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natto1784:master natto1784:thumb natto1784:tests natto1784:build-system natto1784:test-public-api
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compare: natto1784:tests
Branches Tags
natto1784:master natto1784:thumb natto1784:tests natto1784:build-system natto1784:test-public-api

18 Commits
0b674c7c64 ... tests

Author SHA1 Message Date
Amneesh Singh
ed01ed80cd tests: add tests for memory 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-24 18:04:28 +05:30
Amneesh Singh
8e26cadc9a chore: revert util/crypto 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-24 17:45:19 +05:30
Amneesh Singh
6e56828dfd tests/arm/exec: test conditions 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-24 17:38:11 +05:30
Amneesh Singh
5fcc75bc9a tests: add tests for internal utilities 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-24 17:36:38 +05:30
Amneesh Singh
560bd5bfa1 tests: add tests for bus 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-23 23:20:05 +05:30
Amneesh Singh
9cdfa90acc memory: remove unused functions 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-23 21:58:41 +05:30
Amneesh Singh
91a82eec7c log: encapsulate logger 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-23 21:09:44 +05:30
Amneesh Singh
c3bf8b0ae8 nix: add support to build with GCC 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-23 16:07:05 +05:30
Amneesh Singh
6c33c77ef3 restructure: get rid of cpu/utility 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-23 14:15:23 +05:30
Amneesh Singh
1e8966553f chore: enclose everything in namespace matar 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-21 10:52:40 +05:30
Amneesh Singh
1eb4a9545b tests: complete exec tests (for now) 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-19 08:58:11 +05:30
Amneesh Singh
fa96a4d09f tests: add execution tests 
all but data processing

Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-18 18:23:52 +05:30
Amneesh Singh
dd9dd5f116 tests: complete disassembler tests 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-17 09:50:32 +05:30
Amneesh Singh
be7deb349a tests: [WIP] add unit tests for some of the instructions 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-15 14:07:23 +05:30
Amneesh Singh
aa96237c37 shifts are always immediate in single data transfer 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-15 10:24:23 +05:30
Amneesh Singh
7fc6876264 [UNTESTED] complete initial disassembler structure for ARM 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-15 05:23:07 +05:30
Amneesh Singh
169723275e replace symlinks 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-14 11:25:44 +05:30
Amneesh Singh
81afd67e0b delete symlinks 
Signed-off-by: Amneesh Singh <natto@weirdnatto.in>
 2023-09-14 11:14:36 +05:30
66 changed files with 4166 additions and 1444 deletions
Expand all files Collapse all files

2
.clang-tidy
View File

@@ -5,4 +5,6 @@ Checks: '
, -cppcoreguidelines-pro-bounds-constant-array-index
, -cppcoreguidelines-macro-usage
, -cppcoreguidelines-avoid-const-or-ref-data-members
, -cppcoreguidelines-non-private-member-variables-in-classes
, -cppcoreguidelines-avoid-non-const-global-variables
'

36
.github/workflows/clang.yml vendored Normal file
View File

@@ -0,0 +1,36 @@
name: matar-clang
on: [push, pull_request, workflow_dispatch]
env:
BUILDDIR: build
jobs:
build:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v3
- uses: cachix/install-nix-action@v20
with:
extra_nix_config: |
auto-optimise-store = true
experimental-features = nix-command flakes
- uses: cachix/cachix-action@v12
with:
name: pain
authToken: '${{ secrets.CACHIX_AUTH_TOKEN }}'
- name: setup
run: nix develop .#matar-clang -c meson setup $BUILDDIR
- name: fmt
run: nix develop .#matar-clang -c ninja clang-format-check -C $BUILDDIR
- name: lint
run: nix develop .#matar-clang -c ninja clang-tidy -C $BUILDDIR
- name: tests
run: nix develop .#matar-clang -c ninja test -C $BUILDDIR
- name: build
run: nix develop .#matar-clang -c ninja -C $BUILDDIR

30
.github/workflows/gcc.yml vendored Normal file
View File

@@ -0,0 +1,30 @@
name: matar-gcc
on: [push, pull_request, workflow_dispatch]
env:
BUILDDIR: build
jobs:
build:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v3
- uses: cachix/install-nix-action@v20
with:
extra_nix_config: |
auto-optimise-store = true
experimental-features = nix-command flakes
- uses: cachix/cachix-action@v12
with:
name: pain
authToken: '${{ secrets.CACHIX_AUTH_TOKEN }}'
- name: setup
run: nix develop .#matar -c meson setup $BUILDDIR
- name: tests
run: nix develop .#matar -c ninja test -C $BUILDDIR
- name: build
run: nix develop .#matar -c ninja -C $BUILDDIR

28
.github/workflows/main.yml vendored
View File

@@ -1,28 +0,0 @@
name: matar
on: [push, pull_request, workflow_dispatch]
env:
BUILDDIR: build
jobs:
build:
runs-on: ubuntu-latest
steps:
- uses: actions/checkout@v3
- uses: cachix/install-nix-action@v20
with:
extra_nix_config: |
auto-optimise-store = true
experimental-features = nix-command flakes
- name: meson build
run: nix develop -c meson setup $BUILDDIR
- name: clang-format check
run: nix develop -c ninja clang-format-check -C $BUILDDIR
- name: clang-tidy check
run: nix develop -c ninja clang-tidy -C $BUILDDIR
- name: ninja compile
run: nix develop -c ninja -C $BUILDDIR

1
README
View File

@@ -1 +0,0 @@
nothing to be seen here yet. LEAVE

22
README.md Normal file
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@@ -0,0 +1,22 @@
nothing to be seen here yet. LEAVE
But if you are curious (probably not), read ahead
# Dependencies
## Tested toolchains
- LLVM 16.0.6
- GCC 12.3.0
In theory, any toolchain supporting at least the C++20 standard should work.
I am using LLVM's clang and libcxx as the primary toolchain.
## Static libraries
| Name | Version | Required? |
|:------:|:----------|:---------:|
| fmt | >= 10.1.1 | yes |
| catch2 | >= 3.4 | for tests |
This goes without saying but using a different toolchain to compile these libraries before linking probably won't work.
I will add meson wrap support once LLVM 17 is out, since I want to get rid of fmt.

25
apps/target/main.cc
View File

@@ -1,11 +1,13 @@
#include "bus.hh"
#include "cpu/cpu.hh"
#include "memory.hh"
#include "util/loglevel.hh"
#include <array>
#include <cstdlib>
#include <fstream>
#include <iostream>
#include <memory>
#include <ostream>
#include <unistd.h>
#include <vector>
@@ -14,7 +16,7 @@
int
main(int argc, const char* argv[]) {
std::vector<uint8_t> rom;
std::array<uint8_t, Memory::BIOS_SIZE> bios = { 0 };
std::array<uint8_t, matar::Memory::BIOS_SIZE> bios = { 0 };
auto usage = [argv]() {
std::cerr << "Usage: " << argv[0] << " <file> [-b <bios>]" << std::endl;
@@ -64,7 +66,7 @@ main(int argc, const char* argv[]) {
ifile.seekg(0, std::ios::end);
bios_size = ifile.tellg();
if (bios_size != Memory::BIOS_SIZE) {
if (bios_size != matar::Memory::BIOS_SIZE) {
throw std::ios::failure("BIOS file has invalid size",
std::error_code());
}
@@ -80,15 +82,24 @@ main(int argc, const char* argv[]) {
return 1;
}
{
Memory memory(std::move(bios), std::move(rom));
Bus bus(memory);
Cpu cpu(bus);
std::flush(std::cout);
std::flush(std::cout);
matar::set_log_level(matar::LogLevel::Debug);
try {
matar::Memory memory(std::move(bios), std::move(rom));
matar::Bus bus(memory);
matar::Cpu cpu(bus);
while (true) {
cpu.step();
sleep(1);
sleep(2);
}
} catch (const std::exception& e) {
std::cerr << "Exception: " << e.what() << std::endl;
return 1;
}
return 0;
}

2
apps/target/meson.build
View File

@@ -7,7 +7,7 @@ target_sources = files(
)
executable(
meson.project_name(),
'matar',
target_sources,
link_with: target_deps,
include_directories: inc,

43
flake.lock generated
View File

@@ -1,12 +1,30 @@
{
"nodes": {
"flake-parts": {
"inputs": {
"nixpkgs-lib": "nixpkgs-lib"
},
"locked": {
"lastModified": 1693611461,
"narHash": "sha256-aPODl8vAgGQ0ZYFIRisxYG5MOGSkIczvu2Cd8Gb9+1Y=",
"owner": "hercules-ci",
"repo": "flake-parts",
"rev": "7f53fdb7bdc5bb237da7fefef12d099e4fd611ca",
"type": "github"
},
"original": {
"owner": "hercules-ci",
"repo": "flake-parts",
"type": "github"
}
},
"nixpkgs": {
"locked": {
"lastModified": 1692007866,
"narHash": "sha256-X8w0vPZjZxMm68VCwh/BHDoKRGp+BgzQ6w7Nkif6IVM=",
"lastModified": 1695318763,
"narHash": "sha256-FHVPDRP2AfvsxAdc+AsgFJevMz5VBmnZglFUMlxBkcY=",
"owner": "nixos",
"repo": "nixpkgs",
"rev": "de2b8ddf94d6cc6161b7659649594c79bd66c13b",
"rev": "e12483116b3b51a185a33a272bf351e357ba9a99",
"type": "github"
},
"original": {
@@ -16,8 +34,27 @@
"type": "github"
}
},
"nixpkgs-lib": {
"locked": {
"dir": "lib",
"lastModified": 1693471703,
"narHash": "sha256-0l03ZBL8P1P6z8MaSDS/MvuU8E75rVxe5eE1N6gxeTo=",
"owner": "NixOS",
"repo": "nixpkgs",
"rev": "3e52e76b70d5508f3cec70b882a29199f4d1ee85",
"type": "github"
},
"original": {
"dir": "lib",
"owner": "NixOS",
"ref": "nixos-unstable",
"repo": "nixpkgs",
"type": "github"
}
},
"root": {
"inputs": {
"flake-parts": "flake-parts",
"nixpkgs": "nixpkgs"
}
}

71
flake.nix
View File

@@ -1,63 +1,40 @@
{
description = "matar";
inputs = {
nixpkgs.url = github:nixos/nixpkgs/nixpkgs-unstable;
flake-parts.url = github:hercules-ci/flake-parts;
};
outputs = { self, nixpkgs }:
let
outputs = inputs@{ self, nixpkgs, flake-parts }:
flake-parts.lib.mkFlake { inherit inputs; } {
systems = [
"x86_64-linux"
"aarch64-linux"
# "i686-linux"
];
eachSystem = with nixpkgs.lib; f: foldAttrs mergeAttrs { }
(map (s: mapAttrs (_: v: { ${s} = v; }) (f s)) systems);
in
eachSystem (system:
let
pkgs = import nixpkgs { inherit system; };
llvm = pkgs.llvmPackages_16;
stdenv = llvm.libcxxStdenv;
nativeBuildInputs = with pkgs; [
meson
ninja
imports = [
./nix
];
# libraries
pkg-config
fmt.dev
];
in
rec {
packages = rec {
matar = stdenv.mkDerivation rec {
name = "matar";
version = "0.1";
src = pkgs.lib.sourceFilesBySuffices ./. [
".hh"
".cc"
".build"
];
outputs = [ "out" "dev" ];
perSystem = { self', system, ... }:
let
pkgs = import nixpkgs { inherit system; };
inherit nativeBuildInputs;
enableParallelBuilding = true;
src = pkgs.lib.sourceFilesBySuffices ./. [
".hh"
".cc"
".build"
"meson_options.txt"
];
in
rec {
_module.args = {
inherit src pkgs;
};
default = matar;
};
devShells = rec {
matar = pkgs.mkShell.override { inherit stdenv; } {
name = "matar";
packages = nativeBuildInputs ++ (with pkgs; [
# dev tools
clang-tools_16
]);
};
default = matar;
formatter = pkgs.nixpkgs-fmt;
};
formatter = pkgs.nixpkgs-fmt;
});
};
}

1
include/bus.hh
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@@ -1 +0,0 @@
../src/bus.hh

23
include/bus.hh Normal file
View File

@@ -0,0 +1,23 @@
#pragma once
#include "memory.hh"
#include <memory>
namespace matar {
class Bus {
public:
Bus(const Memory& memory);
uint8_t read_byte(size_t address);
void write_byte(size_t address, uint8_t byte);
uint16_t read_halfword(size_t address);
void write_halfword(size_t address, uint16_t halfword);
uint32_t read_word(size_t address);
void write_word(size_t address, uint32_t word);
private:
std::shared_ptr<Memory> memory;
};
}

1
include/cpu/cpu.hh
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@@ -1 +0,0 @@
../../src/cpu/cpu.hh

21
include/cpu/cpu.hh Normal file
View File

@@ -0,0 +1,21 @@
#include "bus.hh"
namespace matar {
class CpuImpl;
class Cpu {
public:
Cpu(const Bus& bus) noexcept;
Cpu(const Cpu&) = delete;
Cpu(Cpu&&) = delete;
Cpu& operator=(const Cpu&) = delete;
Cpu& operator=(Cpu&&) = delete;
~Cpu();
void step();
private:
std::unique_ptr<CpuImpl> impl;
};
}

1
include/cpu/instruction.hh
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@@ -1 +0,0 @@
../../src/cpu/instruction.hh

3
include/cpu/meson.build
View File

@@ -1,6 +1,3 @@
headers += files(
'cpu.hh',
'instruction.hh',
'psr.hh',
'utility.hh'
)

1
include/cpu/psr.hh
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@@ -1 +0,0 @@
../../src/cpu/psr.hh

1
include/cpu/utility.hh
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@@ -1 +0,0 @@
../../src/cpu/utility.hh

1
include/header.hh
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@@ -1 +0,0 @@
../src/header.hh

48
include/header.hh Normal file
View File

@@ -0,0 +1,48 @@
#pragma once
#include <cstdint>
#include <string>
namespace matar {
struct Header {
static constexpr uint8_t HEADER_SIZE = 192;
enum class UniqueCode {
Old, // old games
New, // new games
Newer, // unused (newer games)
Famicom, // NES
YoshiKoro, // acceleration sensor
Ereader, // dot code scanner
Warioware, // rumble and z-axis gyro
Boktai, // RTC and solar sensor
DrillDozer, // rumble
};
enum class I18n {
Japan,
Europe,
French,
Spanish,
Usa,
German,
Italian
};
enum class BootMode {
Joybus,
Normal,
Multiplay
};
uint32_t entrypoint;
std::string title;
std::string title_code;
UniqueCode unique_code;
I18n i18n;
uint8_t version;
BootMode multiboot;
uint32_t multiboot_entrypoint;
uint8_t slave_id;
};
}

