Arquivos
hhvm/hphp/runtime/vm/runtime.cpp
T
Keith Adams 98483c74d6 Lift a lot of stuff out of HPHP::VM.
This is a partial step towards merging the HPHP::VM namespace
up into its parent. To keep it reviewable/mergeable I'm not doing
everything at once here, but most of the code I've touched seems
improved. I've drawn an invisible line around the jit, Unit and
its cohort (Class, Func, PreClass, etc.); we'll get back to them
soon.
2013-04-25 00:50:01 -07:00

523 linhas
14 KiB
C++

/*
+----------------------------------------------------------------------+
| HipHop for PHP |
+----------------------------------------------------------------------+
| Copyright (c) 2010- Facebook, Inc. (http://www.facebook.com) |
+----------------------------------------------------------------------+
| This source file is subject to version 3.01 of the PHP license, |
| that is bundled with this package in the file LICENSE, and is |
| available through the world-wide-web at the following url: |
| http://www.php.net/license/3_01.txt |
| If you did not receive a copy of the PHP license and are unable to |
| obtain it through the world-wide-web, please send a note to |
| license@php.net so we can mail you a copy immediately. |
+----------------------------------------------------------------------+
*/
#include "runtime/base/execution_context.h"
#include "runtime/base/complex_types.h"
#include "runtime/base/zend/zend_string.h"
#include "runtime/base/array/hphp_array.h"
#include "runtime/base/builtin_functions.h"
#include "runtime/ext/ext_closure.h"
#include "runtime/ext/ext_continuation.h"
#include "runtime/ext/ext_collections.h"
#include "runtime/vm/core_types.h"
#include "runtime/vm/bytecode.h"
#include "runtime/vm/repo.h"
#include "util/trace.h"
#include "runtime.h"
#include "runtime/vm/translator/translator-inline.h"
#include "runtime/vm/translator/translator-x64.h"
#include "runtime/base/zend/zend_functions.h"
#include "runtime/ext/ext_string.h"
namespace HPHP {
using VM::Unit;
using VM::Func;
using VM::Transl::tx64;
static const Trace::Module TRACEMOD = Trace::runtime;
CompileStringFn g_hphp_compiler_parse;
BuildNativeFuncUnitFn g_hphp_build_native_func_unit;
BuildNativeClassUnitFn g_hphp_build_native_class_unit;
/**
* print_string will decRef the string
*/
void print_string(StringData* s) {
g_context->write(s->data(), s->size());
TRACE(1, "t-x64 output(str): (%p) %43s\n", s->data(),
Util::escapeStringForCPP(s->data(), s->size()).data());
decRefStr(s);
}
void print_int(int64_t i) {
char buf[256];
snprintf(buf, 256, "%" PRId64, i);
echo(buf);
TRACE(1, "t-x64 output(int): %" PRId64 "\n", i);
}
void print_boolean(bool val) {
if (val) {
echo("1");
}
}
HOT_FUNC_VM
ArrayData* new_array(int capacity) {
ArrayData *a = NEW(HphpArray)(capacity);
a->incRefCount();
TRACE(2, "newArrayHelper: capacity %d\n", capacity);
return a;
}
ArrayData* new_tuple(int n, const TypedValue* values) {
HphpArray* a = NEW(HphpArray)(n, values);
a->incRefCount();
TRACE(2, "new_tuple: size %d\n", n);
return a;
}
#define NEW_COLLECTION_HELPER(name) \
ObjectData* \
new##name##Helper(int nElms) { \
ObjectData *obj = NEWOBJ(c_##name)(); \
obj->incRefCount(); \
if (nElms) { \
collectionReserve(obj, nElms); \
} \
TRACE(2, "new" #name "Helper: capacity %d\n", nElms); \
