/*
* Copyright 2011 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "SkScriptRuntime.h"
#include "SkScript2.h"
#include "SkMath.h"
#include "SkParse.h"
#include "SkScriptCallBack.h"
#include "SkString.h"
#include "SkOpArray.h"
// script tokenizer
// turn text into token string
// turn number literals into inline UTF8-style values
// process operators to turn standard notation into stack notation
// defer processing until the tokens can all be resolved
// then, turn token strings into indices into the appropriate tables / dictionaries
// consider: const evaluation?
// replace script string with script tokens preceeded by special value
// need second version of script plugins that return private index of found value?
// then would need in script index of plugin, private index
// encode brace stack push/pop as opcodes
// should token script enocde type where possible?
// current flow:
// strip whitespace
// if in array brace [ recurse, continue
// if token, handle function, or array, or property (continue)
// parse number, continue
// parse token, continue
// parse string literal, continue
// if dot operator, handle dot, continue
// if [ , handle array literal or accessor, continue
// if ), pop (if function, break)
// if ], pop ; if ',' break
// handle logical ops
// or, handle arithmetic ops
// loop
// !!! things to do
// add separate processing loop to advance while suppressed
// or, include jump offset to skip suppressed code?
SkScriptRuntime::~SkScriptRuntime() {
for (SkString** stringPtr = fTrackString.begin(); stringPtr < fTrackString.end(); stringPtr++)
delete *stringPtr;
for (SkOpArray** arrayPtr = fTrackArray.begin(); arrayPtr < fTrackArray.end(); arrayPtr++)
delete *arrayPtr;
}
bool SkScriptRuntime::executeTokens(unsigned char* opCode) {
SkOperand2 operand[2]; // 1=accumulator and 2=operand
SkScriptEngine2::TypeOp op;
size_t ref;
int index, size;
int registerLoad;
SkScriptCallBack* callBack SK_INIT_TO_AVOID_WARNING;
do {
switch ((op = (SkScriptEngine2::TypeOp) *opCode++)) {
case SkScriptEngine2::kArrayToken: // create an array
operand[0].fArray = new SkOpArray(SkOperand2::kNoType /*fReturnType*/);
break;
case SkScriptEngine2::kArrayIndex: // array accessor
index = operand[1].fS32;
if (index >= operand[0].fArray->count()) {
fError = kArrayIndexOutOfBounds;
return false;
}
operand[0] = operand[0].fArray->begin()[index];
break;
case SkScriptEngine2::kArrayParam: // array initializer, or function param
*operand[0].fArray->append() = operand[1];
break;
case SkScriptEngine2::kCallback:
memcpy(&index, opCode, sizeof(index));
opCode += sizeof(index);
callBack = fCallBackArray[index];
break;
case SkScriptEngine2::kFunctionCall: {
memcpy(&ref, opCode, sizeof(ref));
opCode += sizeof(ref);
SkScriptCallBackFunction* callBackFunction = (SkScriptCallBackFunction*) callBack;
if (callBackFunction->invoke(ref, operand[0].fArray, /* params */
&operand[0] /* result */) == false) {
fError = kFunctionCallFailed;
return false;
}
} break;
case SkScriptEngine2::kMemberOp: {
memcpy(&ref, opCode, sizeof(ref));
opCode += sizeof(ref);
SkScriptCallBackMember* callBackMember = (SkScriptCallBackMember*) callBack;
if (callBackMember->invoke(ref, operand[0].fObject, &operand[0]) == false) {
fError = kMemberOpFailed;
return false;
}
} break;
case SkScriptEngine2::kPropertyOp: {
memcpy(&ref, opCode, sizeof(ref));
opCode += sizeof(ref);
SkScriptCallBackProperty* callBackProperty = (SkScriptCallBackProperty*) callBack;
if (callBackProperty->getResult(ref, &operand[0])== false) {
fError = kPropertyOpFailed;
return false;
}
} break;
case SkScriptEngine2::kAccumulatorPop:
fRunStack.pop(&operand[0]);
break;
case SkScriptEngine2::kAccumulatorPush:
*fRunStack.push() = operand[0];
break;
case SkScriptEngine2::kIntegerAccumulator:
case SkScriptEngine2::kIntegerOperand:
registerLoad = op - SkScriptEngine2::kIntegerAccumulator;
memcpy(&operand[registerLoad].fS32, opCode, sizeof(int32_t));