1
include/memory.hh
View File

@@ -1 +0,0 @@
../src/memory.hh

61
include/memory.hh Normal file
View File

@@ -0,0 +1,61 @@
#pragma once
#include "header.hh"
#include <array>
#include <cstddef>
#include <cstdint>
#include <unordered_map>
#include <vector>
namespace matar {
class Memory {
public:
static constexpr size_t BIOS_SIZE = 1024 * 16;
Memory(std::array<uint8_t, BIOS_SIZE>&& bios, std::vector<uint8_t>&& rom);
uint8_t read(size_t address) const;
void write(size_t address, uint8_t byte);
private:
#define MEMORY_REGION(name, start, end) \
static constexpr size_t name##_START = start; \
static constexpr size_t name##_END = end;
#define DECL_MEMORY(name, ident, start, end) \
MEMORY_REGION(name, start, end) \
std::array<uint8_t, name##_END - name##_START + 1> ident;
MEMORY_REGION(BIOS, 0x00000000, 0x00003FFF)
std::array<uint8_t, BIOS_SIZE> bios;
static_assert(BIOS_END - BIOS_START + 1 == BIOS_SIZE);
// board working RAM
DECL_MEMORY(BOARD_WRAM, board_wram, 0x02000000, 0x0203FFFF)
// chip working RAM
DECL_MEMORY(CHIP_WRAM, chip_wram, 0x03000000, 0x03007FFF)
// palette RAM
DECL_MEMORY(PALETTE_RAM, palette_ram, 0x05000000, 0x050003FF)
// video RAM
DECL_MEMORY(VRAM, vram, 0x06000000, 0x06017FFF)
// OAM OBJ attributes
DECL_MEMORY(OAM_OBJ_ATTR, oam_obj_attr, 0x07000000, 0x070003FF)
#undef DECL_MEMORY
MEMORY_REGION(ROM_0, 0x08000000, 0x09FFFFFF)
MEMORY_REGION(ROM_1, 0x0A000000, 0x0BFFFFFF)
MEMORY_REGION(ROM_2, 0x0C000000, 0x0DFFFFFF)
#undef MEMORY_REGION
std::unordered_map<size_t, uint8_t> invalid_mem;
std::vector<uint8_t> rom;
Header header;
void parse_header();
};
}

3
include/meson.build
View File

@@ -4,6 +4,9 @@ headers = files(
'header.hh',
)
inc = include_directories('.')
subdir('cpu')
subdir('util')
install_headers(headers, subdir: meson.project_name(), preserve_path: true)

14
include/util/loglevel.hh Normal file
View File

@@ -0,0 +1,14 @@
#pragma once
namespace matar {
enum class LogLevel {
Off = 1 << 0,
Error = 1 << 1,
Warn = 1 << 2,
Info = 1 << 3,
Debug = 1 << 4
};
void
set_log_level(LogLevel level);
}

3
include/util/meson.build Normal file
View File

@@ -0,0 +1,3 @@
headers += files(
'loglevel.hh'
)

32
meson.build
View File

@@ -4,9 +4,37 @@ project('matar', 'cpp',
default_options : ['warning_level=3',
'werror=true',
'optimization=3',
'cpp_std=c++20'])
'cpp_std=c++20',
'default_library=static'])
compiler = meson.get_compiler('cpp')
'''
TODO: use <print> and <format> instead of libfmt once LLVM 17 is out
if compiler.has_argument('-std=c++2c')
add_global_arguments('-std=c++2c', language: 'cpp')
elif compiler.has_argument('-std=c++23')
add_global_arguments('-std=c++23', language: 'cpp')
elif compiler.has_argument('-std=c++2b')
add_global_arguments('-std=c++2b', language: 'cpp')
elif compiler.has_argument('-std=c++20')
add_global_arguments('-std=c++20', language: 'cpp')
else
error(compiler.get_id() + ' ' + compiler.version() + 'does not meet the compiler requirements')
endif
if compiler.has_argument('-fexperimental-library')
add_global_arguments('-fexperimental-library', language: 'cpp')
else
error(compiler.get_id() + ' ' + compiler.version() + 'does not support -fexperimental-library')
endif
'''
inc = include_directories('include')
subdir('include')
subdir('src')
subdir('apps')
if get_option('tests')
subdir('tests')
endif

1
meson_options.txt Normal file
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@@ -0,0 +1 @@
option('tests', type : 'boolean', value : true, description: 'enable tests')

23
nix/build.nix Normal file
View File

@@ -0,0 +1,23 @@
{ stdenv
, meson
, ninja
, pkg-config
, src ? "../."
, libraries ? [ ]
}:
stdenv.mkDerivation {
name = "matar";
version = "0.1";
inherit src;
outputs = [ "out" "dev" ];
nativeBuildInputs = [
meson
ninja
pkg-config
] ++ libraries;
enableParallelBuilding = true;
}

11
nix/default.nix Normal file
View File

@@ -0,0 +1,11 @@
{ ... }: {
imports = [
./matar.nix
./matar-clang.nix
];
perSystem = { self', pkgs, ... }: {
packages.default = self'.packages.matar-clang;
devShells.default = self'.devShells.matar-clang;
};
}

25
nix/matar-clang.nix Normal file
View File

@@ -0,0 +1,25 @@
{ ... }: {
perSystem = { pkgs, src, ... }:
let
llvm = pkgs.llvmPackages_16;
stdenv = llvm.libcxxStdenv;
libraries = with pkgs; [
((pkgs.fmt.override {
inherit stdenv;
enableShared = false;
}).overrideAttrs (oa: {
cmakeFlags = oa.cmakeFlags ++ [ "-DFMT_TEST=off" ];
})).dev
(catch2_3.override { inherit stdenv; }).out
];
in
{
packages.matar-clang = pkgs.callPackage ./build.nix { inherit src libraries stdenv; };
devShells.matar-clang = pkgs.callPackage ./shell.nix {
inherit libraries stdenv;
tools = with pkgs; [ clang-tools_16 ];
};
};
}

13
nix/matar.nix Normal file
View File

@@ -0,0 +1,13 @@
{ ... }: {
perSystem = { pkgs, src, ... }:
let
libraries = with pkgs; [
(pkgs.fmt.override { enableShared = false; }).dev
catch2_3.out
];
in
{
packages.matar = pkgs.callPackage ./build.nix { inherit src libraries; };
devShells.matar = pkgs.callPackage ./shell.nix { inherit libraries; };
};
}

20
nix/shell.nix Normal file
View File

@@ -0,0 +1,20 @@
{ stdenv
, mkShell
, meson
, ninja
, pkg-config
, libraries ? [ ]
, tools ? [ ]
}:
mkShell.override { inherit stdenv; } {
name = "matar";
packages = [
meson
ninja
pkg-config
] ++ libraries ++ tools;
enableParallelBuilding = true;
}

30
src/bus.cc
View File

@@ -1,7 +1,9 @@
#include "bus.hh"
#include "util/log.hh"
#include <memory>
Bus::Bus(Memory& memory)
namespace matar {
Bus::Bus(const Memory& memory)
: memory(std::make_shared<Memory>(memory)) {}
uint8_t
@@ -16,20 +18,38 @@ Bus::write_byte(size_t address, uint8_t byte) {
uint16_t
Bus::read_halfword(size_t address) {
return memory->read_halfword(address);
if (address & 0b01)
glogger.warn("Reading a non aligned halfword address");
return memory->read(address) | memory->read(address + 1) << 8;
}
void
Bus::write_halfword(size_t address, uint16_t halfword) {
memory->write_halfword(address, halfword);
if (address & 0b01)
glogger.warn("Writing to a non aligned halfword address");
memory->write(address, halfword & 0xFF);
memory->write(address + 1, halfword >> 8 & 0xFF);
}
uint32_t
Bus::read_word(size_t address) {
return memory->read_word(address);
if (address & 0b11)
glogger.warn("Reading a non aligned word address");
return memory->read(address) | memory->read(address + 1) << 8 |
memory->read(address + 2) << 16 | memory->read(address + 3) << 24;
}
void
Bus::write_word(size_t address, uint32_t word) {
memory->write_halfword(address, word);
if (address & 0b11)
glogger.warn("Writing to a non aligned word address");
memory->write(address, word & 0xFF);
memory->write(address + 1, word >> 8 & 0xFF);
memory->write(address + 2, word >> 16 & 0xFF);
memory->write(address + 3, word >> 24 & 0xFF);
}
}

21
src/bus.hh
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#pragma once
#include "memory.hh"
#include <memory>
class Bus {
public:
Bus(Memory& memory);
uint8_t read_byte(size_t address);
void write_byte(size_t address, uint8_t byte);
uint16_t read_halfword(size_t address);
void write_halfword(size_t address, uint16_t halfword);
uint32_t read_word(size_t address);
void write_word(size_t address, uint32_t word);
private:
std::shared_ptr<Memory> memory;
};

71
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#include "alu.hh"
#include "util/bits.hh"
namespace matar {
uint32_t
eval_shift(ShiftType shift_type, uint32_t value, uint8_t amount, bool& carry) {
uint32_t eval = 0;
switch (shift_type) {
case ShiftType::LSL:
if (amount > 0 && amount <= 32)
carry = get_bit(value, 32 - amount);
else if (amount > 32)
carry = 0;
eval = value << amount;
break;
case ShiftType::LSR:
if (amount > 0 && amount <= 32)
carry = get_bit(value, amount - 1);
else if (amount > 32)
carry = 0;
else
carry = get_bit(value, 31);
eval = value >> amount;
break;
case ShiftType::ASR:
if (amount > 0 && amount <= 32)
carry = get_bit(value, amount - 1);
else
carry = get_bit(value, 31);
return static_cast<int32_t>(value) >> amount;
break;
case ShiftType::ROR:
if (amount == 0) {
eval = (value >> 1) | (carry << 31);
carry = get_bit(value, 0);
} else {
eval = std::rotr(value, amount);
carry = get_bit(value, (amount % 32 + 31) % 32);
}
break;
}
return eval;
}
std::ostream&
operator<<(std::ostream& os, const ShiftType shift_type) {
#define CASE(type) \
case ShiftType::type: \
os << #type; \
break;
switch (shift_type) {
CASE(LSL)
CASE(LSR)
CASE(ASR)
CASE(ROR)
}
#undef CASE
return os;
}
}

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#pragma once
#include <cstdint>
#include <fmt/ostream.h>
namespace matar {
enum class ShiftType {
LSL = 0b00,
LSR = 0b01,
ASR = 0b10,
ROR = 0b11
};
struct ShiftData {
ShiftType type;
bool immediate;
uint8_t operand;
};
struct Shift {
uint8_t rm;
ShiftData data;
};
uint32_t
eval_shift(ShiftType shift_type, uint32_t value, uint8_t amount, bool& carry);
// https://fmt.dev/dev/api.html#std-ostream-support
std::ostream&
operator<<(std::ostream& os, const ShiftType cond);
}
namespace fmt {
template<>
struct formatter<matar::ShiftType> : ostream_formatter {};
}