return obj; \
}
NEW_COLLECTION_HELPER(Vector)
NEW_COLLECTION_HELPER(Map)
NEW_COLLECTION_HELPER(StableMap)
ObjectData* newPairHelper() {
ObjectData *obj = NEWOBJ(c_Pair)();
obj->incRefCount();
TRACE(2, "newPairHelper: capacity 2\n");
return obj;
}
#undef NEW_COLLECTION_HELPER
static inline void
tvPairToCString(DataType t, uint64_t v,
const char** outStr,
size_t* outSz,
bool* outMustFree) {
if (IS_STRING_TYPE(t)) {
StringData *strd = (StringData*)v;
*outStr = strd->data();
*outSz = strd->size();
*outMustFree = false;
return;
}
Cell c;
c.m_type = t;
c.m_data.num = v;
String s = tvAsVariant(&c).toString();
*outStr = (const char*)malloc(s.size());
TRACE(1, "t-x64: stringified: %s -> %s\n", s.data(), *outStr);
memcpy((char*)*outStr, s.data(), s.size());
*outSz = s.size();
*outMustFree = true;
}
/**
* concat_ss will decRef the values passed in as appropriate, and it will
* incRef the output string
*/
StringData*
concat_ss(StringData* v1, StringData* v2) {
if (v1->getCount() > 1) {
StringData* ret = NEW(StringData)(v1, v2);
ret->setRefCount(1);
decRefStr(v2);
// Because v1->getCount() is greater than 1, we know we will never
// have to release the string here
v1->decRefCount();
return ret;
} else {
v1->append(v2->slice());
decRefStr(v2);
return v1;
}
}
/**
* concat_is will decRef the string passed in as appropriate, and it will
* incRef the output string
*/
StringData*
concat_is(int64_t v1, StringData* v2) {
int len1;
char intbuf[21];
char* intstart;
// Convert the int to a string
{
int is_negative;
intstart = conv_10(v1, &is_negative, intbuf + sizeof(intbuf), &len1);
}
StringSlice s1(intstart, len1);
StringSlice s2 = v2->slice();
StringData* ret = NEW(StringData)(s1, s2);
ret->incRefCount();
decRefStr(v2);
return ret;
}
/**
* concat_si will decRef the string passed in as appropriate, and it will
* incRef the output string
*/
StringData*
concat_si(StringData* v1, int64_t v2) {
int len2;
char intbuf[21];
char* intstart;
// Convert the int to a string
{
int is_negative;
intstart = conv_10(v2, &is_negative, intbuf + sizeof(intbuf), &len2);
}
StringSlice s1 = v1->slice();
StringSlice s2(intstart, len2);
StringData* ret = NEW(StringData)(s1, s2);
ret->incRefCount();
decRefStr(v1);
return ret;
}
/**
* concat will decRef the values passed in as appropriate, and it will
* incRef the output string
*/
StringData*
concat_tv(DataType t1, uint64_t v1, DataType t2, uint64_t v2) {
const char *s1, *s2;
size_t s1len, s2len;
bool free1, free2;
tvPairToCString(t1, v1, &s1, &s1len, &free1);
tvPairToCString(t2, v2, &s2, &s2len, &free2);
StringSlice r1(s1, s1len);
StringSlice r2(s2, s2len);
StringData* retval = NEW(StringData)(r1, r2);
retval->incRefCount();
// If tvPairToCString allocated temporary buffers, free them now
if (free1) free((void*)s1);
if (free2) free((void*)s2);
// decRef the parameters as appropriate
tvRefcountedDecRefHelper(t2, v2);
tvRefcountedDecRefHelper(t1, v1);
return retval;
}
int64_t eq_null_str(StringData* v1) {
int64_t retval = v1->empty();
decRefStr(v1);
return retval;
}
int64_t eq_bool_str(int64_t v1, StringData* v2) {
// The truth table for v2->toBoolean() ? v1 : !v1
// looks like:
// \ v2:0 | v2:1
// v1:0 | 1 | 0
// v1:1 | 0 | 1
//
// which is nothing but nxor.
