt64;
m_data.num = source.toInt64();
break;
}
case KindOfDouble:
{
m_data.dbl = source.toDouble();
break;
}
case KindOfStaticString:
{
if (serialized) goto StringCase;
m_data.str = source.getStringData();
break;
}
StringCase:
case KindOfString:
{
String s = source.toString();
if (serialized) {
m_type = KindOfObject;
// It is priming, and there might not be the right class definitions
// for unserialization.
s = apc_reserialize(s);
}
StringData* st = StringData::LookupStaticString(s.get());
if (st) {
m_data.str = st;
m_type = KindOfStaticString;
break;
}
m_data.str = s->copy(true);
break;
}
case KindOfArray:
{
ArrayData *arr = source.getArrayData();
if (!inner) {
// only need to call hasInternalReference() on the toplevel array
PointerSet seen;
if (arr->hasInternalReference(seen)) {
setSerializedArray();
m_shouldCache = true;
String s = apc_serialize(source);
m_data.str = StringData::MakeMalloced(s.data(), s.size());
break;
}
}
if (arr->isVectorData()) {
setIsVector();
m_data.vec = new (arr->size()) VectorData();
for (ArrayIter it(arr); !it.end(); it.next()) {
SharedVariant* val = Create(it.secondRef(), false, true,
unserializeObj);
if (val->m_shouldCache) m_shouldCache = true;
m_data.vec->vals()[m_data.vec->m_size++] = val;
}
} else {
m_data.map = ImmutableMap::Create(arr, unserializeObj, m_shouldCache);
}
break;
}
case KindOfUninit:
case KindOfNull:
{
break;
}
case KindOfResource:
{
// TODO Task #2661075: Here and elsewhere in the runtime, we convert
// Resources to the empty array during various serialization operations,
// which does not match Zend behavior. We should fix this.
m_type = KindOfArray;
setIsVector();
m_data.vec = new (0) VectorData();
break;
}
default:
{
assert(source.isObject());
m_shouldCache = true;
if (unserializeObj) {
// This assumes hasInternalReference(seen, true) is false
ImmutableObj* obj = new ImmutableObj(source.getObjectData());
m_data.obj = obj;
setIsObj();
} else {
String s = apc_serialize(source);
m_data.str = StringData::MakeMalloced(s.data(), s.size());
}
break;
}
}
assert(m_type != KindOfResource);
}
ThreadSharedVariant::ThreadSharedVariant(CVarRef source, bool serialized,
bool inner /* = false */) {
ASSERT(!serialized || source.isString());
setOwner();
m_ref = 1;
switch (source.getType()) {
case KindOfBoolean:
{
m_type = KindOfBoolean;
m_data.num = source.toBoolean();
break;
}
case KindOfByte:
case KindOfInt16:
case KindOfInt32:
case KindOfInt64:
{
m_type = KindOfInt64;
m_data.num = source.toInt64();
break;
}
case KindOfDouble:
{
m_type = KindOfDouble;
m_data.dbl = source.toDouble();
break;
}
case KindOfStaticString:
case KindOfString:
{
String s = source.toString();
m_type = serialized ? KindOfObject : KindOfString;
if (serialized) {
// It is priming, and there might not be the right class definitions
// for unserialization.
s = apc_reserialize(s);
}
m_data.str = s->copy(true);
break;
}
case KindOfArray:
{
m_type = KindOfArray;
ArrayData *arr = source.getArrayData();
if (!inner) {
// only need to call hasInternalReference() on the toplevel array
PointerSet seen;
if (arr->hasInternalReference(seen)) {
setSerializedArray();
setShouldCache();
String s = apc_serialize(source);
m_data.str = new StringData(s.data(), s.size(), CopyString);
break;
}
}
size_t size = arr->size();
if (arr->isVectorData()) {
setIsVector();
m_data.vec = new VectorData(size);
uint i = 0;
for (ArrayIter it(arr); !it.end(); it.next(), i++) {
ThreadSharedVariant* val = createAnother(it.second(), false, true);
if (val->shouldCache()) setShouldCache();
m_data.vec->vals[i] = val;
}
} else {
m_data.map = new ImmutableMap(size);
uint i = 0;
for (ArrayIter it(arr); !it.end(); it.next(), i++) {
ThreadSharedVariant* key = createAnother(it.first(), false);
ThreadSharedVariant* val = createAnother(it.second(), false, true);
if (val->shouldCache()) setShouldCache();
m_data.map->add(key, val);
}
}
break;
}
default:
{
m_type = KindOfObject;
setShouldCache();
String s = apc_serialize(source);
m_data.str = new StringData(s.data(), s.size(), CopyString);
break;
}
}
}
static void url_encode_array(StringBuffer &ret, CVarRef varr,
std::set<void*> &seen_arrs,
const String& num_prefix, const String& key_prefix,
const String& key_suffix, const String& arg_sep) {
void *id = varr.is(KindOfArray) ?