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#include "cpu/cpu-impl.hh"
#include "util/bits.hh"
#include "util/log.hh"
namespace matar {
void
CpuImpl::exec_arm(const arm::Instruction instruction) {
Condition cond = instruction.condition;
arm::InstructionData data = instruction.data;
if (!cpsr.condition(cond)) {
return;
}
auto pc_error = [](uint8_t r) {
if (r == PC_INDEX)
glogger.error("Using PC (R15) as operand register");
};
auto pc_warn = [](uint8_t r) {
if (r == PC_INDEX)
glogger.warn("Using PC (R15) as operand register");
};
using namespace arm;
std::visit(
overloaded{
[this, pc_warn](BranchAndExchange& data) {
State state = static_cast<State>(data.rn & 1);
pc_warn(data.rn);
// set state
cpsr.set_state(state);
// copy to PC
pc = gpr[data.rn];
// ignore [1:0] bits for arm and 0 bit for thumb
rst_bit(pc, 0);
if (state == State::Arm)
rst_bit(pc, 1);
// pc is affected so flush the pipeline
is_flushed = true;
},
[this](Branch& data) {
if (data.link)
gpr[14] = pc - INSTRUCTION_SIZE;
// data.offset accounts for two instructions ahead when
// disassembling, so need to adjust
pc = static_cast<int32_t>(pc) - 2 * INSTRUCTION_SIZE + data.offset;
// pc is affected so flush the pipeline
is_flushed = true;
},
[this, pc_error](Multiply& data) {
if (data.rd == data.rm)
glogger.error("rd and rm are not distinct in {}",
typeid(data).name());
pc_error(data.rd);
pc_error(data.rd);
pc_error(data.rd);
gpr[data.rd] =
gpr[data.rm] * gpr[data.rs] + (data.acc ? gpr[data.rn] : 0);
if (data.set) {
cpsr.set_z(gpr[data.rd] == 0);
cpsr.set_n(get_bit(gpr[data.rd], 31));
cpsr.set_c(0);
}
},
[this, pc_error](MultiplyLong& data) {
if (data.rdhi == data.rdlo || data.rdhi == data.rm ||
data.rdlo == data.rm)
glogger.error("rdhi, rdlo and rm are not distinct in {}",
typeid(data).name());
pc_error(data.rdhi);
pc_error(data.rdlo);
pc_error(data.rm);
pc_error(data.rs);
if (data.uns) {
auto cast = [](uint32_t x) -> uint64_t {
return static_cast<uint64_t>(x);
};
uint64_t eval = cast(gpr[data.rm]) * cast(gpr[data.rs]) +
(data.acc ? (cast(gpr[data.rdhi]) << 32) |
cast(gpr[data.rdlo])
: 0);
gpr[data.rdlo] = bit_range(eval, 0, 31);
gpr[data.rdhi] = bit_range(eval, 32, 63);
} else {
auto cast = [](uint32_t x) -> int64_t {
return static_cast<int64_t>(static_cast<int32_t>(x));
};
int64_t eval = cast(gpr[data.rm]) * cast(gpr[data.rs]) +
(data.acc ? (cast(gpr[data.rdhi]) << 32) |
cast(gpr[data.rdlo])
: 0);
gpr[data.rdlo] = bit_range(eval, 0, 31);
gpr[data.rdhi] = bit_range(eval, 32, 63);
}
if (data.set) {
cpsr.set_z(gpr[data.rdhi] == 0 && gpr[data.rdlo] == 0);
cpsr.set_n(get_bit(gpr[data.rdhi], 31));
cpsr.set_c(0);
cpsr.set_v(0);
}
},
[](Undefined) { glogger.warn("Undefined instruction"); },
[this, pc_error](SingleDataSwap& data) {
pc_error(data.rm);
pc_error(data.rn);
pc_error(data.rd);
if (data.byte) {
gpr[data.rd] = bus->read_byte(gpr[data.rn]);
bus->write_byte(gpr[data.rn], gpr[data.rm] & 0xFF);
} else {
gpr[data.rd] = bus->read_word(gpr[data.rn]);
bus->write_word(gpr[data.rn], gpr[data.rm]);
}
},
[this, pc_warn, pc_error](SingleDataTransfer& data) {
uint32_t offset = 0;
uint32_t address = gpr[data.rn];
if (!data.pre && data.write)
glogger.warn("Write-back enabled with post-indexing in {}",
typeid(data).name());
if (data.rn == PC_INDEX && data.write)
glogger.warn("Write-back enabled with base register as PC {}",
typeid(data).name());
if (data.write)
pc_warn(data.rn);
// evaluate the offset
if (const uint16_t* immediate =
std::get_if<uint16_t>(&data.offset)) {
offset = *immediate;
} else if (const Shift* shift = std::get_if<Shift>(&data.offset)) {
uint8_t amount =
(shift->data.immediate ? shift->data.operand
: gpr[shift->data.operand] & 0xFF);
bool carry = cpsr.c();
if (!shift->data.immediate)
pc_error(shift->data.operand);
pc_error(shift->rm);
offset =
eval_shift(shift->data.type, gpr[shift->rm], amount, carry);
cpsr.set_c(carry);
}
// PC is always two instructions ahead
if (data.rn == PC_INDEX)
address -= 2 * INSTRUCTION_SIZE;
if (data.pre)
address += (data.up ? offset : -offset);
// load
if (data.load) {
// byte
if (data.byte)
gpr[data.rd] = bus->read_byte(address);
// word
else
gpr[data.rd] = bus->read_word(address);
// store
} else {
// take PC into consideration
if (data.rd == PC_INDEX)
address += INSTRUCTION_SIZE;
// byte
if (data.byte)
bus->write_byte(address, gpr[data.rd] & 0xFF);
// word
else
bus->write_word(address, gpr[data.rd]);
}
if (!data.pre)
address += (data.up ? offset : -offset);
if (!data.pre || data.write)
gpr[data.rn] = address;
if (data.rd == PC_INDEX && data.load)
is_flushed = true;
},
[this, pc_warn, pc_error](HalfwordTransfer& data) {
uint32_t address = gpr[data.rn];
uint32_t offset = 0;
if (!data.pre && data.write)
glogger.error("Write-back enabled with post-indexing in {}",
typeid(data).name());
if (data.sign && !data.load)
glogger.error("Signed data found in {}", typeid(data).name());
if (data.write)
pc_warn(data.rn);
// offset is register number (4 bits) when not an immediate
if (!data.imm) {
pc_error(data.offset);
offset = gpr[data.offset];
} else {
offset = data.offset;
}
// PC is always two instructions ahead
if (data.rn == PC_INDEX)
address -= 2 * INSTRUCTION_SIZE;
if (data.pre)
address += (data.up ? offset : -offset);
// load
if (data.load) {
// signed
if (data.sign) {
// halfword
if (data.half) {
gpr[data.rd] = bus->read_halfword(address);
// sign extend the halfword
gpr[data.rd] =
(static_cast<int32_t>(gpr[data.rd]) << 16) >> 16;
// byte
} else {
gpr[data.rd] = bus->read_byte(address);
// sign extend the byte
gpr[data.rd] =
(static_cast<int32_t>(gpr[data.rd]) << 24) >> 24;
}
// unsigned halfword
} else if (data.half) {
gpr[data.rd] = bus->read_halfword(address);
}
// store
} else {
// take PC into consideration
if (data.rd == PC_INDEX)
address += INSTRUCTION_SIZE;
// halfword
if (data.half)
bus->write_halfword(address, gpr[data.rd]);
}
if (!data.pre)
address += (data.up ? offset : -offset);
if (!data.pre || data.write)
gpr[data.rn] = address;
if (data.rd == PC_INDEX && data.load)
is_flushed = true;
},
[this, pc_error](BlockDataTransfer& data) {
uint32_t address = gpr[data.rn];
Mode mode = cpsr.mode();
uint8_t alignment = 4; // word
uint8_t i = 0;
uint8_t n_regs = std::popcount(data.regs);
pc_error(data.rn);
if (cpsr.mode() == Mode::User && data.s) {
glogger.error("Bit S is set outside priviliged modes in {}",
typeid(data).name());
}
// we just change modes to load user registers
if ((!get_bit(data.regs, PC_INDEX) && data.s) ||
(!data.load && data.s)) {
chg_mode(Mode::User);
if (data.write) {
glogger.error(
"Write-back enable for user bank registers in {}",
typeid(data).name());
}
}
// account for decrement
if (!data.up)
address -= (n_regs - 1) * alignment;
if (data.pre)
address += (data.up ? alignment : -alignment);
if (data.load) {
if (get_bit(data.regs, PC_INDEX) && data.s && data.load) {
// current mode's spsr is already loaded when it was
// switched
spsr = cpsr;
}
for (i = 0; i < GPR_COUNT; i++) {
if (get_bit(data.regs, i)) {
gpr[i] = bus->read_word(address);
address += alignment;
}
}
} else {
for (i = 0; i < GPR_COUNT; i++) {
if (get_bit(data.regs, i)) {
bus->write_word(address, gpr[i]);
address += alignment;
}
}
}
if (!data.pre)
address += (data.up ? alignment : -alignment);
// reset back to original address + offset if incremented earlier
if (data.up)
address -= n_regs * alignment;
else
address -= alignment;
if (!data.pre || data.write)
gpr[data.rn] = address;
if (data.load && get_bit(data.regs, PC_INDEX))
is_flushed = true;
// load back the original mode registers
chg_mode(mode);
},
[this, pc_error](PsrTransfer& data) {
if (data.spsr && cpsr.mode() == Mode::User) {
glogger.error("Accessing SPSR in User mode in {}",
typeid(data).name());
}
Psr& psr = data.spsr ? spsr : cpsr;
switch (data.type) {
case PsrTransfer::Type::Mrs:
pc_error(data.operand);
gpr[data.operand] = psr.raw();
break;
case PsrTransfer::Type::Msr:
pc_error(data.operand);
if (cpsr.mode() != Mode::User) {
psr.set_all(gpr[data.operand]);
}
break;
case PsrTransfer::Type::Msr_flg:
uint32_t operand =
(data.imm ? data.operand : gpr[data.operand]);
psr.set_n(get_bit(operand, 31));
psr.set_z(get_bit(operand, 30));
psr.set_c(get_bit(operand, 29));
psr.set_v(get_bit(operand, 28));
break;
}
},
[this, pc_error](DataProcessing& data) {
using OpCode = DataProcessing::OpCode;
uint32_t op_1 = gpr[data.rn];
uint32_t op_2 = 0;
uint32_t result = 0;
if (const uint32_t* immediate =
std::get_if<uint32_t>(&data.operand)) {
op_2 = *immediate;
} else if (const Shift* shift = std::get_if<Shift>(&data.operand)) {
uint8_t amount =
(shift->data.immediate ? shift->data.operand
: gpr[shift->data.operand] & 0xFF);
bool carry = cpsr.c();
if (!shift->data.immediate)
pc_error(shift->data.operand);
pc_error(shift->rm);
op_2 =
eval_shift(shift->data.type, gpr[shift->rm], amount, carry);
cpsr.set_c(carry);
// PC is 12 bytes ahead when shifting
if (data.rn == PC_INDEX)
op_1 += INSTRUCTION_SIZE;
}
bool overflow = cpsr.v();
bool carry = cpsr.c();
auto sub = [&carry, &overflow](uint32_t a, uint32_t b) -> uint32_t {
bool s1 = get_bit(a, 31);
bool s2 = get_bit(b, 31);
uint32_t result = a - b;
carry = b <= a;
overflow = s1 != s2 && s2 == get_bit(result, 31);
return result;
};
auto add = [&carry, &overflow](
uint32_t a, uint32_t b, bool c = 0) -> uint32_t {
bool s1 = get_bit(a, 31);
bool s2 = get_bit(b, 31);
// 33 bits
uint64_t result_ = a + b + c;
uint32_t result = result_ & 0xFFFFFFFF;
carry = get_bit(result_, 32);
overflow = s1 == s2 && s2 != get_bit(result, 31);
return result;
};
auto sbc = [&carry,
&overflow](uint32_t a, uint32_t b, bool c) -> uint32_t {
bool s1 = get_bit(a, 31);
bool s2 = get_bit(b, 31);
uint64_t result_ = a - b + c - 1;
uint32_t result = result_ & 0xFFFFFFFF;
carry = get_bit(result_, 32);
overflow = s1 != s2 && s2 == get_bit(result, 31);
return result;
};
switch (data.opcode) {
case OpCode::AND:
case OpCode::TST:
result = op_1 & op_2;
result = op_1 & op_2;
break;
case OpCode::EOR:
case OpCode::TEQ:
result = op_1 ^ op_2;
break;
case OpCode::SUB:
case OpCode::CMP:
result = sub(op_1, op_2);
break;
case OpCode::RSB:
result = sub(op_2, op_1);
break;
case OpCode::ADD:
case OpCode::CMN:
result = add(op_1, op_2);
break;
case OpCode::ADC:
result = add(op_1, op_2, carry);
break;
case OpCode::SBC:
result = sbc(op_1, op_2, carry);
break;
case OpCode::RSC:
result = sbc(op_2, op_1, carry);
break;
case OpCode::ORR:
result = op_1 | op_2;
break;
case OpCode::MOV:
result = op_2;
break;
case OpCode::BIC:
result = op_1 & ~op_2;
break;
case OpCode::MVN:
result = ~op_2;
break;
}
auto set_conditions = [this, carry, overflow, result]() {
cpsr.set_c(carry);
cpsr.set_v(overflow);
cpsr.set_n(get_bit(result, 31));
cpsr.set_z(result == 0);
};
if (data.set) {
if (data.rd == PC_INDEX) {
if (cpsr.mode() == Mode::User)
glogger.error("Running {} in User mode",
typeid(data).name());
spsr = cpsr;
} else {
set_conditions();
}
}
if (data.opcode == OpCode::TST || data.opcode == OpCode::TEQ ||
data.opcode == OpCode::CMP || data.opcode == OpCode::CMN) {
set_conditions();
} else {
gpr[data.rd] = result;
if (data.rd == PC_INDEX || data.opcode == OpCode::MVN)
is_flushed = true;
}
},
[this](SoftwareInterrupt) {
chg_mode(Mode::Supervisor);
pc = 0x08;
spsr = cpsr;
},
[](auto& data) {
glogger.error("Unimplemented {} instruction", typeid(data).name());
} },
data);
}
}