int64_t v2i = int64_t(v2->toBoolean());
assert(v2i == 0ll || v2i == 1ll);
assert(v1 == 0ll || v1 == 1ll);
int64_t retval = (v2i ^ v1) ^ 1;
assert(retval == 0ll || retval == 1ll);
decRefStr(v2);
return retval;
}
int64_t eq_int_str(int64_t v1, StringData* v2) {
int64_t lval; double dval;
DataType ret = is_numeric_string(v2->data(), v2->size(), &lval, &dval, 1);
decRefStr(v2);
if (ret == KindOfInt64) {
return v1 == lval;
} else if (ret == KindOfDouble) {
return (double)v1 == dval;
} else {
return v1 == 0;
}
}
int64_t eq_str_str(StringData* v1, StringData* v2) {
int64_t retval = v1->equal(v2);
decRefStr(v2);
decRefStr(v1);
return retval;
}
int64_t same_str_str(StringData* v1, StringData* v2) {
int64_t retval = v1 == v2 || v1->same(v2);
decRefStr(v2);
decRefStr(v1);
return retval;
}
int64_t str0_to_bool(StringData* sd) {
int64_t retval = sd->toBoolean();
return retval;
}
int64_t str_to_bool(StringData* sd) {
int64_t retval = str0_to_bool(sd);
decRefStr(sd);
return retval;
}
int64_t arr0_to_bool(ArrayData* ad) {
return ad->size() != 0;
}
int64_t arr_to_bool(ArrayData* ad) {
assert(tx64->stateIsDirty());
int64_t retval = arr0_to_bool(ad);
decRefArr(ad);
return retval;
}
/**
* tv_to_bool will decrement tv's refcount if tv is a refcounted type
*/
int64_t
tv_to_bool(TypedValue* tv) {
using std::string;
bool retval;
if (IS_STRING_TYPE(tv->m_type)) {
StringData* sd = tv->m_data.pstr;
retval = bool(str0_to_bool(sd));
} else if (tv->m_type == KindOfArray) {
ArrayData* ad = tv->m_data.parr;
retval = bool(arr0_to_bool(ad));
} else {
retval = bool(tvAsCVarRef(tv));
}
TRACE(2, Trace::prettyNode("TvToBool", *tv) + string(" -> ") +
string(retval ? "t" : "f") + string("\n"));
tvRefcountedDecRef(tv);
return int64_t(retval);
}
Unit* compile_file(const char* s, size_t sz, const MD5& md5,
const char* fname) {
return g_hphp_compiler_parse(s, sz, md5, fname);
}
Unit* build_native_func_unit(const HhbcExtFuncInfo* builtinFuncs,
ssize_t numBuiltinFuncs) {
return g_hphp_build_native_func_unit(builtinFuncs, numBuiltinFuncs);
}
Unit* build_native_class_unit(const HhbcExtClassInfo* builtinClasses,
ssize_t numBuiltinClasses) {
return g_hphp_build_native_class_unit(builtinClasses, numBuiltinClasses);
}
Unit* compile_string(const char* s, size_t sz) {
MD5 md5;
int out_len;
md5 = MD5(string_md5(s, sz, false, out_len));
VM::Unit* u = VM::Repo::get().loadUnit("", md5);
if (u != nullptr) {
return u;
}
return g_hphp_compiler_parse(s, sz, md5, nullptr);
}
// Returned array has refcount zero! Caller must refcount.
HphpArray* pack_args_into_array(ActRec* ar, int nargs) {
HphpArray* argArray = NEW(HphpArray)(nargs);
for (int i = 0; i < nargs; ++i) {
TypedValue* tv = (TypedValue*)(ar) - (i+1);
argArray->HphpArray::appendWithRef(tvAsCVarRef(tv), false);
}
if (!ar->hasInvName()) {
// If this is not a magic call, we're done
return argArray;
}
// This is a magic call, so we need to shuffle the args
HphpArray* magicArgs = NEW(HphpArray)(2);
magicArgs->append(ar->getInvName(), false);
magicArgs->append(argArray, false);
return magicArgs;
}
bool run_intercept_handler_for_invokefunc(TypedValue* retval,
const Func* f,
CArrRef params,
ObjectData* this_,
StringData* invName,
Variant* ihandler) {
using namespace HPHP::VM::Transl;
assert(ihandler);
assert(retval);
Variant doneFlag = true;
Array args = params;
if (invName) {
// This is a magic call, so we need to shuffle the args
HphpArray* magicArgs = NEW(HphpArray)(2);
magicArgs->append(invName, false);
magicArgs->append(params, false);
args = magicArgs;
}
Array intArgs =
CREATE_VECTOR5(f->fullNameRef(), (this_ ? Variant(Object(this_)) : uninit_null()),
args, ihandler->asCArrRef()[1], ref(doneFlag));
call_intercept_handler<false>(retval, intArgs, nullptr, ihandler);
// $done is true, meaning don't enter the intercepted function.