(void*)varr.getArrayData() : (void*)varr.getObjectData();
if (!seen_arrs.insert(id).second) {
return; // recursive
}
Array arr;
if (varr.is(KindOfObject)) {
Object o = varr.toObject();
arr = (o.objectForCall()->isCollection()) ?
varr.toArray() :
f_get_object_vars(o).toArray();
} else {
arr = varr.toArray();
}
for (ArrayIter iter(arr); iter; ++iter) {
Variant data = iter.second();
if (data.isNull() || data.isResource()) continue;
String key = iter.first();
bool numeric = key.isNumeric();
if (data.is(KindOfArray) || data.is(KindOfObject)) {
String encoded;
if (numeric) {
encoded = key;
} else {
encoded = StringUtil::UrlEncode(key);
}
StringBuffer new_prefix(key_prefix.size() + num_prefix.size() +
encoded.size() + key_suffix.size() + 4);
new_prefix.append(key_prefix);
if (numeric) new_prefix.append(num_prefix);
new_prefix.append(encoded);
new_prefix.append(key_suffix);
new_prefix.append("%5B");
url_encode_array(ret, data, seen_arrs, String(),
new_prefix.detach(), String("%5D", CopyString),
arg_sep);
} else {
if (!ret.empty()) {
ret.append(arg_sep);
}
ret.append(key_prefix);
if (numeric) {
ret.append(num_prefix);
ret.append(key);
} else {
ret.append(StringUtil::UrlEncode(key));
}
ret.append(key_suffix);
ret.append("=");
if (data.isInteger() || data.is(KindOfBoolean)) {
ret.append(String(data.toInt64()));
} else if (data.is(KindOfDouble)) {
ret.append(String(data.toDouble()));
} else {
ret.append(StringUtil::UrlEncode(data.toString()));
}
}
}
}
Array Array::operator+(CVarRef var) const {
if (var.getType() != KindOfArray) {
throw BadArrayMergeException();
}
return operator+(var.getArrayData());
}
SharedVariant::SharedVariant(CVarRef source, bool serialized,
bool inner /* = false */,
bool unserializeObj /* = false */)
: m_count (1), m_shouldCache(false), m_flags(0){
ASSERT(!serialized || source.isString());
m_type = source.getType();
switch (m_type) {
case KindOfBoolean:
{
m_data.num = source.toBoolean();
break;
}
case KindOfByte:
case KindOfInt16:
case KindOfInt32:
case KindOfInt64:
{
m_type = KindOfInt64;
m_data.num = source.toInt64();
break;
}
case KindOfDouble:
{
m_data.dbl = source.toDouble();
break;
}
case KindOfStaticString:
case KindOfString:
{
String s = source.toString();
if (serialized) {
m_type = KindOfObject;
// It is priming, and there might not be the right class definitions
// for unserialization.
s = apc_reserialize(s);
}
m_data.str = s->copy(true);
break;
}
case KindOfArray:
{
ArrayData *arr = source.getArrayData();
if (!inner) {
// only need to call hasInternalReference() on the toplevel array
PointerSet seen;
if (arr->hasInternalReference(seen)) {
setSerializedArray();
m_shouldCache = true;
String s = apc_serialize(source);
m_data.str = new StringData(s.data(), s.size(), CopyString);
break;
}
}
size_t size = arr->size();
if (arr->isVectorData()) {
setIsVector();
m_data.vec = new VectorData(size);
uint i = 0;
for (ArrayIter it(arr); !it.end(); it.next(), i++) {
SharedVariant* val = Create(it.secondRef(), false, true,
unserializeObj);
if (val->m_shouldCache) m_shouldCache = true;
m_data.vec->vals[i] = val;
}
} else {
m_data.map = new ImmutableMap(size);
for (ArrayIter it(arr); !it.end(); it.next()) {
SharedVariant* key = Create(it.first(), false, true,
unserializeObj);
SharedVariant* val = Create(it.secondRef(), false, true,
unserializeObj);
if (val->m_shouldCache) m_shouldCache = true;
m_data.map->add(key, val);
}
}
break;
}
case KindOfNull:
{
m_data.num = 0;
break;
}
default:
{
ASSERT(source.isObject());
m_shouldCache = true;
if (unserializeObj) {
// This assumes hasInternalReference(seen, true) is false
ImmutableObj* obj = new ImmutableObj(source.getObjectData());
m_data.obj = obj;
setIsObj();
} else {
String s = apc_serialize(source);
m_data.str = new StringData(s.data(), s.size(), CopyString);
}
break;
}
}
}