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#include "instruction.hh"
#include "util/bits.hh"
#include <iterator>
namespace matar {
namespace arm {
Instruction::Instruction(uint32_t insn)
: condition(static_cast<Condition>(bit_range(insn, 28, 31))) {
// Branch and exhcange
if ((insn & 0x0FFFFFF0) == 0x012FFF10) {
uint8_t rn = insn & 0b1111;
data = BranchAndExchange{ rn };
// Branch
} else if ((insn & 0x0E000000) == 0x0A000000) {
bool link = get_bit(insn, 24);
uint32_t offset = bit_range(insn, 0, 23);
// lsh 2 and sign extend the 26 bit offset to 32 bits
offset = (static_cast<int32_t>(offset) << 8) >> 6;
offset += 2 * INSTRUCTION_SIZE;
data = Branch{ .link = link, .offset = offset };
// Multiply
} else if ((insn & 0x0FC000F0) == 0x00000090) {
uint8_t rm = bit_range(insn, 0, 3);
uint8_t rs = bit_range(insn, 8, 11);
uint8_t rn = bit_range(insn, 12, 15);
uint8_t rd = bit_range(insn, 16, 19);
bool set = get_bit(insn, 20);
bool acc = get_bit(insn, 21);
data = Multiply{
.rm = rm, .rs = rs, .rn = rn, .rd = rd, .set = set, .acc = acc
};
// Multiply long
} else if ((insn & 0x0F8000F0) == 0x00800090) {
uint8_t rm = bit_range(insn, 0, 3);
uint8_t rs = bit_range(insn, 8, 11);
uint8_t rdlo = bit_range(insn, 12, 15);
uint8_t rdhi = bit_range(insn, 16, 19);
bool set = get_bit(insn, 20);
bool acc = get_bit(insn, 21);
bool uns = !get_bit(insn, 22);
data = MultiplyLong{ .rm = rm,
.rs = rs,
.rdlo = rdlo,
.rdhi = rdhi,
.set = set,
.acc = acc,
.uns = uns };
// Undefined
} else if ((insn & 0x0E000010) == 0x06000010) {
data = Undefined{};
// Single data swap
} else if ((insn & 0x0FB00FF0) == 0x01000090) {
uint8_t rm = bit_range(insn, 0, 3);
uint8_t rd = bit_range(insn, 12, 15);
uint8_t rn = bit_range(insn, 16, 19);
bool byte = get_bit(insn, 22);
data = SingleDataSwap{ .rm = rm, .rd = rd, .rn = rn, .byte = byte };
// Single data transfer
} else if ((insn & 0x0C000000) == 0x04000000) {
std::variant<uint16_t, Shift> offset;
uint8_t rd = bit_range(insn, 12, 15);
uint8_t rn = bit_range(insn, 16, 19);
bool load = get_bit(insn, 20);
bool write = get_bit(insn, 21);
bool byte = get_bit(insn, 22);
bool up = get_bit(insn, 23);
bool pre = get_bit(insn, 24);
bool imm = get_bit(insn, 25);
if (imm) {
// register specified shift amounts not available in single data
// transfer (see Undefined)
uint8_t rm = bit_range(insn, 0, 3);
ShiftType shift_type =
static_cast<ShiftType>(bit_range(insn, 5, 6));
uint8_t operand = bit_range(insn, 7, 11);
offset = Shift{ .rm = rm,
.data = ShiftData{ .type = shift_type,
.immediate = true,
.operand = operand } };
} else {
offset = static_cast<uint16_t>(bit_range(insn, 0, 11));
}
data = SingleDataTransfer{ .offset = offset,
.rd = rd,
.rn = rn,
.load = load,
.write = write,
.byte = byte,
.up = up,
.pre = pre };
// Halfword transfer
} else if ((insn & 0x0E000090) == 0x00000090) {
uint8_t offset = bit_range(insn, 0, 3);
bool half = get_bit(insn, 5);
bool sign = get_bit(insn, 6);
uint8_t rd = bit_range(insn, 12, 15);
uint8_t rn = bit_range(insn, 16, 19);
bool load = get_bit(insn, 20);
bool write = get_bit(insn, 21);
bool imm = get_bit(insn, 22);
bool up = get_bit(insn, 23);
bool pre = get_bit(insn, 24);
offset |= (imm ? bit_range(insn, 8, 11) << 2 : 0);
data = HalfwordTransfer{ .offset = offset,
.half = half,
.sign = sign,
.rd = rd,
.rn = rn,
.load = load,
.write = write,
.imm = imm,
.up = up,
.pre = pre };
// Block data transfer
} else if ((insn & 0x0E000000) == 0x08000000) {
uint16_t regs = bit_range(insn, 0, 15);
uint8_t rn = bit_range(insn, 16, 19);
bool load = get_bit(insn, 20);
bool write = get_bit(insn, 21);
bool s = get_bit(insn, 22);
bool up = get_bit(insn, 23);
bool pre = get_bit(insn, 24);
data = BlockDataTransfer{ .regs = regs,
.rn = rn,
.load = load,
.write = write,
.s = s,
.up = up,
.pre = pre };
// Data Processing
} else if ((insn & 0x0C000000) == 0x00000000) {
using OpCode = DataProcessing::OpCode;
uint8_t rd = bit_range(insn, 12, 15);
uint8_t rn = bit_range(insn, 16, 19);
bool set = get_bit(insn, 20);
OpCode opcode = static_cast<OpCode>(bit_range(insn, 21, 24));
bool imm = get_bit(insn, 25);
if ((opcode == OpCode::TST || opcode == OpCode::CMP) && !set) {
data = PsrTransfer{ .operand = rd,
.spsr = get_bit(insn, 22),
.type = PsrTransfer::Type::Mrs,
.imm = 0 };
} else if ((opcode == OpCode::TEQ || opcode == OpCode::CMN) && !set) {
uint32_t operand = 0;
if (imm) {
uint32_t immediate = bit_range(insn, 0, 7);
uint8_t rotate = bit_range(insn, 8, 11);
operand = std::rotr(immediate, rotate * 2);
} else {
operand = bit_range(insn, 0, 3);
}
data = PsrTransfer{ .operand = operand,
.spsr = get_bit(insn, 22),
.type = (get_bit(insn, 16)
? PsrTransfer::Type::Msr
: PsrTransfer::Type::Msr_flg),
.imm = imm };
} else {
std::variant<Shift, uint32_t> operand;
if (imm) {
uint32_t immediate = bit_range(insn, 0, 7);
uint8_t rotate = bit_range(insn, 8, 11);
operand = std::rotr(immediate, rotate * 2);
} else {
uint8_t rm = bit_range(insn, 0, 3);
bool reg = get_bit(insn, 4);
ShiftType shift_type =
static_cast<ShiftType>(bit_range(insn, 5, 6));
uint8_t sh_operand = bit_range(insn, (reg ? 8 : 7), 11);
operand = Shift{ .rm = rm,
.data = ShiftData{ .type = shift_type,
.immediate = !reg,
.operand = sh_operand } };
}
data = DataProcessing{ .operand = operand,
.rd = rd,
.rn = rn,
.set = set,
.opcode = opcode };
}
// Software interrupt
} else if ((insn & 0x0F000000) == 0x0F000000) {
data = SoftwareInterrupt{};
// Coprocessor data transfer
} else if ((insn & 0x0E000000) == 0x0C000000) {
uint8_t offset = bit_range(insn, 0, 7);
uint8_t cpn = bit_range(insn, 8, 11);
uint8_t crd = bit_range(insn, 12, 15);
uint8_t rn = bit_range(insn, 16, 19);
bool load = get_bit(insn, 20);
bool write = get_bit(insn, 21);
bool len = get_bit(insn, 22);
bool up = get_bit(insn, 23);
bool pre = get_bit(insn, 24);
data = CoprocessorDataTransfer{ .offset = offset,
.cpn = cpn,
.crd = crd,
.rn = rn,
.load = load,
.write = write,
.len = len,
.up = up,
.pre = pre };
// Coprocessor data operation
} else if ((insn & 0x0F000010) == 0x0E000000) {
uint8_t crm = bit_range(insn, 0, 3);
uint8_t cp = bit_range(insn, 5, 7);
uint8_t cpn = bit_range(insn, 8, 11);
uint8_t crd = bit_range(insn, 12, 15);
uint8_t crn = bit_range(insn, 16, 19);
uint8_t cp_opc = bit_range(insn, 20, 23);
data = CoprocessorDataOperation{ .crm = crm,
.cp = cp,
.cpn = cpn,
.crd = crd,
.crn = crn,
.cp_opc = cp_opc };
// Coprocessor register transfer
} else if ((insn & 0x0F000010) == 0x0E000010) {
uint8_t crm = bit_range(insn, 0, 3);
uint8_t cp = bit_range(insn, 5, 7);
uint8_t cpn = bit_range(insn, 8, 11);
uint8_t rd = bit_range(insn, 12, 15);
uint8_t crn = bit_range(insn, 16, 19);
bool load = get_bit(insn, 20);
uint8_t cp_opc = bit_range(insn, 21, 23);
data = CoprocessorRegisterTransfer{ .crm = crm,
.cp = cp,
.cpn = cpn,
.rd = rd,
.crn = crn,
.load = load,
.cp_opc = cp_opc };
} else {
data = Undefined{};
}
}
std::string
Instruction::disassemble() {
// goddamn this is gore
// TODO: make this less ugly
return std::visit(
overloaded{
[this](BranchAndExchange& data) {
return fmt::format("BX{} R{:d}", condition, data.rn);
},
[this](Branch& data) {
return fmt::format(
"B{}{} 0x{:06X}", (data.link ? "L" : ""), condition, data.offset);
},
[this](Multiply& data) {
if (data.acc) {
return fmt::format("MLA{}{} R{:d},R{:d},R{:d},R{:d}",
condition,
(data.set ? "S" : ""),
data.rd,
data.rm,
data.rs,
data.rn);
} else {
return fmt::format("MUL{}{} R{:d},R{:d},R{:d}",
condition,
(data.set ? "S" : ""),
data.rd,
data.rm,
data.rs);
}
},
[this](MultiplyLong& data) {
return fmt::format("{}{}{}{} R{:d},R{:d},R{:d},R{:d}",
(data.uns ? 'U' : 'S'),
(data.acc ? "MLAL" : "MULL"),
condition,
(data.set ? "S" : ""),
data.rdlo,
data.rdhi,
data.rm,
data.rs);
},
[](Undefined) { return std::string("UND"); },
[this](SingleDataSwap& data) {
return fmt::format("SWP{}{} R{:d},R{:d},[R{:d}]",
condition,
(data.byte ? "B" : ""),
data.rd,
data.rm,
data.rn);
},
[this](SingleDataTransfer& data) {
std::string expression;
std::string address;
if (const uint16_t* offset = std::get_if<uint16_t>(&data.offset)) {
if (*offset == 0) {
expression = "";
} else {
expression =
fmt::format(",{}#{:d}", (data.up ? '+' : '-'), *offset);
}
} else if (const Shift* shift = std::get_if<Shift>(&data.offset)) {
// Shifts are always immediate in single data transfer
expression = fmt::format(",{}R{:d},{} #{:d}",
(data.up ? '+' : '-'),
shift->rm,
shift->data.type,
shift->data.operand);
}
return fmt::format(
"{}{}{}{} R{:d},[R{:d}{}]{}",
(data.load ? "LDR" : "STR"),
condition,
(data.byte ? "B" : ""),
(!data.pre && data.write ? "T" : ""),
data.rd,
data.rn,
(data.pre ? expression : ""),
(data.pre ? (data.write ? "!" : "") : expression));
},
[this](HalfwordTransfer& data) {
std::string expression;
if (data.imm) {
if (data.offset == 0) {
expression = "";
} else {
expression = fmt::format(
",{}#{:d}", (data.up ? '+' : '-'), data.offset);
}
} else {
expression =
fmt::format(",{}R{:d}", (data.up ? '+' : '-'), data.offset);
}
return fmt::format(
"{}{}{}{} R{:d},[R{:d}{}]{}",
(data.load ? "LDR" : "STR"),
condition,
(data.sign ? "S" : ""),
(data.half ? 'H' : 'B'),
data.rd,
data.rn,
(data.pre ? expression : ""),
(data.pre ? (data.write ? "!" : "") : expression));
},
[this](BlockDataTransfer& data) {
std::string regs;
for (uint8_t i = 0; i < 16; i++) {
if (get_bit(data.regs, i))
fmt::format_to(std::back_inserter(regs), "R{:d},", i);
};
regs.pop_back();
return fmt::format("{}{}{}{} R{:d}{},{{{}}}{}",
(data.load ? "LDM" : "STM"),
condition,
(data.up ? 'I' : 'D'),
(data.pre ? 'B' : 'A'),
data.rn,
(data.write ? "!" : ""),
regs,
(data.s ? "^" : ""));
},
[this](PsrTransfer& data) {
if (data.type == PsrTransfer::Type::Mrs) {
return fmt::format("MRS{} R{:d},{}",
condition,
data.operand,
(data.spsr ? "SPSR_all" : "CPSR_all"));
} else {
return fmt::format(
"MSR{} {}_{},{}{}",
condition,
(data.spsr ? "SPSR" : "CPSR"),
(data.type == PsrTransfer::Type::Msr_flg ? "flg" : "all"),
(data.imm ? '#' : 'R'),
data.operand);
}
},
[this](DataProcessing& data) {
using OpCode = DataProcessing::OpCode;
std::string op_2;
if (const uint32_t* operand =
std::get_if<uint32_t>(&data.operand)) {
op_2 = fmt::format("#{:d}", *operand);
} else if (const Shift* shift = std::get_if<Shift>(&data.operand)) {
op_2 = fmt::format("R{:d},{} {}{:d}",
shift->rm,
shift->data.type,
(shift->data.immediate ? '#' : 'R'),
shift->data.operand);
}
switch (data.opcode) {
case OpCode::MOV:
case OpCode::MVN:
return fmt::format("{}{}{} R{:d},{}",
data.opcode,
condition,
(data.set ? "S" : ""),
data.rd,
op_2);
case OpCode::TST:
case OpCode::TEQ:
case OpCode::CMP:
case OpCode::CMN:
return fmt::format(
"{}{} R{:d},{}", data.opcode, condition, data.rn, op_2);
default:
return fmt::format("{}{}{} R{:d},R{:d},{}",
data.opcode,
condition,
(data.set ? "S" : ""),
data.rd,
data.rn,
op_2);
}
},
[this](SoftwareInterrupt) { return fmt::format("SWI{}", condition); },
[this](CoprocessorDataTransfer& data) {
std::string expression = fmt::format(",#{:d}", data.offset);
return fmt::format(
"{}{}{} p{:d},c{:d},[R{:d}{}]{}",
(data.load ? "LDC" : "STC"),
condition,
(data.len ? "L" : ""),
data.cpn,
data.crd,
data.rn,
(data.pre ? expression : ""),
(data.pre ? (data.write ? "!" : "") : expression));
},
[this](CoprocessorDataOperation& data) {
return fmt::format("CDP{} p{},{},c{},c{},c{},{}",
condition,
data.cpn,
data.cp_opc,
data.crd,
data.crn,
data.crm,
data.cp);
},
[this](CoprocessorRegisterTransfer& data) {
return fmt::format("{}{} p{},{},R{},c{},c{},{}",
(data.load ? "MRC" : "MCR"),
condition,
data.cpn,
data.cp_opc,
data.rd,
data.crn,
data.crm,
data.cp);
},
[](auto) { return std::string("unknown instruction"); } },
data);
}
std::ostream&
operator<<(std::ostream& os, const DataProcessing::OpCode opcode) {
#define CASE(opcode) \
case DataProcessing::OpCode::opcode: \
os << #opcode; \
break;
switch (opcode) {
CASE(AND)
CASE(EOR)
CASE(SUB)
CASE(RSB)
CASE(ADD)
CASE(ADC)
CASE(SBC)
CASE(RSC)
CASE(TST)
CASE(TEQ)
CASE(CMP)
CASE(CMN)
CASE(ORR)
CASE(MOV)
CASE(BIC)
CASE(MVN)
}
#undef CASE
return os;
}
}
}

200
src/cpu/arm/instruction.hh Normal file
View File

@@ -0,0 +1,200 @@
#pragma once
#include "cpu/alu.hh"
#include "cpu/psr.hh"
#include <cstdint>
#include <fmt/ostream.h>
#include <variant>
namespace matar {
namespace arm {
template<class... Ts>
struct overloaded : Ts... {
using Ts::operator()...;
};
template<class... Ts>
overloaded(Ts...) -> overloaded<Ts...>;
static constexpr size_t INSTRUCTION_SIZE = 4;
struct BranchAndExchange {
uint8_t rn;
};
struct Branch {
bool link;
uint32_t offset;
};
struct Multiply {
uint8_t rm;
uint8_t rs;
uint8_t rn;
uint8_t rd;
bool set;
bool acc;
};
struct MultiplyLong {
uint8_t rm;
uint8_t rs;
uint8_t rdlo;
uint8_t rdhi;
bool set;
bool acc;
bool uns;
};
struct SingleDataSwap {
uint8_t rm;
uint8_t rd;
uint8_t rn;
bool byte;
};
struct SingleDataTransfer {
std::variant<uint16_t, Shift> offset;
uint8_t rd;
uint8_t rn;
bool load;
bool write;
bool byte;
bool up;
bool pre;
};
struct HalfwordTransfer {
uint8_t offset;
bool half;
bool sign;
uint8_t rd;
uint8_t rn;
bool load;
bool write;
bool imm;
bool up;
bool pre;
};
struct BlockDataTransfer {
uint16_t regs;
uint8_t rn;
bool load;
bool write;
bool s;
bool up;
bool pre;
};
struct DataProcessing {
enum class OpCode {
AND = 0b0000,
EOR = 0b0001,
SUB = 0b0010,
RSB = 0b0011,
ADD = 0b0100,
ADC = 0b0101,
SBC = 0b0110,
RSC = 0b0111,
TST = 0b1000,
TEQ = 0b1001,
CMP = 0b1010,
CMN = 0b1011,
ORR = 0b1100,
MOV = 0b1101,
BIC = 0b1110,
MVN = 0b1111
};
std::variant<Shift, uint32_t> operand;
uint8_t rd;
uint8_t rn;
bool set;
OpCode opcode;
};
struct PsrTransfer {
enum class Type {
Mrs,
Msr,
Msr_flg
};
uint32_t operand;
bool spsr;
Type type;
// ignored outside MSR_flg
bool imm;
};
struct CoprocessorDataTransfer {
uint8_t offset;
uint8_t cpn;
uint8_t crd;
uint8_t rn;
bool load;
bool write;
bool len;
bool up;
bool pre;
};
struct CoprocessorDataOperation {
uint8_t crm;
uint8_t cp;
uint8_t cpn;
uint8_t crd;
uint8_t crn;
uint8_t cp_opc;
};
struct CoprocessorRegisterTransfer {
uint8_t crm;
uint8_t cp;
uint8_t cpn;
uint8_t rd;
uint8_t crn;
bool load;
uint8_t cp_opc;
};
struct Undefined {};
struct SoftwareInterrupt {};
using InstructionData = std::variant<BranchAndExchange,
Branch,
Multiply,
MultiplyLong,
SingleDataSwap,
SingleDataTransfer,
HalfwordTransfer,
BlockDataTransfer,
DataProcessing,
PsrTransfer,
CoprocessorDataTransfer,
CoprocessorDataOperation,
CoprocessorRegisterTransfer,
Undefined,
SoftwareInterrupt>;
struct Instruction {
Condition condition;
InstructionData data;
Instruction(uint32_t insn);
Instruction(Condition condition, InstructionData data) noexcept
: condition(condition)
, data(data){};
std::string disassemble();
};
std::ostream&
operator<<(std::ostream& os, const DataProcessing::OpCode cond);
}
}
namespace fmt {
template<>
struct formatter<matar::arm::DataProcessing::OpCode> : ostream_formatter {};
}

4
src/cpu/arm/meson.build Normal file
View File

@@ -0,0 +1,4 @@
lib_sources += files(
'instruction.cc',
'exec.cc'
)

