mirror of
https://github.com/luau-lang/luau.git
synced 2024-12-13 05:20:38 +00:00
be2769ad14
- Fix autocomplete not suggesting globals defined after the cursor (fixes #622) - Improve type checker stability - Reduce parser C stack consumption which fixes some stack overflow crashes on deeply nested sources - Improve performance of bit32.extract/replace when width is implied (~3% faster chess) - Improve performance of bit32.extract when field/width are constants (~10% faster base64) - Heap dump now annotates thread stacks with local variable/function names
464 lines
13 KiB
C++
464 lines
13 KiB
C++
// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
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#include "BuiltinFolding.h"
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#include "Luau/Bytecode.h"
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#include <math.h>
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namespace Luau
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{
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namespace Compile
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{
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const double kRadDeg = 3.14159265358979323846 / 180.0;
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static Constant cvar()
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{
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return Constant();
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}
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static Constant cbool(bool v)
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{
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Constant res = {Constant::Type_Boolean};
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res.valueBoolean = v;
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return res;
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}
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static Constant cnum(double v)
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{
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Constant res = {Constant::Type_Number};
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res.valueNumber = v;
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return res;
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}
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static Constant cstring(const char* v)
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{
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Constant res = {Constant::Type_String};
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res.stringLength = unsigned(strlen(v));
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res.valueString = v;
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return res;
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}
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static Constant ctype(const Constant& c)
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{
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LUAU_ASSERT(c.type != Constant::Type_Unknown);
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switch (c.type)
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{
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case Constant::Type_Nil:
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return cstring("nil");
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case Constant::Type_Boolean:
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return cstring("boolean");
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case Constant::Type_Number:
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return cstring("number");
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case Constant::Type_String:
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return cstring("string");
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default:
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LUAU_ASSERT(!"Unsupported constant type");
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return cvar();
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}
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}
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static uint32_t bit32(double v)
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{
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// convert through signed 64-bit integer to match runtime behavior and gracefully truncate negative integers
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return uint32_t(int64_t(v));
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}
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Constant foldBuiltin(int bfid, const Constant* args, size_t count)
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{
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switch (bfid)
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{
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case LBF_MATH_ABS:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(fabs(args[0].valueNumber));
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break;
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case LBF_MATH_ACOS:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(acos(args[0].valueNumber));
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break;
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case LBF_MATH_ASIN:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(asin(args[0].valueNumber));
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break;
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case LBF_MATH_ATAN2:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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return cnum(atan2(args[0].valueNumber, args[1].valueNumber));
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break;
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case LBF_MATH_ATAN:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(atan(args[0].valueNumber));
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break;
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case LBF_MATH_CEIL:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(ceil(args[0].valueNumber));
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break;
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case LBF_MATH_COSH:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(cosh(args[0].valueNumber));
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break;
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case LBF_MATH_COS:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(cos(args[0].valueNumber));
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break;
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case LBF_MATH_DEG:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(args[0].valueNumber / kRadDeg);
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break;
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case LBF_MATH_EXP:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(exp(args[0].valueNumber));
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break;
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case LBF_MATH_FLOOR:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(floor(args[0].valueNumber));
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break;
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case LBF_MATH_FMOD:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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return cnum(fmod(args[0].valueNumber, args[1].valueNumber));
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break;
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// Note: FREXP isn't folded since it returns multiple values
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case LBF_MATH_LDEXP:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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return cnum(ldexp(args[0].valueNumber, int(args[1].valueNumber)));
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break;
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case LBF_MATH_LOG10:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(log10(args[0].valueNumber));
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break;
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case LBF_MATH_LOG:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(log(args[0].valueNumber));
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else if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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{
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if (args[1].valueNumber == 2.0)
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return cnum(log2(args[0].valueNumber));
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else if (args[1].valueNumber == 10.0)
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return cnum(log10(args[0].valueNumber));
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else
