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mirror of https://github.com/TomHarte/CLK.git synced 2024-11-19 23:32:28 +00:00

Switch Memory to using accessors.

This commit is contained in:
Thomas Harte 2023-11-07 14:03:20 -05:00
parent 91b7d55871
commit 413e7b7de1

View File

@ -98,16 +98,6 @@ struct Memory {
public:
using AccessType = InstructionSet::x86::AccessType;
template <typename IntT, AccessType type> struct ReturnType;
// Reads: return a value directly.
template <typename IntT> struct ReturnType<IntT, AccessType::Read> { using type = IntT; };
template <typename IntT> struct ReturnType<IntT, AccessType::PreauthorisedRead> { using type = IntT; };
// Writes: return a reference.
template <typename IntT> struct ReturnType<IntT, AccessType::Write> { using type = IntT &; };
template <typename IntT> struct ReturnType<IntT, AccessType::ReadModifyWrite> { using type = IntT &; };
// Constructor.
Memory(Registers &registers) : registers_(registers) {
memory.resize(1024*1024);
@ -163,30 +153,13 @@ struct Memory {
// Accesses an address based on segment:offset.
template <typename IntT, AccessType type>
typename ReturnType<IntT, type>::type &access(InstructionSet::x86::Source segment, uint16_t offset) {
if constexpr (std::is_same_v<IntT, uint16_t>) {
// If this is a 16-bit access that runs past the end of the segment, it'll wrap back
// to the start. So the 16-bit value will need to be a local cache.
if(offset == 0xffff) {
write_back_address_[0] = address(segment, offset);
write_back_address_[1] = (write_back_address_[0] - 65535) & 0xf'ffff;
write_back_value_ = memory[write_back_address_[0]] | (memory[write_back_address_[1]] << 8);
return write_back_value_;
}
}
auto &value = access<IntT, type>(segment, offset, Tag::Accessed);
// If the CPU has indicated a write, it should be safe to fuzz the value now.
if(type == AccessType::Write) {
value = IntT(~0);
}
return value;
typename InstructionSet::x86::Accessor<IntT, type>::type access(InstructionSet::x86::Source segment, uint16_t offset) {
return access<IntT, type>(segment, offset, Tag::Accessed);
}
// Accesses an address based on physical location.
template <typename IntT, AccessType type>
typename ReturnType<IntT, type>::type &access(uint32_t address) {
typename InstructionSet::x86::Accessor<IntT, type>::type access(uint32_t address) {
return access<IntT, type>(address, Tag::Accessed);
}
@ -283,42 +256,57 @@ struct Memory {
// Entry point used by the flow controller so that it can mark up locations at which the flags were written,
// so that defined-flag-only masks can be applied while verifying RAM contents.
template <typename IntT, AccessType type>
typename ReturnType<IntT, type>::type &access(InstructionSet::x86::Source segment, uint16_t offset, Tag tag) {
typename InstructionSet::x86::Accessor<IntT, type>::type access(InstructionSet::x86::Source segment, uint16_t offset, Tag tag) {
const uint32_t physical_address = address(segment, offset);
if constexpr (std::is_same_v<IntT, uint16_t>) {
// If this is a 16-bit access that runs past the end of the segment, it'll wrap back
// to the start. So the 16-bit value will need to be a local cache.
if(offset == 0xffff) {
return split_word<type>(physical_address, address(segment, 0), tag);
}
}
return access<IntT, type>(physical_address, tag);
}
// An additional entry point for the flow controller; on the original 8086 interrupt vectors aren't relative
// to a selector, they're just at an absolute location.
template <typename IntT, AccessType type>
typename ReturnType<IntT, type>::type &access(uint32_t address, Tag tag) {
typename InstructionSet::x86::Accessor<IntT, type>::type access(uint32_t address, Tag tag) {
if constexpr (type == AccessType::PreauthorisedRead) {
if(!test_preauthorisation(address)) {
printf("Non preauthorised access\n");
}
}
// Check for address wraparound
if(address > 0x10'0000 - sizeof(IntT)) {
if constexpr (std::is_same_v<IntT, uint8_t>) {
address &= 0xf'ffff;
} else {
address &= 0xf'ffff;
if(address == 0xf'ffff) {
// This is a 16-bit access comprising the final byte in memory and the first.
write_back_address_[0] = address;
write_back_address_[1] = 0;
write_back_value_ = memory[write_back_address_[0]] | (memory[write_back_address_[1]] << 8);
return write_back_value_;
}
}
for(size_t c = 0; c < sizeof(IntT); c++) {
tags[(address + c) & 0xf'ffff] = tag;
}
if(tags.find(address) == tags.end()) {
printf("Access to unexpected RAM address\n");
// Dispense with the single-byte case trivially.
if constexpr (std::is_same_v<IntT, uint8_t>) {
return memory[address];
} else if(address != 0xf'ffff) {
return *reinterpret_cast<IntT *>(&memory[address]);
} else {
return split_word<type>(address, 0, tag);
}
}
template <AccessType type>
typename InstructionSet::x86::Accessor<uint16_t, type>::type
split_word(uint32_t low_address, uint32_t high_address, Tag tag) {
if constexpr (is_writeable(type)) {
write_back_address_[0] = low_address;
write_back_address_[1] = high_address;
tags[low_address] = tag;
tags[high_address] = tag;
write_back_value_ = memory[write_back_address_[0]] | (memory[write_back_address_[1]] << 8);
return write_back_value_;
} else {
return memory[low_address] | (memory[high_address] << 8);
}
tags[address] = tag;
return *reinterpret_cast<IntT *>(&memory[address]);
}
static constexpr uint32_t NoWriteBack = 0; // A low byte address of 0 can't require write-back.