142
src/cpu/cpu-impl.cc Normal file
View File

@@ -0,0 +1,142 @@
#include "cpu-impl.hh"
#include "util/bits.hh"
#include "util/log.hh"
#include <algorithm>
#include <cstdio>
namespace matar {
CpuImpl::CpuImpl(const Bus& bus) noexcept
: bus(std::make_shared<Bus>(bus))
, gpr({ 0 })
, cpsr(0)
, spsr(0)
, is_flushed(false)
, gpr_banked({ { 0 }, { 0 }, { 0 }, { 0 }, { 0 }, { 0 } })
, spsr_banked({ 0, 0, 0, 0, 0 }) {
cpsr.set_mode(Mode::Supervisor);
cpsr.set_irq_disabled(true);
cpsr.set_fiq_disabled(true);
cpsr.set_state(State::Arm);
glogger.info("CPU successfully initialised");
// PC always points to two instructions ahead
// PC - 2 is the instruction being executed
pc += 2 * arm::INSTRUCTION_SIZE;
}
/* change modes */
void
CpuImpl::chg_mode(const Mode to) {
Mode from = cpsr.mode();
if (from == to)
return;
/* TODO: replace visible registers with view once I understand how to
* concatenate views */
#define STORE_BANKED(mode, MODE) \
std::copy(gpr.begin() + GPR_##MODE##_FIRST, \
gpr.begin() + gpr.size() - 1, \
gpr_banked.mode.begin())
switch (from) {
case Mode::Fiq:
STORE_BANKED(fiq, FIQ);
spsr_banked.fiq = spsr;
break;
case Mode::Supervisor:
STORE_BANKED(svc, SVC);
spsr_banked.svc = spsr;
break;
case Mode::Abort:
STORE_BANKED(abt, ABT);
spsr_banked.abt = spsr;
break;
case Mode::Irq:
STORE_BANKED(irq, IRQ);
spsr_banked.irq = spsr;
break;
case Mode::Undefined:
STORE_BANKED(und, UND);
spsr_banked.und = spsr;
break;
case Mode::User:
case Mode::System:
STORE_BANKED(old, SYS_USR);
break;
}
#define RESTORE_BANKED(mode, MODE) \
std::copy(gpr_banked.mode.begin(), \
gpr_banked.mode.end(), \
gpr.begin() + GPR_##MODE##_FIRST)
switch (to) {
case Mode::Fiq:
RESTORE_BANKED(fiq, FIQ);
spsr = spsr_banked.fiq;
break;
case Mode::Supervisor:
RESTORE_BANKED(svc, SVC);
spsr = spsr_banked.svc;
break;
case Mode::Abort:
RESTORE_BANKED(abt, ABT);
spsr = spsr_banked.abt;
break;
case Mode::Irq:
RESTORE_BANKED(irq, IRQ);
spsr = spsr_banked.irq;
break;
case Mode::Undefined:
RESTORE_BANKED(und, UND);
spsr = spsr_banked.und;
break;
case Mode::User:
case Mode::System:
STORE_BANKED(old, SYS_USR);
break;
}
#undef RESTORE_BANKED
cpsr.set_mode(to);
}
void
CpuImpl::step() {
// Current instruction is two instructions behind PC
uint32_t cur_pc = pc - 2 * arm::INSTRUCTION_SIZE;
if (cpsr.state() == State::Arm) {
uint32_t x = bus->read_word(cur_pc);
arm::Instruction instruction(x);
glogger.info("{:#034b}", x);
exec_arm(instruction);
glogger.info("0x{:08X} : {}", cur_pc, instruction.disassemble());
if (is_flushed) {
// if flushed, do not increment the PC, instead set it to two
// instructions ahead to account for flushed "fetch" and "decode"
// instructions
pc += 2 * arm::INSTRUCTION_SIZE;
is_flushed = false;
} else {
// if not flushed continue like normal
pc += arm::INSTRUCTION_SIZE;
}
}
}
}

40
src/cpu/cpu.hh → src/cpu/cpu-impl.hh
View File

@@ -1,27 +1,28 @@
#pragma once
#include "bus.hh"
#include "instruction.hh"
#include "psr.hh"
#include "cpu/arm/instruction.hh"
#include "cpu/psr.hh"
#include <cstdint>
using std::size_t;
class Cpu {
namespace matar {
class CpuImpl {
public:
Cpu(Bus& bus);
CpuImpl(const Bus& bus) noexcept;
void step();
void chg_mode(const Mode to);
void exec_arm(const arm::Instruction instruction);
private:
static constexpr size_t GPR_COUNT = 16;
static constexpr uint8_t GPR_COUNT = 16;
static constexpr size_t GPR_FIQ_FIRST = 8;
static constexpr size_t GPR_SVC_FIRST = 13;
static constexpr size_t GPR_ABT_FIRST = 13;
static constexpr size_t GPR_IRQ_FIRST = 13;
static constexpr size_t GPR_UND_FIRST = 13;
static constexpr size_t GPR_SYS_USR_FIRST = 8;
static constexpr uint8_t GPR_FIQ_FIRST = 8;
static constexpr uint8_t GPR_SVC_FIRST = 13;
static constexpr uint8_t GPR_ABT_FIRST = 13;
static constexpr uint8_t GPR_IRQ_FIRST = 13;
static constexpr uint8_t GPR_UND_FIRST = 13;
static constexpr uint8_t GPR_SYS_USR_FIRST = 8;
std::shared_ptr<Bus> bus;
std::array<uint32_t, GPR_COUNT> gpr; // general purpose registers
@@ -29,7 +30,12 @@ class Cpu {
Psr cpsr; // current program status register
Psr spsr; // status program status register
uint32_t& pc = gpr[15];
static constexpr uint8_t PC_INDEX = 15;
static_assert(PC_INDEX < GPR_COUNT);
uint32_t& pc = gpr[PC_INDEX];
bool is_flushed;
struct {
std::array<uint32_t, GPR_COUNT - GPR_FIQ_FIRST - 1> fiq;
@@ -49,7 +55,5 @@ class Cpu {
Psr irq;
Psr und;
} spsr_banked; // banked saved program status registers
void chg_mode(const Mode to);
void exec_arm(const ArmInstruction instruction);
};
}

391
src/cpu/cpu.cc
View File

@@ -1,389 +1,14 @@
#include "cpu.hh"
#include "util/bits.hh"
#include "util/log.hh"
#include "utility.hh"
#include <algorithm>
#include <cstdio>
#include "cpu/cpu.hh"
#include "cpu-impl.hh"
using namespace logger;
namespace matar {
Cpu::Cpu(const Bus& bus) noexcept
: impl(std::make_unique<CpuImpl>(bus)){};
Cpu::Cpu(Bus& bus)
: bus(std::make_shared<Bus>(bus))
, gpr({ 0 })
, cpsr(0)
, spsr(0)
, gpr_banked({ { 0 }, { 0 }, { 0 }, { 0 }, { 0 }, { 0 } })
, spsr_banked({ 0, 0, 0, 0, 0 }) {
cpsr.set_mode(Mode::System);
cpsr.set_irq_disabled(true);
cpsr.set_fiq_disabled(true);
cpsr.set_state(State::Arm);
log_info("CPU successfully initialised");
// PC is always two instructions ahead in the pipeline
pc += 2 * ARM_INSTRUCTION_SIZE;
}
/* change modes */
void
Cpu::chg_mode(const Mode to) {
Mode from = cpsr.mode();
if (from == to)
return;
/* TODO: replace visible registers with view once I understand how to
* concatenate views */
#define STORE_BANKED(mode, MODE) \
std::copy(gpr.begin() + GPR_##MODE##_FIRST, \
gpr.begin() + GPR_COUNT - 1, \
gpr_banked.mode.begin())
switch (from) {
case Mode::Fiq:
STORE_BANKED(fiq, FIQ);
spsr_banked.fiq = spsr;
break;
case Mode::Supervisor:
STORE_BANKED(svc, SVC);
spsr_banked.svc = spsr;
break;
case Mode::Abort:
STORE_BANKED(abt, ABT);
spsr_banked.abt = spsr;
break;
case Mode::Irq:
STORE_BANKED(irq, IRQ);
spsr_banked.irq = spsr;
break;
case Mode::Undefined:
STORE_BANKED(und, UND);
spsr_banked.und = spsr;
break;
case Mode::User:
case Mode::System:
STORE_BANKED(old, SYS_USR);
break;
}
#define RESTORE_BANKED(mode, MODE) \
std::copy(gpr_banked.mode.begin(), \
gpr_banked.mode.end(), \
gpr.begin() + GPR_##MODE##_FIRST)
switch (to) {
case Mode::Fiq:
RESTORE_BANKED(fiq, FIQ);
spsr = spsr_banked.fiq;
break;
case Mode::Supervisor:
RESTORE_BANKED(svc, SVC);
spsr = spsr_banked.svc;
break;
case Mode::Abort:
RESTORE_BANKED(abt, ABT);
spsr = spsr_banked.abt;
break;
case Mode::Irq:
RESTORE_BANKED(irq, IRQ);
spsr = spsr_banked.irq;
break;
case Mode::Undefined:
RESTORE_BANKED(und, UND);
spsr = spsr_banked.und;
break;
case Mode::User:
case Mode::System:
STORE_BANKED(old, SYS_USR);
break;
}
#undef RESTORE_BANKED
cpsr.set_mode(to);
}
void
Cpu::exec_arm(const ArmInstruction instruction) {
auto cond = instruction.get_condition();
auto data = instruction.get_data();
if (!cpsr.condition(cond)) {
return;
}
auto pc_error = [](uint8_t r) {
if (r == 15)
log_error("Using PC (R15) as operand register");
};
auto pc_warn = [](uint8_t r) {
if (r == 15)
log_warn("Using PC (R15) as operand register");
};
std::visit(
overloaded{
[this, pc_warn](ArmInstruction::BranchAndExchange& data) {
State state = static_cast<State>(data.rn & 1);
pc_warn(data.rn);
// set state
cpsr.set_state(state);
// copy to PC
pc = gpr[data.rn];
// ignore [1:0] bits for arm and 0 bit for thumb
rst_nth_bit(pc, 0);
if (state == State::Arm)
rst_nth_bit(pc, 1);
},
[this](ArmInstruction::Branch& data) {
auto offset = data.offset;
// lsh 2 and sign extend the 26 bit offset to 32 bits
offset <<= 2;
if (get_nth_bit(offset, 25))
offset |= 0xFC000000;
if (data.link)
gpr[14] = pc - ARM_INSTRUCTION_SIZE;
pc += offset - ARM_INSTRUCTION_SIZE;
},
[this, pc_error](ArmInstruction::Multiply& data) {
if (data.rd == data.rm)
log_error("rd and rm are not distinct in {}",
typeid(data).name());
pc_error(data.rd);
pc_error(data.rd);
pc_error(data.rd);
gpr[data.rd] =
gpr[data.rm] * gpr[data.rs] + (data.acc ? gpr[data.rn] : 0);
if (data.set) {
cpsr.set_z(!static_cast<bool>(gpr[data.rd]));
cpsr.set_n(get_nth_bit(gpr[data.rd], 31));
cpsr.set_c(0);
}
},
[this, pc_error](ArmInstruction::MultiplyLong& data) {
if (data.rdhi == data.rdlo || data.rdhi == data.rm ||
data.rdlo == data.rm)
log_error("rdhi, rdlo and rm are not distinct in {}",
typeid(data).name());
pc_error(data.rdhi);
pc_error(data.rdlo);
pc_error(data.rm);
pc_error(data.rs);
if (data.uns) {
uint64_t eval =
static_cast<uint64_t>(gpr[data.rm]) *
static_cast<uint64_t>(gpr[data.rs]) +
(data.acc ? static_cast<uint64_t>(gpr[data.rdhi]) << 32 |
static_cast<uint64_t>(gpr[data.rdlo])
: 0);
gpr[data.rdlo] = get_bit_range(eval, 0, 31);
gpr[data.rdhi] = get_bit_range(eval, 32, 63);
} else {
int64_t eval =
static_cast<int64_t>(gpr[data.rm]) *
static_cast<int64_t>(gpr[data.rs]) +
(data.acc ? static_cast<int64_t>(gpr[data.rdhi]) << 32 |
static_cast<int64_t>(gpr[data.rdlo])
: 0);
gpr[data.rdlo] = get_bit_range(eval, 0, 31);
gpr[data.rdhi] = get_bit_range(eval, 32, 63);
}
if (data.set) {
cpsr.set_z(!(static_cast<bool>(gpr[data.rdhi]) ||
static_cast<bool>(gpr[data.rdlo])));
cpsr.set_n(get_nth_bit(gpr[data.rdhi], 31));
cpsr.set_c(0);
cpsr.set_v(0);
}
},
[](ArmInstruction::Undefined) { log_warn("Undefined instruction"); },
[this, pc_warn](ArmInstruction::SingleDataSwap& data) {
pc_warn(data.rm);
pc_warn(data.rn);
pc_warn(data.rd);
if (data.byte) {
gpr[data.rd] = bus->read_byte(gpr[data.rn]);
bus->write_byte(gpr[data.rn], gpr[data.rm] & 0xFF);
} else {
gpr[data.rd] = bus->read_word(gpr[data.rn]);
bus->write_word(gpr[data.rn], gpr[data.rm]);
}
},
[this, pc_warn, pc_error](ArmInstruction::SingleDataTransfer& data) {
uint32_t offset = 0;
uint32_t address = gpr[data.rn];
if (!data.pre && data.write)
log_warn("Write-back enabled with post-indexing in {}",
typeid(data).name());
if (data.write)
pc_warn(data.rn);
// evaluate the offset
if (const uint16_t* immediate =
std::get_if<uint16_t>(&data.offset)) {
offset = *immediate;
} else if (const Shift* shift = std::get_if<Shift>(&data.offset)) {
uint8_t amount =
(shift->data.immediate ? shift->data.operand
: gpr[shift->data.operand] & 0xFF);
bool carry = cpsr.c();
if (!shift->data.immediate)
pc_error(shift->data.operand);
pc_error(shift->rm);
eval_shift(shift->data.type, gpr[shift->rm], amount, carry);
cpsr.set_c(carry);
}
// PC is always two instructions ahead
if (data.rn == 15)
address -= 2 * ARM_INSTRUCTION_SIZE;
if (data.pre)
address += (data.up ? offset : -offset);
// load
if (data.load) {
// byte
if (data.byte)
gpr[data.rd] = bus->read_byte(address);
// word
else
gpr[data.rd] = bus->read_word(address);
// store
} else {
// take PC into consideration
if (data.rd == 15)
address += ARM_INSTRUCTION_SIZE;
// byte
if (data.byte)
bus->write_byte(address, gpr[data.rd] & 0xFF);
// word
else
bus->write_word(address, gpr[data.rd]);
}
if (!data.pre)
address += (data.up ? offset : -offset);
if (!data.pre || data.write)
gpr[data.rn] = address;
},
[this, pc_warn, pc_error](ArmInstruction::HalfwordTransfer& data) {
uint32_t address = gpr[data.rn];
if (!data.pre && data.write)
log_error("Write-back enabled with post-indexing in {}",
typeid(data).name());
if (data.sign && !data.load)
log_error("Signed data found in {}", typeid(data).name());
if (data.write)
pc_warn(data.rn);
// offset is register number (4 bits) when not an immediate
if (!data.imm)
pc_error(data.offset);
if (data.pre)
address += (data.up ? data.offset : -data.offset);
// load
if (data.load) {
// signed
if (data.sign) {
// halfword
if (data.half) {
gpr[data.rd] = bus->read_halfword(address);
// sign extend the halfword
if (get_nth_bit(gpr[data.rd], 15))
gpr[data.rd] |= 0xFFFF0000;
// byte
} else {
gpr[data.rd] = bus->read_byte(address);
// sign extend the byte
if (get_nth_bit(gpr[data.rd], 7))
gpr[data.rd] |= 0xFFFFFF00;
}
// unsigned halfword
} else if (data.half) {
gpr[data.rd] = bus->read_halfword(address);
}
// store
} else {
// take PC into consideration
if (data.rd == 15)
address += ARM_INSTRUCTION_SIZE;
// halfword
if (data.half)
bus->write_halfword(address, gpr[data.rd]);
}
if (!data.pre)
address += (data.up ? data.offset : -data.offset);
if (!data.pre || data.write)
gpr[data.rn] = address;
},
[this](ArmInstruction::SoftwareInterrupt) {
chg_mode(Mode::Supervisor);
pc = 0x08;
spsr = cpsr;
},
[](auto& data) { log_error("{} instruction", typeid(data).name()); } },
data);
}
Cpu::~Cpu() = default;
void
Cpu::step() {
uint32_t cur_pc = pc - 2 * ARM_INSTRUCTION_SIZE;
if (cpsr.state() == State::Arm) {
ArmInstruction instruction(bus->read_word(cur_pc));
log_info("{:#034b}", bus->read_word(cur_pc));
exec_arm(instruction);
log_info("{:#010X} : {}", cur_pc, instruction.disassemble());
pc += ARM_INSTRUCTION_SIZE;
}
impl->step();
};
}

