mirror of
https://github.com/LadybirdBrowser/ladybird.git
synced 2024-11-21 15:10:19 +00:00
f87041bf3a
Resulting in a massive rename across almost everywhere! Alongside the namespace change, we now have the following names: * JS::NonnullGCPtr -> GC::Ref * JS::GCPtr -> GC::Ptr * JS::HeapFunction -> GC::Function * JS::CellImpl -> GC::Cell * JS::Handle -> GC::Root
120 lines
4.8 KiB
C++
120 lines
4.8 KiB
C++
/*
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* Copyright (c) 2024, Shannon Booth <shannon@serenityos.org>
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*
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* SPDX-License-Identifier: BSD-2-Clause
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*/
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#pragma once
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#include <AK/BitCast.h>
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#include <AK/Types.h>
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#include <LibGC/Cell.h>
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namespace GC {
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static_assert(sizeof(double) == 8);
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static_assert(sizeof(void*) == sizeof(double) || sizeof(void*) == sizeof(u32));
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// To make our Value representation compact we can use the fact that IEEE
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// doubles have a lot (2^52 - 2) of NaN bit patterns. The canonical form being
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// just 0x7FF8000000000000 i.e. sign = 0 exponent is all ones and the top most
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// bit of the mantissa set.
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static constexpr u64 CANON_NAN_BITS = bit_cast<u64>(__builtin_nan(""));
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static_assert(CANON_NAN_BITS == 0x7FF8000000000000);
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// (Unfortunately all the other values are valid so we have to convert any
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// incoming NaNs to this pattern although in practice it seems only the negative
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// version of these CANON_NAN_BITS)
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// +/- Infinity are represented by a full exponent but without any bits of the
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// mantissa set.
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static constexpr u64 POSITIVE_INFINITY_BITS = bit_cast<u64>(__builtin_huge_val());
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static constexpr u64 NEGATIVE_INFINITY_BITS = bit_cast<u64>(-__builtin_huge_val());
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static_assert(POSITIVE_INFINITY_BITS == 0x7FF0000000000000);
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static_assert(NEGATIVE_INFINITY_BITS == 0xFFF0000000000000);
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// However as long as any bit is set in the mantissa with the exponent of all
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// ones this value is a NaN, and it even ignores the sign bit.
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// (NOTE: we have to use __builtin_isnan here since some isnan implementations are not constexpr)
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static_assert(__builtin_isnan(bit_cast<double>(0x7FF0000000000001)));
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static_assert(__builtin_isnan(bit_cast<double>(0xFFF0000000040000)));
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// This means we can use all of these NaNs to store all other options for Value.
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// To make sure all of these other representations we use 0x7FF8 as the base top
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// 2 bytes which ensures the value is always a NaN.
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static constexpr u64 BASE_TAG = 0x7FF8;
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// This leaves the sign bit and the three lower bits for tagging a value and then
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// 48 bits of potential payload.
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// First the pointer backed types (Object, String etc.), to signify this category
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// and make stack scanning easier we use the sign bit (top most bit) of 1 to
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// signify that it is a pointer backed type.
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static constexpr u64 IS_CELL_BIT = 0x8000 | BASE_TAG;
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// On all current 64-bit systems this code runs pointer actually only use the
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// lowest 6 bytes which fits neatly into our NaN payload with the top two bytes
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// left over for marking it as a NaN and tagging the type.
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// Note that we do need to take care when extracting the pointer value but this
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// is explained in the extract_pointer method.
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static constexpr u64 IS_CELL_PATTERN = 0xFFF8ULL;
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static constexpr u64 TAG_SHIFT = 48;
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static constexpr u64 TAG_EXTRACTION = 0xFFFF000000000000;
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static constexpr u64 SHIFTED_IS_CELL_PATTERN = IS_CELL_PATTERN << TAG_SHIFT;
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class NanBoxedValue {
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public:
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bool is_cell() const { return (m_value.tag & IS_CELL_PATTERN) == IS_CELL_PATTERN; }
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static constexpr FlatPtr extract_pointer_bits(u64 encoded)
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{
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#ifdef AK_ARCH_32_BIT
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// For 32-bit system the pointer fully fits so we can just return it directly.
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static_assert(sizeof(void*) == sizeof(u32));
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return static_cast<FlatPtr>(encoded & 0xffff'ffff);
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#elif ARCH(X86_64) || ARCH(RISCV64)
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// For x86_64 and riscv64 the top 16 bits should be sign extending the "real" top bit (47th).
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// So first shift the top 16 bits away then using the right shift it sign extends the top 16 bits.
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return static_cast<FlatPtr>((static_cast<i64>(encoded << 16)) >> 16);
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#elif ARCH(AARCH64) || ARCH(PPC64) || ARCH(PPC64LE)
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// For AArch64 the top 16 bits of the pointer should be zero.
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// For PPC64: all 64 bits can be used for pointers, however on Linux only
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// the lower 43 bits are used for user-space addresses, so
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// masking off the top 16 bits should match the rest of LibGC.
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return static_cast<FlatPtr>(encoded & 0xffff'ffff'ffffULL);
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#else
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# error "Unknown architecture. Don't know whether pointers need to be sign-extended."
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#endif
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}
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template<typename PointerType>
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PointerType* extract_pointer() const
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{
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VERIFY(is_cell());
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return reinterpret_cast<PointerType*>(extract_pointer_bits(m_value.encoded));
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}
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Cell& as_cell()
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{
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VERIFY(is_cell());
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return *extract_pointer<Cell>();
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}
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Cell& as_cell() const
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{
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VERIFY(is_cell());
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return *extract_pointer<Cell>();
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}
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bool is_nan() const
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{
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return m_value.encoded == CANON_NAN_BITS;
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}
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protected:
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union {
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double as_double;
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struct {
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u64 payload : 48;
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u64 tag : 16;
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};
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u64 encoded;
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} m_value { .encoded = 0 };
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};
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static_assert(sizeof(NanBoxedValue) == sizeof(double));
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}
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