opCode += sizeof(int32_t);
break;
case SkScriptEngine2::kScalarAccumulator:
case SkScriptEngine2::kScalarOperand:
registerLoad = op - SkScriptEngine2::kScalarAccumulator;
memcpy(&operand[registerLoad].fScalar, opCode, sizeof(SkScalar));
opCode += sizeof(SkScalar);
break;
case SkScriptEngine2::kStringAccumulator:
case SkScriptEngine2::kStringOperand: {
SkString* strPtr = new SkString();
track(strPtr);
registerLoad = op - SkScriptEngine2::kStringAccumulator;
memcpy(&size, opCode, sizeof(size));
opCode += sizeof(size);
strPtr->set((char*) opCode, size);
opCode += size;
operand[registerLoad].fString = strPtr;
} break;
case SkScriptEngine2::kStringTrack: // call after kObjectToValue
track(operand[0].fString);
break;
case SkScriptEngine2::kBoxToken: {
SkOperand2::OpType type;
memcpy(&type, opCode, sizeof(type));
opCode += sizeof(type);
SkScriptCallBackConvert* callBackBox = (SkScriptCallBackConvert*) callBack;
if (callBackBox->convert(type, &operand[0]) == false)
return false;
} break;
case SkScriptEngine2::kUnboxToken:
case SkScriptEngine2::kUnboxToken2: {
SkScriptCallBackConvert* callBackUnbox = (SkScriptCallBackConvert*) callBack;
if (callBackUnbox->convert(SkOperand2::kObject, &operand[0]) == false)
return false;
} break;
case SkScriptEngine2::kIfOp:
case SkScriptEngine2::kLogicalAndInt:
memcpy(&size, opCode, sizeof(size));
opCode += sizeof(size);
if (operand[0].fS32 == 0)
opCode += size; // skip to else (or end of if predicate)
break;
case SkScriptEngine2::kElseOp:
memcpy(&size, opCode, sizeof(size));
opCode += sizeof(size);
opCode += size; // if true: after predicate, always skip to end of else
break;
case SkScriptEngine2::kLogicalOrInt:
memcpy(&size, opCode, sizeof(size));
opCode += sizeof(size);
if (operand[0].fS32 != 0)
opCode += size; // skip to kToBool opcode after || predicate
break;
// arithmetic conversion ops
case SkScriptEngine2::kFlipOpsOp:
SkTSwap(operand[0], operand[1]);
break;
case SkScriptEngine2::kIntToString:
case SkScriptEngine2::kIntToString2:
case SkScriptEngine2::kScalarToString:
case SkScriptEngine2::kScalarToString2:{
SkString* strPtr = new SkString();
track(strPtr);
if (op == SkScriptEngine2::kIntToString || op == SkScriptEngine2::kIntToString2)
strPtr->appendS32(operand[op - SkScriptEngine2::kIntToString].fS32);
else
strPtr->appendScalar(operand[op - SkScriptEngine2::kScalarToString].fScalar);
operand[0].fString = strPtr;
} break;
case SkScriptEngine2::kIntToScalar:
case SkScriptEngine2::kIntToScalar2:
operand[0].fScalar = SkScriptEngine2::IntToScalar(operand[op - SkScriptEngine2::kIntToScalar].fS32);
break;
case SkScriptEngine2::kStringToInt:
if (SkParse::FindS32(operand[0].fString->c_str(), &operand[0].fS32) == false)
return false;
break;
case SkScriptEngine2::kStringToScalar:
case SkScriptEngine2::kStringToScalar2:
if (SkParse::FindScalar(operand[0].fString->c_str(),
&operand[op - SkScriptEngine2::kStringToScalar].fScalar) == false)
return false;
break;
case SkScriptEngine2::kScalarToInt:
operand[0].fS32 = SkScalarFloor(operand[0].fScalar);
break;
// arithmetic ops
case SkScriptEngine2::kAddInt:
operand[0].fS32 += operand[1].fS32;
break;
case SkScriptEngine2::kAddScalar:
operand[0].fScalar += operand[1].fScalar;
break;
case SkScriptEngine2::kAddString:
// if (fTrackString.find(operand[1].fString) < 0) {
// operand[1].fString = SkNEW_ARGS(SkString, (*operand[1].fString));
// track(operand[1].fString);
// }
operand[0].fString->append(*operand[1].fString);
break;
case SkScriptEngine2::kBitAndInt:
operand[0].fS32 &= operand[1].fS32;
break;
case SkScriptEngine2::kBitNotInt:
operand[0].fS32 = ~operand[0].fS32;
break;
case SkScriptEngine2::kBitOrInt:
operand[0].fS32 |= operand[1].fS32;
break;
case SkScriptEngine2::kDivideInt:
SkASSERT(operand[1].fS32 != 0);
if (operand[1].fS32 == 0)
operand[0].fS32 = operand[0].fS32 == 0 ? SK_NaN32 :
operand[0].fS32 > 0 ? SK_MaxS32 : -SK_MaxS32;
else
if (operand[1].fS32 != 0) // throw error on divide by zero?