359
src/cpu/instruction.cc
View File

@@ -1,359 +0,0 @@
#include "instruction.hh"
#include "util/bits.hh"
ArmInstruction::ArmInstruction(uint32_t insn)
: condition(static_cast<Condition>(get_bit_range(insn, 28, 31))) {
// Branch and exhcange
if ((insn & 0x0FFFFFF0) == 0x012FFF10) {
uint8_t rn = insn & 0b1111;
data = BranchAndExchange{ rn };
// Branch
} else if ((insn & 0x0E000000) == 0x0A000000) {
bool link = get_nth_bit(insn, 24);
uint32_t offset = get_bit_range(insn, 0, 23);
data = Branch{ .link = link, .offset = offset };
// Multiply
} else if ((insn & 0x0FC000F0) == 0x00000090) {
uint8_t rm = get_bit_range(insn, 0, 3);
uint8_t rs = get_bit_range(insn, 8, 11);
uint8_t rn = get_bit_range(insn, 12, 15);
uint8_t rd = get_bit_range(insn, 16, 19);
bool set = get_nth_bit(insn, 20);
bool acc = get_nth_bit(insn, 21);
data = Multiply{
.rm = rm, .rs = rs, .rn = rn, .rd = rd, .set = set, .acc = acc
};
// Multiply long
} else if ((insn & 0x0F8000F0) == 0x00800090) {
uint8_t rm = get_bit_range(insn, 0, 3);
uint8_t rs = get_bit_range(insn, 8, 11);
uint8_t rdlo = get_bit_range(insn, 12, 15);
uint8_t rdhi = get_bit_range(insn, 16, 19);
bool set = get_nth_bit(insn, 20);
bool acc = get_nth_bit(insn, 21);
bool uns = get_nth_bit(insn, 22);
data = MultiplyLong{ .rm = rm,
.rs = rs,
.rdlo = rdlo,
.rdhi = rdhi,
.set = set,
.acc = acc,
.uns = uns };
// Undefined
} else if ((insn & 0x0E000010) == 0x06000010) {
data = Undefined{};
// Single data swap
} else if ((insn & 0x0FB00FF0) == 0x01000090) {
uint8_t rm = get_bit_range(insn, 0, 3);
uint8_t rd = get_bit_range(insn, 12, 15);
uint8_t rn = get_bit_range(insn, 16, 19);
bool byte = get_nth_bit(insn, 22);
data = SingleDataSwap{ .rm = rm, .rd = rd, .rn = rn, .byte = byte };
// Single data transfer
} else if ((insn & 0x0C000000) == 0x04000000) {
std::variant<uint16_t, Shift> offset;
uint8_t rd = get_bit_range(insn, 12, 15);
uint8_t rn = get_bit_range(insn, 16, 19);
bool load = get_nth_bit(insn, 20);
bool write = get_nth_bit(insn, 21);
bool byte = get_nth_bit(insn, 22);
bool up = get_nth_bit(insn, 23);
bool pre = get_nth_bit(insn, 24);
bool imm = get_nth_bit(insn, 25);
if (imm) {
uint8_t rm = get_bit_range(insn, 0, 3);
bool reg = get_nth_bit(insn, 4);
ShiftType shift_type =
static_cast<ShiftType>(get_bit_range(insn, 5, 6));
uint8_t operand = get_bit_range(insn, (reg ? 8 : 7), 11);
offset = Shift{ .rm = rm,
.data = ShiftData{ .type = shift_type,
.immediate = !reg,
.operand = operand } };
} else {
offset = static_cast<uint16_t>(get_bit_range(insn, 0, 11));
}
data = SingleDataTransfer{ .offset = offset,
.rd = rd,
.rn = rn,
.load = load,
.write = write,
.byte = byte,
.up = up,
.pre = pre };
// Halfword transfer
} else if ((insn & 0x0E000090) == 0x00000090) {
uint8_t offset = get_bit_range(insn, 0, 3);
bool half = get_nth_bit(insn, 5);
bool sign = get_nth_bit(insn, 6);
uint8_t rd = get_bit_range(insn, 12, 15);
uint8_t rn = get_bit_range(insn, 16, 19);
bool load = get_nth_bit(insn, 20);
bool write = get_nth_bit(insn, 21);
bool imm = get_nth_bit(insn, 22);
bool up = get_nth_bit(insn, 23);
bool pre = get_nth_bit(insn, 24);
offset |= (imm ? get_bit_range(insn, 8, 11) << 2 : 0);
data = HalfwordTransfer{ .offset = offset,
.half = half,
.sign = sign,
.rd = rd,
.rn = rn,
.load = load,
.write = write,
.imm = imm,
.up = up,
.pre = pre };
// Block data transfer
} else if ((insn & 0x0E000000) == 0x08000000) {
/*static constexpr array<stringv, 2> syn = { "STM", "LDM" };
uint16_t regs = get_bit_range(insn, 0, 15);
uint8_t rn = get_bit_range(insn, 16, 19);
bool load = get_nth_bit(insn, 20);
bool write = get_nth_bit(insn, 21);
bool s = get_nth_bit(insn, 22);
bool up = get_nth_bit(insn, 23);
bool pre = get_nth_bit(insn, 24);
// disassembly
{
uint8_t lpu = load << 2 | pre << 1 | up;
std::string addr_mode;
switch(lpu) {
}
}*/
data = Undefined{};
// Software Interrupt
// What to do here?
} else if ((insn & 0x0F000000) == 0x0F000000) {
data = SoftwareInterrupt{};
// Coprocessor data transfer
} else if ((insn & 0x0E000000) == 0x0C000000) {
uint8_t offset = get_bit_range(insn, 0, 7);
uint8_t cpn = get_bit_range(insn, 8, 11);
uint8_t crd = get_bit_range(insn, 12, 15);
uint8_t rn = get_bit_range(insn, 16, 19);
bool load = get_nth_bit(insn, 20);
bool write = get_nth_bit(insn, 21);
bool len = get_nth_bit(insn, 22);
bool up = get_nth_bit(insn, 23);
bool pre = get_nth_bit(insn, 24);
data = CoprocessorDataTransfer{ .offset = offset,
.cpn = cpn,
.crd = crd,
.rn = rn,
.load = load,
.write = write,
.len = len,
.up = up,
.pre = pre };
// Coprocessor data operation
} else if ((insn & 0x0F000010) == 0x0E000000) {
uint8_t crm = get_bit_range(insn, 0, 4);
uint8_t cp = get_bit_range(insn, 5, 7);
uint8_t cpn = get_bit_range(insn, 8, 11);
uint8_t crd = get_bit_range(insn, 12, 15);
uint8_t crn = get_bit_range(insn, 16, 19);
uint8_t cp_opc = get_bit_range(insn, 20, 23);
data = CoprocessorDataOperation{ .crm = crm,
.cp = cp,
.cpn = cpn,
.crd = crd,
.crn = crn,
.cp_opc = cp_opc };
// Coprocessor register transfer
} else if ((insn & 0x0F000010) == 0x0E000010) {
uint8_t crm = get_bit_range(insn, 0, 4);
uint8_t cp = get_bit_range(insn, 5, 7);
uint8_t cpn = get_bit_range(insn, 8, 11);
uint8_t rd = get_bit_range(insn, 12, 15);
uint8_t crn = get_bit_range(insn, 16, 19);
bool load = get_nth_bit(insn, 20);
uint8_t cp_opc = get_bit_range(insn, 21, 23);
data = CoprocessorRegisterTransfer{ .crm = crm,
.cp = cp,
.cpn = cpn,
.rd = rd,
.crn = crn,
.load = load,
.cp_opc = cp_opc };
} else {
data = Undefined{};
}
}
std::string
ArmInstruction::disassemble() {
static const std::string undefined = "UNDEFINED";
// goddamn this is gore
// TODO: make this less ugly
return std::visit(
overloaded{
[this](BranchAndExchange& data) {
return fmt::format("BX{} R{:d}", condition, data.rn);
},
[this](Branch& data) {
return fmt::format(
"B{}{} {:#08X}", (data.link ? "L" : ""), condition, data.offset);
},
[this](Multiply& data) {
if (data.acc) {
return fmt::format("MLA{}{} R{:d},R{:d},R{:d},R{:d}",
condition,
(data.set ? "S" : ""),
data.rd,
data.rm,
data.rs,
data.rn);
} else {
return fmt::format("MUL{}{} R{:d},R{:d},R{:d}",
condition,
(data.set ? "S" : ""),
data.rd,
data.rm,
data.rs);
}
},
[this](MultiplyLong& data) {
return fmt::format("{}{}{}{} R{:d},R{:d},R{:d},R{:d}",
(data.uns ? 'U' : 'S'),
(data.acc ? "MLAL" : "MULL"),
condition,
(data.set ? "S" : ""),
data.rdlo,
data.rdhi,
data.rm,
data.rs);
},
[](Undefined) { return undefined; },
[this](SingleDataSwap& data) {
return fmt::format("SWP{}{} R{:d},R{:d},[R{:d}]",
condition,
(data.byte ? "B" : ""),
data.rd,
data.rm,
data.rn);
},
[this](SingleDataTransfer& data) {
std::string expression;
std::string address;
if (const uint16_t* offset = std::get_if<uint16_t>(&data.offset)) {
if (*offset == 0) {
expression = "";
} else {
expression = fmt::format(",#{:d}", *offset);
}
} else if (const Shift* shift = std::get_if<Shift>(&data.offset)) {
expression = fmt::format(",{}R{:d},{} {}{:d}",
(data.up ? '+' : '-'),
shift->rm,
shift->data.type,
(shift->data.immediate ? '#' : 'R'),
shift->data.operand);
}
return fmt::format(
"{}{}{}{} R{:d},[R{:d}{}]{}",
(data.load ? "LDR" : "STR"),
condition,
(data.byte ? "B" : ""),
(!data.pre && data.write ? "T" : ""),
data.rd,
data.rn,
(data.pre ? expression : ""),
(data.pre ? (data.write ? "!" : "") : expression));
},
[this](HalfwordTransfer& data) {
std::string expression;
if (data.imm) {
if (data.offset == 0) {
expression = "";
} else {
expression = fmt::format(",#{:d}", data.offset);
}
} else {
expression =
fmt::format(",{}R{:d}", (data.up ? '+' : '-'), data.offset);
}
return fmt::format(
"{}{}{}{} R{:d},[R{:d}{}]{}",
(data.load ? "LDR" : "STR"),
condition,
(data.sign ? "S" : ""),
(data.half ? 'H' : 'B'),
data.rd,
data.rn,
(data.pre ? expression : ""),
(data.pre ? (data.write ? "!" : "") : expression));
},
[this](SoftwareInterrupt) { return fmt::format("SWI{}", condition); },
[this](CoprocessorDataTransfer& data) {
std::string expression = fmt::format(",#{:d}", data.offset);
return fmt::format(
"{}{}{} p{:d},c{:d},[R{:d}{}]{}",
(data.load ? "LDC" : "STC"),
condition,
(data.len ? "L" : ""),
data.cpn,
data.crd,
data.rn,
(data.pre ? expression : ""),
(data.pre ? (data.write ? "!" : "") : expression));
},
[this](CoprocessorDataOperation& data) {
return fmt::format("CDP{} p{},{},c{},c{},c{},{}",
condition,
data.cpn,
data.cp_opc,
data.crd,
data.crn,
data.crm,
data.cp);
},
[this](CoprocessorRegisterTransfer& data) {
return fmt::format("{}{} p{},{},c{},c{},c{},{}",
(data.load ? "MRC" : "MCR"),
condition,
data.cpn,
data.cp_opc,
data.rd,
data.crn,
data.crm,
data.cp);
},
[](auto) { return undefined; } },
data);
}

132
src/cpu/instruction.hh
View File

@@ -1,132 +0,0 @@
#include "cpu/utility.hh"
#include <cstdint>
#include <variant>
template<class... Ts>
struct overloaded : Ts... {
using Ts::operator()...;
};
template<class... Ts>
overloaded(Ts...) -> overloaded<Ts...>;
class ArmInstruction {
public:
ArmInstruction() = delete;
ArmInstruction(uint32_t insn);
auto get_condition() const { return condition; }
auto get_data() const { return data; }
std::string disassemble();
struct BranchAndExchange {
uint8_t rn;
};
struct Branch {
bool link;
uint32_t offset;
};
struct Multiply {
uint8_t rm;
uint8_t rs;
uint8_t rn;
uint8_t rd;
bool set;
bool acc;
};
struct MultiplyLong {
uint8_t rm;
uint8_t rs;
uint8_t rdlo;
uint8_t rdhi;
bool set;
bool acc;
bool uns;
};
struct SingleDataSwap {
uint8_t rm;
uint8_t rd;
uint8_t rn;
bool byte;
};
struct SingleDataTransfer {
std::variant<uint16_t, Shift> offset;
uint8_t rd;
uint8_t rn;
bool load;
bool write;
bool byte;
bool up;
bool pre;
};
struct HalfwordTransfer {
uint8_t offset;
bool half;
bool sign;
uint8_t rd;
uint8_t rn;
bool load;
bool write;
bool byte;
bool imm;
bool up;
bool pre;
};
struct CoprocessorDataTransfer {
uint8_t offset;
uint8_t cpn;
uint8_t crd;
uint8_t rn;
bool load;
bool write;
bool len;
bool up;
bool pre;
};
struct CoprocessorDataOperation {
uint8_t crm;
uint8_t cp;
uint8_t cpn;
uint8_t crd;
uint8_t crn;
uint8_t cp_opc;
};
struct CoprocessorRegisterTransfer {
uint8_t crm;
uint8_t cp;
uint8_t cpn;
uint8_t rd;
uint8_t crn;
bool load;
uint8_t cp_opc;
};
struct Undefined {};
struct SoftwareInterrupt {};
using InstructionData = std::variant<BranchAndExchange,
Branch,
Multiply,
MultiplyLong,
SingleDataSwap,
SingleDataTransfer,
HalfwordTransfer,
CoprocessorDataTransfer,
CoprocessorDataOperation,
CoprocessorRegisterTransfer,
Undefined,
SoftwareInterrupt>;
private:
Condition condition;
InstructionData data;
};