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return cnum(log(args[0].valueNumber) / log(args[1].valueNumber));
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}
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break;
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case LBF_MATH_MAX:
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if (count >= 1 && args[0].type == Constant::Type_Number)
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{
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double r = args[0].valueNumber;
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for (size_t i = 1; i < count; ++i)
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{
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if (args[i].type != Constant::Type_Number)
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return cvar();
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double a = args[i].valueNumber;
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r = (a > r) ? a : r;
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}
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return cnum(r);
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}
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break;
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case LBF_MATH_MIN:
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if (count >= 1 && args[0].type == Constant::Type_Number)
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{
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double r = args[0].valueNumber;
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for (size_t i = 1; i < count; ++i)
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{
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if (args[i].type != Constant::Type_Number)
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return cvar();
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double a = args[i].valueNumber;
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r = (a < r) ? a : r;
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}
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return cnum(r);
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}
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break;
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// Note: MODF isn't folded since it returns multiple values
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case LBF_MATH_POW:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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return cnum(pow(args[0].valueNumber, args[1].valueNumber));
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break;
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case LBF_MATH_RAD:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(args[0].valueNumber * kRadDeg);
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break;
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case LBF_MATH_SINH:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(sinh(args[0].valueNumber));
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break;
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case LBF_MATH_SIN:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(sin(args[0].valueNumber));
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break;
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case LBF_MATH_SQRT:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(sqrt(args[0].valueNumber));
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break;
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case LBF_MATH_TANH:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(tanh(args[0].valueNumber));
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break;
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case LBF_MATH_TAN:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(tan(args[0].valueNumber));
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break;
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case LBF_BIT32_ARSHIFT:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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{
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uint32_t u = bit32(args[0].valueNumber);
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int s = int(args[1].valueNumber);
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if (unsigned(s) < 32)
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return cnum(double(uint32_t(int32_t(u) >> s)));
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}
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break;
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case LBF_BIT32_BAND:
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if (count >= 1 && args[0].type == Constant::Type_Number)
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{
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uint32_t r = bit32(args[0].valueNumber);
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for (size_t i = 1; i < count; ++i)
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{
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if (args[i].type != Constant::Type_Number)
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return cvar();
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r &= bit32(args[i].valueNumber);
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}
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return cnum(double(r));
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}
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break;
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case LBF_BIT32_BNOT:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(double(uint32_t(~bit32(args[0].valueNumber))));
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break;
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case LBF_BIT32_BOR:
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if (count >= 1 && args[0].type == Constant::Type_Number)
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{
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uint32_t r = bit32(args[0].valueNumber);
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for (size_t i = 1; i < count; ++i)
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{
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if (args[i].type != Constant::Type_Number)
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return cvar();
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r |= bit32(args[i].valueNumber);
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}
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return cnum(double(r));
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}
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break;
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case LBF_BIT32_BXOR:
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if (count >= 1 && args[0].type == Constant::Type_Number)
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{
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uint32_t r = bit32(args[0].valueNumber);
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for (size_t i = 1; i < count; ++i)
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{
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if (args[i].type != Constant::Type_Number)
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return cvar();
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r ^= bit32(args[i].valueNumber);
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}
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return cnum(double(r));
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}
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break;
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case LBF_BIT32_BTEST:
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if (count >= 1 && args[0].type == Constant::Type_Number)
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{
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uint32_t r = bit32(args[0].valueNumber);
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for (size_t i = 1; i < count; ++i)
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{
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if (args[i].type != Constant::Type_Number)
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return cvar();
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r &= bit32(args[i].valueNumber);
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}
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return cbool(r != 0);
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}
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break;
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case LBF_BIT32_EXTRACT:
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if (count >= 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number &&
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(count == 2 || args[2].type == Constant::Type_Number))