return !doneFlag.toBoolean();
}
HphpArray* get_static_locals(const ActRec* ar) {
if (ar->m_func->isClosureBody()) {
TypedValue* closureLoc = frame_local(ar, ar->m_func->numParams());
c_Closure* closure = static_cast<c_Closure*>(closureLoc->m_data.pobj);
assert(closure != nullptr);
return closure->getStaticLocals();
} else if (ar->m_func->isGeneratorFromClosure()) {
TypedValue* contLoc = frame_local(ar, 0);
c_Continuation* cont = static_cast<c_Continuation*>(contLoc->m_data.pobj);
assert(cont != nullptr);
return cont->getStaticLocals();
} else {
return ar->m_func->getStaticLocals();
}
}
void collection_setm_wk1_v0(ObjectData* obj, TypedValue* value) {
assert(obj);
collectionAppend(obj, value);
// TODO Task #1970153: It would be great if we had a version of
// collectionAppend() that didn't incRef the value so that we
// wouldn't have to decRef it here
tvRefcountedDecRef(value);
}
void collection_setm_ik1_v0(ObjectData* obj, int64_t key, TypedValue* value) {
assert(obj);
switch (obj->getCollectionType()) {
case Collection::VectorType: {
c_Vector* vec = static_cast<c_Vector*>(obj);
vec->set(key, value);
break;
}
case Collection::MapType: {
c_Map* mp = static_cast<c_Map*>(obj);
mp->set(key, value);
break;
}
case Collection::StableMapType: {
c_StableMap* smp = static_cast<c_StableMap*>(obj);
smp->set(key, value);
break;
}
case Collection::PairType: {
Object e(SystemLib::AllocRuntimeExceptionObject(
"Cannot assign to an element of a Pair"));
throw e;
}
default:
assert(false);
}
tvRefcountedDecRef(value);
}
void collection_setm_sk1_v0(ObjectData* obj, StringData* key,
TypedValue* value) {
switch (obj->getCollectionType()) {
case Collection::VectorType: {
Object e(SystemLib::AllocInvalidArgumentExceptionObject(
"Only integer keys may be used with Vectors"));
throw e;
}
case Collection::MapType: {
c_Map* mp = static_cast<c_Map*>(obj);
mp->set(key, value);
break;
}
case Collection::StableMapType: {
c_StableMap* smp = static_cast<c_StableMap*>(obj);
smp->set(key, value);
break;
}
case Collection::PairType: {
Object e(SystemLib::AllocRuntimeExceptionObject(
"Cannot assign to an element of a Pair"));
throw e;
}
default:
assert(false);
}
tvRefcountedDecRef(value);
}
bool checkTv(const TypedValue* tv) {
return tv && tvIsPlausible(tv) &&
(!IS_REFCOUNTED_TYPE(tv->m_type) ||
is_refcount_realistic(tv->m_data.pstr->getCount()));
}
void assertTv(const TypedValue* tv) {
always_assert(checkTv(tv));
}
int init_closure(ActRec* ar, TypedValue* sp) {
c_Closure* closure = static_cast<c_Closure*>(ar->getThis());
// Swap in the $this or late bound class
ar->setThis(closure->getThisOrClass());
if (ar->hasThis()) {
ar->getThis()->incRefCount();
}
// Put in the correct context
ar->m_func = closure->getInvokeFunc();
// The closure is the first local.
// Similar to tvWriteObject() but we don't incref because it used to be $this
// and now it is a local, so they cancel out
TypedValue* firstLocal = --sp;
firstLocal->m_type = KindOfObject;
firstLocal->m_data.pobj = closure;
// Copy in all the use vars
TypedValue* prop = closure->getUseVars();
int n = closure->getNumUseVars();
for (int i=0; i < n; i++) {
tvDup(prop++, --sp);
}
return n + 1;
}
void raiseWarning(const StringData* sd) {
raise_warning("%s", sd->data());
}
HOT_FUNC int64_t modHelper(int64_t left, int64_t right) {
// We already dealt with divide-by-zero up in hhbctranslator.
assert(right != 0);
return left % right;
}
} // HPHP::VM