8
src/cpu/meson.build
View File

@@ -1,6 +1,8 @@
lib_sources += files(
'cpu-impl.cc',
'cpu.cc',
'instruction.cc',
'psr.cc',
'utility.cc'
)
'alu.cc'
)
subdir('arm')

57
src/cpu/psr.cc
View File

@@ -2,9 +2,20 @@
#include "util/bits.hh"
#include "util/log.hh"
namespace matar {
Psr::Psr(uint32_t raw)
: psr(raw & PSR_CLEAR_RESERVED) {}
uint32_t
Psr::raw() const {
return psr;
}
void
Psr::set_all(uint32_t raw) {
psr = raw & ~PSR_CLEAR_RESERVED;
}
Mode
Psr::mode() const {
return static_cast<Mode>(psr & ~PSR_CLEAR_MODE);
@@ -18,20 +29,20 @@ Psr::set_mode(Mode mode) {
State
Psr::state() const {
return static_cast<State>(get_nth_bit(psr, 5));
return static_cast<State>(get_bit(psr, 5));
}
void
Psr::set_state(State state) {
chg_nth_bit(psr, 5, static_cast<bool>(state));
chg_bit(psr, 5, static_cast<bool>(state));
}
#define GET_SET_NTH_BIT_FUNCTIONS(name, n) \
bool Psr::name() const { \
return get_nth_bit(psr, n); \
return get_bit(psr, n); \
} \
void Psr::set_##name(bool val) { \
chg_nth_bit(psr, n, val); \
chg_bit(psr, n, val); \
}
GET_SET_NTH_BIT_FUNCTIONS(fiq_disabled, 6)
@@ -80,6 +91,42 @@ Psr::condition(Condition cond) const {
case Condition::LE:
return z() || (n() != v());
case Condition::AL:
return true;
return true && state() == State::Arm;
}
return false;
}
std::ostream&
operator<<(std::ostream& os, const Condition cond) {
#define CASE(cond) \
case Condition::cond: \
os << #cond; \
break;
switch (cond) {
CASE(EQ)
CASE(NE)
CASE(CS)
CASE(CC)
CASE(MI)
CASE(PL)
CASE(VS)
CASE(VC)
CASE(HI)
CASE(LS)
CASE(GE)
CASE(LT)
CASE(GT)
CASE(LE)
case Condition::AL: {
// empty
}
}
#undef CASE
return os;
}
}

54
src/cpu/psr.hh
View File

@@ -1,13 +1,51 @@
#pragma once
#include "utility.hh"
#include <cstdint>
#include <fmt/ostream.h>
namespace matar {
enum class Mode {
/* M[4:0] in PSR */
User = 0b10000,
Fiq = 0b10001,
Irq = 0b10010,
Supervisor = 0b10011,
Abort = 0b10111,
Undefined = 0b11011,
System = 0b11111,
};
enum class State {
Arm = 0,
Thumb = 1
};
enum class Condition {
EQ = 0b0000,
NE = 0b0001,
CS = 0b0010,
CC = 0b0011,
MI = 0b0100,
PL = 0b0101,
VS = 0b0110,
VC = 0b0111,
HI = 0b1000,
LS = 0b1001,
GE = 0b1010,
LT = 0b1011,
GT = 0b1100,
LE = 0b1101,
AL = 0b1110
};
class Psr {
public:
// clear the reserved bits i.e, [8:27]
Psr(uint32_t raw);
uint32_t raw() const;
void set_all(uint32_t raw);
// Mode : [4:0]
Mode mode() const;
void set_mode(Mode mode);
@@ -45,8 +83,18 @@ class Psr {
bool condition(Condition cond) const;
private:
static constexpr uint32_t PSR_CLEAR_RESERVED = 0xf00000ff;
static constexpr uint32_t PSR_CLEAR_MODE = 0x0b00000;
static constexpr uint32_t PSR_CLEAR_RESERVED = 0xF00000FF;
static constexpr uint32_t PSR_CLEAR_MODE = 0xFFFFFFE0;
uint32_t psr;
};
// https://fmt.dev/dev/api.html#std-ostream-support
std::ostream&
operator<<(std::ostream& os, const Condition cond);
}
namespace fmt {
template<>
struct formatter<matar::Condition> : ostream_formatter {};
}

97
src/cpu/utility.cc
View File

@@ -1,97 +0,0 @@
#include "utility.hh"
#include "util/bits.hh"
#include <bit>
std::ostream&
operator<<(std::ostream& os, const Condition cond) {
#define CASE(cond) \
case Condition::cond: \
os << #cond; \
break;
switch (cond) {
CASE(EQ)
CASE(NE)
CASE(CS)
CASE(CC)
CASE(MI)
CASE(PL)
CASE(VS)
CASE(VC)
CASE(HI)
CASE(LS)
CASE(GE)
CASE(LT)
CASE(GT)
CASE(LE)
case Condition::AL: {
// empty
}
}
#undef CASE
return os;
}
uint32_t
eval_shift(ShiftType shift_type, uint32_t value, uint8_t amount, bool& carry) {
switch (shift_type) {
case ShiftType::LSL:
if (amount > 0 && amount <= 32)
carry = get_nth_bit(value, 32 - amount);
else if (amount > 32)
carry = 0;
return value << amount;
case ShiftType::LSR:
if (amount > 0 && amount <= 32)
carry = get_nth_bit(value, amount - 1);
else if (amount > 32)
carry = 0;
else
carry = get_nth_bit(value, 31);
return value >> amount;
case ShiftType::ASR:
if (amount > 0 && amount <= 32)
carry = get_nth_bit(value, amount - 1);
else
carry = get_nth_bit(value, 31);
return static_cast<int32_t>(value) >> amount;
case ShiftType::ROR:
if (amount == 0) {
bool old_carry = carry;
carry = get_nth_bit(value, 0);
return (value >> 1) | (old_carry << 31);
} else {
carry = get_nth_bit(value, (amount % 32 + 31) % 32);
return std::rotr(value, amount);
}
}
}
std::ostream&
operator<<(std::ostream& os, const ShiftType shift_type) {
#define CASE(type) \
case ShiftType::type: \
os << #type; \
break;
switch (shift_type) {
CASE(LSL)
CASE(LSR)
CASE(ASR)
CASE(ROR)
}
#undef CASE
return os;
}

93
src/cpu/utility.hh
View File

@@ -1,93 +0,0 @@
#pragma once
#include <fmt/ostream.h>
#include <ostream>
static constexpr size_t ARM_INSTRUCTION_SIZE = 4;
static constexpr size_t THUMB_INSTRUCTION_SIZE = 2;
enum class Mode {
/* M[4:0] in PSR */
User = 0b10000,
Fiq = 0b10001,
Irq = 0b10010,
Supervisor = 0b10011,
Abort = 0b10111,
Undefined = 0b11011,
System = 0b11111,
};
enum class State {
Arm = 0,
Thumb = 1
};
enum class Condition {
EQ = 0b0000,
NE = 0b0001,
CS = 0b0010,
CC = 0b0011,
MI = 0b0100,
PL = 0b0101,
VS = 0b0110,
VC = 0b0111,
HI = 0b1000,
LS = 0b1001,
GE = 0b1010,
LT = 0b1011,
GT = 0b1100,
LE = 0b1101,
AL = 0b1110
};
// https://fmt.dev/dev/api.html#std-ostream-support
std::ostream&
operator<<(std::ostream& os, const Condition cond);
template<>
struct fmt::formatter<Condition> : ostream_formatter {};
enum class OpCode {
AND = 0b0000,
EOR = 0b0001,
SUB = 0b0010,
RSB = 0b0011,
ADD = 0b0100,
ADC = 0b0101,
SBC = 0b0110,
RSC = 0b0111,
TST = 0b1000,
TEQ = 0b1001,
CMP = 0b1010,
CMN = 0b1011,
ORR = 0b1100,
MOV = 0b1101,
BIC = 0b1110,
MVN = 0b1111
};
enum class ShiftType {
LSL = 0b00,
LSR = 0b01,
ASR = 0b10,
ROR = 0b11
};
struct ShiftData {
ShiftType type;
bool immediate;
uint8_t operand;
};
struct Shift {
uint8_t rm;
ShiftData data;
};
uint32_t
eval_shift(ShiftType shift_type, uint32_t value, uint8_t amount, bool& carry);
// https://fmt.dev/dev/api.html#std-ostream-support
std::ostream&
operator<<(std::ostream& os, const ShiftType cond);
template<>
struct fmt::formatter<ShiftType> : ostream_formatter {};

45
src/header.hh
View File

@@ -1,45 +0,0 @@
#pragma once
#include <cstdint>
#include <string>
#include <vector>
struct Header {
enum class UniqueCode {
Old, // old games
New, // new games
Newer, // unused (newer games)
Famicom, // NES
YoshiKoro, // acceleration sensor
Ereader, // dot code scanner
Warioware, // rumble and z-axis gyro
Boktai, // RTC and solar sensor
DrillDozer, // rumble
};
enum class I18n {
Japan,
Europe,
French,
Spanish,
Usa,
German,
Italian
};
enum class BootMode {
Joybus,
Normal,
Multiplay
};
uint32_t entrypoint;
std::string title;
std::string title_code;
UniqueCode unique_code;
I18n i18n;
uint8_t version;
BootMode multiboot;
uint32_t multiboot_entrypoint;
uint8_t slave_id;
};

85
src/memory.cc
View File

@@ -1,14 +1,14 @@
#include "memory.hh"
#include "header.hh"
#include "util/bits.hh"
#include "util/crypto.hh"
#include "util/log.hh"
#include "util/utils.hh"
#include <bitset>
#include <stdexcept>
using namespace logger;
namespace matar {
Memory::Memory(std::array<uint8_t, BIOS_SIZE>&& bios,
std::vector<uint8_t>&& rom) noexcept
std::vector<uint8_t>&& rom)
: bios(std::move(bios))
, board_wram({ 0 })
, chip_wram({ 0 })
@@ -21,17 +21,17 @@ Memory::Memory(std::array<uint8_t, BIOS_SIZE>&& bios,
"fd2547724b505f487e6dcb29ec2ecff3af35a841a77ab2e85fd87350abd36570";
if (bios_hash != expected_hash) {
log_warn("BIOS hash failed to match, run at your own risk"
"\nExpected : {} "
"\nGot : {}",
expected_hash,
bios_hash);
glogger.warn("BIOS hash failed to match, run at your own risk"
"\nExpected : {} "
"\nGot : {}",
expected_hash,
bios_hash);
}
parse_header();
log_info("Memory successfully initialised");
log_info("Cartridge Title: {}", header.title);
glogger.info("Memory successfully initialised");
glogger.info("Cartridge Title: {}", header.title);
};
#define MATCHES(area) address >= area##_START&& address <= area##_END
@@ -57,8 +57,8 @@ Memory::read(size_t address) const {
} else if (MATCHES(ROM_2)) {
return rom[address - ROM_2_START];
} else {
log_error("Invalid memory region accessed");
return 0;
glogger.error("Invalid memory region accessed");
return 0xFF;
}
}
@@ -83,58 +83,27 @@ Memory::write(size_t address, uint8_t byte) {
} else if (MATCHES(ROM_2)) {
rom[address - ROM_2_START] = byte;
} else {
log_error("Invalid memory region accessed");
glogger.error("Invalid memory region accessed");
}
}
#undef MATCHES
uint16_t
Memory::read_halfword(size_t address) const {
if (address & 0b01)
log_warn("Reading a non aligned halfword address");
return read(address) | read(address + 1) << 8;
}
void
Memory::write_halfword(size_t address, uint16_t halfword) {
if (address & 0b01)
log_warn("Writing to a non aligned halfword address");
write(address, halfword & 0xFF);
write(address + 1, halfword >> 8 & 0xFF);
}
uint32_t
Memory::read_word(size_t address) const {
if (address & 0b11)
log_warn("Reading a non aligned word address");
return read(address) | read(address + 1) << 8 | read(address + 2) << 16 |
read(address + 3) << 24;
}
void
Memory::write_word(size_t address, uint32_t halfword) {
if (address & 0b11)
log_warn("Writing to a non aligned word address");
write(address, halfword & 0xFF);
write(address + 1, halfword >> 8 & 0xFF);
write(address + 2, halfword >> 16 & 0xFF);
write(address + 3, halfword >> 24 & 0xFF);
}
void
Memory::parse_header() {
if (rom.size() < header.HEADER_SIZE) {
throw std::out_of_range(
"ROM is not large enough to even have a header");
}
// entrypoint
header.entrypoint =
rom[0x00] | rom[0x01] << 8 | rom[0x02] << 16 | rom[0x03] << 24;
// nintendo logo
if (rom[0x9C] != 0x21)
log_info("HEADER: BIOS debugger bits not set to 0");
glogger.info("HEADER: BIOS debugger bits not set to 0");
// game info
header.title = std::string(&rom[0xA0], &rom[0xA0 + 12]);
@@ -169,7 +138,7 @@ Memory::parse_header() {
break;
default:
log_error("HEADER: invalid unique code: {}", rom[0xAC]);
glogger.error("HEADER: invalid unique code: {}", rom[0xAC]);
}
header.title_code = std::string(&rom[0xAD], &rom[0xAE]);
@@ -198,15 +167,16 @@ Memory::parse_header() {
break;
default:
log_error("HEADER: invalid destination/language: {}", rom[0xAF]);
glogger.error("HEADER: invalid destination/language: {}",
rom[0xAF]);
}
if (rom[0xB2] != 0x96)
log_error("HEADER: invalid fixed byte at 0xB2");
glogger.error("HEADER: invalid fixed byte at 0xB2");
for (size_t i = 0xB5; i < 0xBC; i++) {
if (rom[i] != 0x00)
log_error("HEADER: invalid fixed bytes at 0xB5");
glogger.error("HEADER: invalid fixed bytes at 0xB5");
}
header.version = rom[0xBC];
@@ -220,8 +190,9 @@ Memory::parse_header() {
chk &= 0xFF;
if (chk != rom[0xBD])
log_error("HEADER: checksum does not match");
glogger.error("HEADER: checksum does not match");
}
// multiboot not required right now
}
}