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{
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uint32_t u = bit32(args[0].valueNumber);
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int f = int(args[1].valueNumber);
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int w = count == 2 ? 1 : int(args[2].valueNumber);
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if (f >= 0 && w > 0 && f + w <= 32)
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{
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uint32_t m = ~(0xfffffffeu << (w - 1));
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return cnum(double((u >> f) & m));
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}
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}
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break;
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case LBF_BIT32_LROTATE:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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{
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uint32_t u = bit32(args[0].valueNumber);
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int s = int(args[1].valueNumber);
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return cnum(double((u << (s & 31)) | (u >> ((32 - s) & 31))));
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}
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break;
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case LBF_BIT32_LSHIFT:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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{
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uint32_t u = bit32(args[0].valueNumber);
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int s = int(args[1].valueNumber);
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if (unsigned(s) < 32)
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return cnum(double(u << s));
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}
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break;
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case LBF_BIT32_REPLACE:
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if (count >= 3 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number && args[2].type == Constant::Type_Number &&
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(count == 3 || args[3].type == Constant::Type_Number))
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{
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uint32_t n = bit32(args[0].valueNumber);
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uint32_t v = bit32(args[1].valueNumber);
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int f = int(args[2].valueNumber);
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int w = count == 3 ? 1 : int(args[3].valueNumber);
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if (f >= 0 && w > 0 && f + w <= 32)
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{
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uint32_t m = ~(0xfffffffeu << (w - 1));
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return cnum(double((n & ~(m << f)) | ((v & m) << f)));
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}
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}
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break;
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case LBF_BIT32_RROTATE:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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{
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uint32_t u = bit32(args[0].valueNumber);
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int s = int(args[1].valueNumber);
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return cnum(double((u >> (s & 31)) | (u << ((32 - s) & 31))));
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}
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break;
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case LBF_BIT32_RSHIFT:
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if (count == 2 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number)
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{
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uint32_t u = bit32(args[0].valueNumber);
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int s = int(args[1].valueNumber);
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if (unsigned(s) < 32)
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return cnum(double(u >> s));
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}
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break;
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case LBF_TYPE:
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if (count == 1 && args[0].type != Constant::Type_Unknown)
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return ctype(args[0]);
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break;
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case LBF_STRING_BYTE:
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if (count == 1 && args[0].type == Constant::Type_String)
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{
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if (args[0].stringLength > 0)
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return cnum(double(uint8_t(args[0].valueString[0])));
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}
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else if (count == 2 && args[0].type == Constant::Type_String && args[1].type == Constant::Type_Number)
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{
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int i = int(args[1].valueNumber);
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if (i > 0 && unsigned(i) <= args[0].stringLength)
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return cnum(double(uint8_t(args[0].valueString[i - 1])));
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}
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break;
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case LBF_STRING_LEN:
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if (count == 1 && args[0].type == Constant::Type_String)
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return cnum(double(args[0].stringLength));
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break;
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case LBF_TYPEOF:
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if (count == 1 && args[0].type != Constant::Type_Unknown)
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return ctype(args[0]);
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break;
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case LBF_MATH_CLAMP:
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if (count == 3 && args[0].type == Constant::Type_Number && args[1].type == Constant::Type_Number && args[2].type == Constant::Type_Number)
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{
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double min = args[1].valueNumber;
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double max = args[2].valueNumber;
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if (min <= max)
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{
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double v = args[0].valueNumber;
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v = v < min ? min : v;
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v = v > max ? max : v;
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return cnum(v);
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}
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}
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break;
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case LBF_MATH_SIGN:
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if (count == 1 && args[0].type == Constant::Type_Number)
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{
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double v = args[0].valueNumber;
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return cnum(v > 0.0 ? 1.0 : v < 0.0 ? -1.0 : 0.0);
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}
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break;
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case LBF_MATH_ROUND:
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if (count == 1 && args[0].type == Constant::Type_Number)
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return cnum(round(args[0].valueNumber));
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break;
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}
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return cvar();
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}
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} // namespace Compile
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} // namespace Luau
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