luau/CodeGen/include/Luau/OperandX64.h
vegorov-rbx 140e5a1495
Sync to upstream/release/566 (#853)
* Fixed incorrect lexeme generated for string parts in the middle of an
interpolated string (Fixes https://github.com/Roblox/luau/issues/744)
* DeprecatedApi lint can report some issues without type inference
information
* Fixed performance of autocomplete requests when suggestions have large
intersection types (Solves
https://github.com/Roblox/luau/discussions/847)
* Marked `table.getn`/`foreach`/`foreachi` as deprecated ([RFC:
Deprecate
table.getn/foreach/foreachi](https://github.com/Roblox/luau/blob/master/rfcs/deprecate-table-getn-foreach.md))
* With -O2 optimization level, we now optimize builtin calls based on
known argument/return count.
Note that this change can be observable if `getfenv/setfenv` is used to
substitute a builtin, especially if arity is different.
Fastcall heavy tests show a 1-2% improvement.
* Luau can now be built with clang-cl (Fixes
https://github.com/Roblox/luau/issues/736)

We also made many improvements to our experimental components.

For our new type solver:
* Overhauled data flow analysis system, fixed issues with 'repeat'
loops, global variables and type annotations
* Type refinements now work on generic table indexing with a string
literal
* Type refinements will properly track potentially 'nil' values (like
t[x] for a missing key) and their further refinements
* Internal top table type is now isomorphic to `{}` which fixes issues
when `typeof(v) == 'table'` type refinement is handled
* References to non-existent types in type annotations no longer resolve
to 'error' type like in old solver
* Improved handling of class unions in property access expressions
* Fixed default type packs
* Unsealed tables can now have metatables
* Restored expected types for function arguments

And for native code generation:
* Added min and max IR instructions mapping to vminsd/vmaxsd on x64
* We now speculatively extract direct execution fast-paths based on
expected types of expressions which provides better optimization
opportunities inside a single basic block
* Translated existing math fastcalls to IR form to improve tag guard
removal and constant propagation
2023-03-03 12:21:14 -08:00

145 lines
3.6 KiB
C++

// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
#pragma once
#include "Luau/Common.h"
#include "Luau/RegisterX64.h"
#include <stdint.h>
namespace Luau
{
namespace CodeGen
{
namespace X64
{
enum class CategoryX64 : uint8_t
{
reg,
mem,
imm,
};
struct OperandX64
{
constexpr OperandX64(RegisterX64 reg)
: cat(CategoryX64::reg)
, index(noreg)
, base(reg)
, memSize(SizeX64::none)
, scale(1)
, imm(0)
{
}
constexpr OperandX64(int32_t imm)
: cat(CategoryX64::imm)
, index(noreg)
, base(noreg)
, memSize(SizeX64::none)
, scale(1)
, imm(imm)
{
}
constexpr explicit OperandX64(SizeX64 size, RegisterX64 index, uint8_t scale, RegisterX64 base, int32_t disp)
: cat(CategoryX64::mem)
, index(index)
, base(base)
, memSize(size)
, scale(scale)
, imm(disp)
{
}
// Fields are carefully placed to make this struct fit into an 8 byte register
CategoryX64 cat;
RegisterX64 index;
RegisterX64 base;
SizeX64 memSize : 4;
uint8_t scale : 4;
int32_t imm;
constexpr OperandX64 operator[](OperandX64&& addr) const
{
LUAU_ASSERT(cat == CategoryX64::mem);
LUAU_ASSERT(index == noreg && scale == 1 && base == noreg && imm == 0);
LUAU_ASSERT(addr.memSize == SizeX64::none);
addr.cat = CategoryX64::mem;
addr.memSize = memSize;
return addr;
}
};
constexpr OperandX64 addr{SizeX64::none, noreg, 1, noreg, 0};
constexpr OperandX64 byte{SizeX64::byte, noreg, 1, noreg, 0};
constexpr OperandX64 word{SizeX64::word, noreg, 1, noreg, 0};
constexpr OperandX64 dword{SizeX64::dword, noreg, 1, noreg, 0};
constexpr OperandX64 qword{SizeX64::qword, noreg, 1, noreg, 0};
constexpr OperandX64 xmmword{SizeX64::xmmword, noreg, 1, noreg, 0};
constexpr OperandX64 ymmword{SizeX64::ymmword, noreg, 1, noreg, 0};
constexpr OperandX64 operator*(RegisterX64 reg, uint8_t scale)
{
if (scale == 1)
return OperandX64(reg);
LUAU_ASSERT(scale == 1 || scale == 2 || scale == 4 || scale == 8);
LUAU_ASSERT(reg.index != 0b100 && "can't scale SP");
return OperandX64(SizeX64::none, reg, scale, noreg, 0);
}
constexpr OperandX64 operator+(RegisterX64 reg, int32_t disp)
{
return OperandX64(SizeX64::none, noreg, 1, reg, disp);
}
constexpr OperandX64 operator-(RegisterX64 reg, int32_t disp)
{
return OperandX64(SizeX64::none, noreg, 1, reg, -disp);
}
constexpr OperandX64 operator+(RegisterX64 base, RegisterX64 index)
{
LUAU_ASSERT(index.index != 4 && "sp cannot be used as index");
LUAU_ASSERT(base.size == index.size);
return OperandX64(SizeX64::none, index, 1, base, 0);
}
constexpr OperandX64 operator+(OperandX64 op, int32_t disp)
{
LUAU_ASSERT(op.cat == CategoryX64::mem);
LUAU_ASSERT(op.memSize == SizeX64::none);
op.imm += disp;
return op;
}
constexpr OperandX64 operator+(OperandX64 op, RegisterX64 base)
{
LUAU_ASSERT(op.cat == CategoryX64::mem);
LUAU_ASSERT(op.memSize == SizeX64::none);
LUAU_ASSERT(op.base == noreg);
LUAU_ASSERT(op.index == noreg || op.index.size == base.size);
op.base = base;
return op;
}
constexpr OperandX64 operator+(RegisterX64 base, OperandX64 op)
{
LUAU_ASSERT(op.cat == CategoryX64::mem);
LUAU_ASSERT(op.memSize == SizeX64::none);
LUAU_ASSERT(op.base == noreg);
LUAU_ASSERT(op.index == noreg || op.index.size == base.size);
op.base = base;
return op;
}
} // namespace X64
} // namespace CodeGen
} // namespace Luau