operand[0].fS32 /= operand[1].fS32;
break;
case SkScriptEngine2::kDivideScalar:
if (operand[1].fScalar == 0)
operand[0].fScalar = operand[0].fScalar == 0 ? SK_ScalarNaN :
operand[0].fScalar > 0 ? SK_ScalarMax : -SK_ScalarMax;
else
operand[0].fScalar = SkScalarDiv(operand[0].fScalar, operand[1].fScalar);
break;
case SkScriptEngine2::kEqualInt:
operand[0].fS32 = operand[0].fS32 == operand[1].fS32;
break;
case SkScriptEngine2::kEqualScalar:
operand[0].fS32 = operand[0].fScalar == operand[1].fScalar;
break;
case SkScriptEngine2::kEqualString:
operand[0].fS32 = *operand[0].fString == *operand[1].fString;
break;
case SkScriptEngine2::kGreaterEqualInt:
operand[0].fS32 = operand[0].fS32 >= operand[1].fS32;
break;
case SkScriptEngine2::kGreaterEqualScalar:
operand[0].fS32 = operand[0].fScalar >= operand[1].fScalar;
break;
case SkScriptEngine2::kGreaterEqualString:
operand[0].fS32 = strcmp(operand[0].fString->c_str(), operand[1].fString->c_str()) >= 0;
break;
case SkScriptEngine2::kToBool:
operand[0].fS32 = !! operand[0].fS32;
break;
case SkScriptEngine2::kLogicalNotInt:
operand[0].fS32 = ! operand[0].fS32;
break;
case SkScriptEngine2::kMinusInt:
operand[0].fS32 = -operand[0].fS32;
break;
case SkScriptEngine2::kMinusScalar:
operand[0].fScalar = -operand[0].fScalar;
break;
case SkScriptEngine2::kModuloInt:
operand[0].fS32 %= operand[1].fS32;
break;
case SkScriptEngine2::kModuloScalar:
operand[0].fScalar = SkScalarMod(operand[0].fScalar, operand[1].fScalar);
break;
case SkScriptEngine2::kMultiplyInt:
operand[0].fS32 *= operand[1].fS32;
break;
case SkScriptEngine2::kMultiplyScalar:
operand[0].fScalar = SkScalarMul(operand[0].fScalar, operand[1].fScalar);
break;
case SkScriptEngine2::kShiftLeftInt:
operand[0].fS32 <<= operand[1].fS32;
break;
case SkScriptEngine2::kShiftRightInt:
operand[0].fS32 >>= operand[1].fS32;
break;
case SkScriptEngine2::kSubtractInt:
operand[0].fS32 -= operand[1].fS32;
break;
case SkScriptEngine2::kSubtractScalar:
operand[0].fScalar -= operand[1].fScalar;
break;
case SkScriptEngine2::kXorInt:
operand[0].fS32 ^= operand[1].fS32;
break;
case SkScriptEngine2::kEnd:
goto done;
case SkScriptEngine2::kNop:
SkASSERT(0);
default:
break;
}
} while (true);
done:
fRunStack.push(operand[0]);
return true;
}
bool SkScriptRuntime::getResult(SkOperand2* result) {
if (fRunStack.count() == 0)
return false;
fRunStack.pop(result);
return true;
}
void SkScriptRuntime::track(SkOpArray* array) {
SkASSERT(fTrackArray.find(array) < 0);
*fTrackArray.append() = array;
}
void SkScriptRuntime::track(SkString* string) {
SkASSERT(fTrackString.find(string) < 0);
*fTrackString.append() = string;
}
void SkScriptRuntime::untrack(SkOpArray* array) {
int index = fTrackArray.find(array);
SkASSERT(index >= 0);
fTrackArray.begin()[index] = NULL;
}
void SkScriptRuntime::untrack(SkString* string) {
int index = fTrackString.find(string);
SkASSERT(index >= 0);
fTrackString.begin()[index] = NULL;
}