64
src/memory.hh
View File

@@ -1,64 +0,0 @@
#pragma once
#include "header.hh"
#include <array>
#include <cstddef>
#include <cstdint>
#include <vector>
class Memory {
public:
static constexpr size_t BIOS_SIZE = 1024 * 16;
Memory(std::array<uint8_t, BIOS_SIZE>&& bios,
std::vector<uint8_t>&& rom) noexcept;
uint8_t read(size_t address) const;
void write(size_t address, uint8_t byte);
uint16_t read_halfword(size_t address) const;
void write_halfword(size_t address, uint16_t halfword);
uint32_t read_word(size_t address) const;
void write_word(size_t address, uint32_t word);
private:
#define MEMORY_REGION(name, start, end) \
static constexpr size_t name##_START = start; \
static constexpr size_t name##_END = end;
#define DECL_MEMORY(name, ident, start, end) \
MEMORY_REGION(name, start, end) \
std::array<uint8_t, name##_END - name##_START + 1> ident;
MEMORY_REGION(BIOS, 0x00000000, 0x00003FFF)
std::array<uint8_t, BIOS_SIZE> bios;
static_assert(BIOS_END - BIOS_START + 1 == BIOS_SIZE);
// board working RAM
DECL_MEMORY(BOARD_WRAM, board_wram, 0x02000000, 0x0203FFFF)
// chip working RAM
DECL_MEMORY(CHIP_WRAM, chip_wram, 0x03000000, 0x03007FFF)
// palette RAM
DECL_MEMORY(PALETTE_RAM, palette_ram, 0x05000000, 0x050003FF)
// video RAM
DECL_MEMORY(VRAM, vram, 0x06000000, 0x06017FFF)
// OAM OBJ attributes
DECL_MEMORY(OAM_OBJ_ATTR, oam_obj_attr, 0x07000000, 0x070003FF)
#undef DECL_MEMORY
MEMORY_REGION(ROM_0, 0x08000000, 0x09FFFFFF)
MEMORY_REGION(ROM_1, 0x0A000000, 0x0BFFFFFF)
MEMORY_REGION(ROM_2, 0x0C000000, 0x0DFFFFFF)
#undef MEMORY_REGION
std::vector<uint8_t> rom;
Header header;
void parse_header();
};

13
src/meson.build
View File

@@ -3,15 +3,24 @@ lib_sources = files(
'bus.cc'
)
subdir('util')
subdir('cpu')
fmt = dependency('fmt', version : '>=10.1.0')
lib_cpp_args = [ ]
fmt = dependency('fmt', version : '>=10.1.0', static: true)
if not fmt.found()
fmt = dependency('fmt', version : '>=10.1.0', static: false)
lib_cpp_args += 'DFMT_HEADER_ONLY'
endif
lib = library(
meson.project_name(),
lib_sources,
dependencies: [fmt],
include_directories: inc,
install: true,
cpp_args: '-DFMT_HEADER_ONLY'
cpp_args: lib_cpp_args
)
import('pkgconfig').generate(lib)

18
src/util/bits.hh
View File

@@ -7,34 +7,34 @@ using std::size_t;
template<std::integral Int>
inline bool
get_nth_bit(Int num, size_t n) {
get_bit(Int num, size_t n) {
return (num >> n) & 1;
}
template<std::integral Int>
inline void
set_nth_bit(Int& num, size_t n) {
num |= (1 << n);
set_bit(Int& num, size_t n) {
num |= (static_cast<Int>(1) << n);
}
template<std::integral Int>
inline void
rst_nth_bit(Int& num, size_t n) {
num &= ~(1 << n);
rst_bit(Int& num, size_t n) {
num &= ~(static_cast<Int>(1) << n);
}
template<std::integral Int>
inline void
chg_nth_bit(Int& num, size_t n, bool x) {
num = (num & ~(1 << n)) | (x << n);
chg_bit(Int& num, size_t n, bool x) {
num = (num & ~(static_cast<Int>(1) << n)) | (static_cast<Int>(x) << n);
}
/// read range of bits from start to end inclusive
template<std::integral Int>
inline Int
get_bit_range(Int num, size_t start, size_t end) {
bit_range(Int num, size_t start, size_t end) {
// NOTE: we do not require -1 if it is a signed integral
Int left =
std::numeric_limits<Int>::digits - (std::is_unsigned<Int>::value) - end;
return num << left >> (left + start);
return static_cast<Int>(num << left) >> (left + start);
}

2
src/util/utils.hh → src/util/crypto.hh
View File

@@ -3,8 +3,6 @@
#include <array>
#include <bit>
#include <fmt/core.h>
#include <iomanip>
#include <sstream>
#include <string>
// Why I wrote this myself? I do not know

8
src/util/log.cc Normal file
View File

@@ -0,0 +1,8 @@
#include "log.hh"
logging::Logger glogger = logging::Logger();
void
matar::set_log_level(LogLevel level) {
glogger.set_level(level);
}

119
src/util/log.hh
View File

@@ -1,58 +1,83 @@
#pragma once
#include "util/loglevel.hh"
#include <fmt/ostream.h>
#include <iostream>
using fmt::print;
using std::clog;
namespace logger {
namespace logging {
namespace ansi {
static constexpr std::string_view RED = "\033[31m";
static constexpr std::string_view YELLOW = "\033[33m";
static constexpr std::string_view MAGENTA = "\033[35m";
static constexpr std::string_view WHITE = "\033[37m";
static constexpr std::string_view BOLD = "\033[1m";
static constexpr std::string_view RESET = "\033[0m";
static constexpr auto RED = "\033[31m";
static constexpr auto YELLOW = "\033[33m";
static constexpr auto MAGENTA = "\033[35m";
static constexpr auto WHITE = "\033[37m";
static constexpr auto BOLD = "\033[1m";
static constexpr auto RESET = "\033[0m";
}
template<typename... Args>
inline void
log_raw(const fmt::format_string<Args...>& fmt, Args&&... args) {
fmt::println(clog, fmt, std::forward<Args>(args)...);
using fmt::print;
class Logger {
using LogLevel = matar::LogLevel;
public:
Logger(LogLevel level = LogLevel::Debug, FILE* stream = stderr)
: level(0)
, stream(stream) {
set_level(level);
}
template<typename... Args>
void log(const fmt::format_string<Args...>& fmt, Args&&... args) {
fmt::println(stream, fmt, std::forward<Args>(args)...);
}
template<typename... Args>
void debug(const fmt::format_string<Args...>& fmt, Args&&... args) {
if (level & static_cast<uint8_t>(LogLevel::Debug)) {
print(stream, "{}{}[DEBUG] ", ansi::MAGENTA, ansi::BOLD);
log(fmt, std::forward<Args>(args)...);
print(stream, ansi::RESET);
}
}
template<typename... Args>
void info(const fmt::format_string<Args...>& fmt, Args&&... args) {
if (level & static_cast<uint8_t>(LogLevel::Info)) {
print(stream, "{}[INFO] ", ansi::WHITE);
log(fmt, std::forward<Args>(args)...);
print(stream, ansi::RESET);
}
}
template<typename... Args>
void warn(const fmt::format_string<Args...>& fmt, Args&&... args) {
if (level & static_cast<uint8_t>(LogLevel::Warn)) {
print(stream, "{}[WARN] ", ansi::YELLOW);
log(fmt, std::forward<Args>(args)...);
print(stream, ansi::RESET);
}
}
template<typename... Args>
void error(const fmt::format_string<Args...>& fmt, Args&&... args) {
if (level & static_cast<uint8_t>(LogLevel::Error)) {
print(stream, "{}{}[ERROR] ", ansi::RED, ansi::BOLD);
log(fmt, std::forward<Args>(args)...);
print(stream, ansi::RESET);
}
}
void set_level(LogLevel level) {
this->level = (static_cast<uint8_t>(level) << 1) - 1;
}
void set_stream(FILE* stream) { this->stream = stream; }
private:
uint8_t level;
FILE* stream;
};
}
template<typename... Args>
inline void
log_debug(const fmt::format_string<Args...>& fmt, Args&&... args) {
print(clog, "{}{}[DEBUG] ", ansi::MAGENTA, ansi::BOLD);
log_raw(fmt, std::forward<Args>(args)...);
print(clog, ansi::RESET);
}
extern logging::Logger glogger;
template<typename... Args>
inline void
log_info(const fmt::format_string<Args...>& fmt, Args&&... args) {
print(clog, "{}[INFO] ", ansi::WHITE);
log_raw(fmt, std::forward<Args>(args)...);
print(clog, ansi::RESET);
}
template<typename... Args>
inline void
log_warn(const fmt::format_string<Args...>& fmt, Args&&... args) {
print(clog, "{}[WARN] ", ansi::YELLOW);
log_raw(fmt, std::forward<Args>(args)...);
print(clog, ansi::RESET);
}
template<typename... Args>
inline void
log_error(const fmt::format_string<Args...>& fmt, Args&&... args) {
print(clog, "{}{}[ERROR] ", ansi::RED, ansi::BOLD);
log_raw(fmt, std::forward<Args>(args)...);
print(clog, ansi::RESET);
}
}
#define debug(value) logger::log_debug("{} = {}", #value, value)
#define debug(x) glogger.debug("{} = {}", #x, x);

3
src/util/meson.build Normal file
View File

@@ -0,0 +1,3 @@
lib_sources += files(
'log.cc'
)

43
tests/bus.cc Normal file
View File

@@ -0,0 +1,43 @@
#include "bus.hh"
#include <catch2/catch_test_macros.hpp>
static constexpr auto TAG = "[bus]";
using namespace matar;
class BusFixture {
public:
BusFixture()
: bus(Memory(std::array<uint8_t, Memory::BIOS_SIZE>(),
std::vector<uint8_t>(Header::HEADER_SIZE))) {}
protected:
Bus bus;
};
TEST_CASE_METHOD(BusFixture, "Byte", TAG) {
CHECK(bus.read_byte(3349) == 0);
bus.write_byte(3349, 0xEC);
CHECK(bus.read_byte(3349) == 0xEC);
CHECK(bus.read_word(3349) == 0xEC);
CHECK(bus.read_halfword(3349) == 0xEC);
}
TEST_CASE_METHOD(BusFixture, "Halfword", TAG) {
CHECK(bus.read_halfword(33750745) == 0);
bus.write_halfword(33750745, 0x1A4A);
CHECK(bus.read_halfword(33750745) == 0x1A4A);
CHECK(bus.read_word(33750745) == 0x1A4A);
CHECK(bus.read_byte(33750745) == 0x4A);
}
TEST_CASE_METHOD(BusFixture, "Word", TAG) {
CHECK(bus.read_word(100724276) == 0);
bus.write_word(100724276, 0x3ACC491D);
CHECK(bus.read_word(100724276) == 0x3ACC491D);
CHECK(bus.read_halfword(100724276) == 0x491D);
CHECK(bus.read_byte(100724276) == 0x1D);
}

1072
tests/cpu/arm/exec.cc Normal file
View File

File diff suppressed because it is too large Load Diff

469
tests/cpu/arm/instruction.cc Normal file
View File

@@ -0,0 +1,469 @@
#include "cpu/arm/instruction.hh"
#include <catch2/catch_test_macros.hpp>
static constexpr auto TAG = "[arm][disassembly]";
using namespace matar;
using namespace arm;
TEST_CASE("Branch and Exchange", TAG) {
uint32_t raw = 0b11000001001011111111111100011010;
Instruction instruction(raw);
BranchAndExchange* bx = nullptr;
REQUIRE((bx = std::get_if<BranchAndExchange>(&instruction.data)));
CHECK(instruction.condition == Condition::GT);
CHECK(bx->rn == 10);
CHECK(instruction.disassemble() == "BXGT R10");
}
TEST_CASE("Branch", TAG) {
uint32_t raw = 0b11101011100001010111111111000011;
Instruction instruction(raw);
Branch* b = nullptr;
REQUIRE((b = std::get_if<Branch>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
// last 24 bits = 8748995
// (8748995 << 8) >> 6 sign extended = 0xFE15FF0C
// Also +8 since PC is two instructions ahead
CHECK(b->offset == 0xFE15FF14);
CHECK(b->link == true);
CHECK(instruction.disassemble() == "BL 0xFE15FF14");
b->link = false;
CHECK(instruction.disassemble() == "B 0xFE15FF14");
}
TEST_CASE("Multiply", TAG) {
uint32_t raw = 0b00000000001110101110111110010000;
Instruction instruction(raw);
Multiply* mul = nullptr;
REQUIRE((mul = std::get_if<Multiply>(&instruction.data)));
CHECK(instruction.condition == Condition::EQ);
CHECK(mul->rm == 0);
CHECK(mul->rs == 15);
CHECK(mul->rn == 14);
CHECK(mul->rd == 10);
CHECK(mul->acc == true);
CHECK(mul->set == true);
CHECK(instruction.disassemble() == "MLAEQS R10,R0,R15,R14");
mul->acc = false;
mul->set = false;
CHECK(instruction.disassemble() == "MULEQ R10,R0,R15");
}
TEST_CASE("Multiply Long", TAG) {
uint32_t raw = 0b00010000100111100111011010010010;
Instruction instruction(raw);
MultiplyLong* mull = nullptr;
REQUIRE((mull = std::get_if<MultiplyLong>(&instruction.data)));
CHECK(instruction.condition == Condition::NE);
CHECK(mull->rm == 2);
CHECK(mull->rs == 6);
CHECK(mull->rdlo == 7);
CHECK(mull->rdhi == 14);
CHECK(mull->acc == false);
CHECK(mull->set == true);
CHECK(mull->uns == true);
CHECK(instruction.disassemble() == "UMULLNES R7,R14,R2,R6");
mull->acc = true;
CHECK(instruction.disassemble() == "UMLALNES R7,R14,R2,R6");
mull->uns = false;
mull->set = false;
CHECK(instruction.disassemble() == "SMLALNE R7,R14,R2,R6");
}
TEST_CASE("Undefined", TAG) {
// notice how this is the same as single data transfer except the shift
// is now a register based shift
uint32_t raw = 0b11100111101000101010111100010110;
Instruction instruction(raw);
CHECK(instruction.condition == Condition::AL);
CHECK(instruction.disassemble() == "UND");
}
TEST_CASE("Single Data Swap", TAG) {
uint32_t raw = 0b10100001000010010101000010010110;
Instruction instruction(raw);
SingleDataSwap* swp = nullptr;
REQUIRE((swp = std::get_if<SingleDataSwap>(&instruction.data)));
CHECK(instruction.condition == Condition::GE);
CHECK(swp->rm == 6);
CHECK(swp->rd == 5);
CHECK(swp->rn == 9);
CHECK(swp->byte == false);
CHECK(instruction.disassemble() == "SWPGE R5,R6,[R9]");
swp->byte = true;
CHECK(instruction.disassemble() == "SWPGEB R5,R6,[R9]");
}
TEST_CASE("Single Data Transfer", TAG) {
uint32_t raw = 0b11100111101000101010111100000110;
Instruction instruction(raw);
SingleDataTransfer* ldr = nullptr;
Shift* shift = nullptr;
REQUIRE((ldr = std::get_if<SingleDataTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
REQUIRE((shift = std::get_if<Shift>(&ldr->offset)));
CHECK(shift->rm == 6);
CHECK(shift->data.immediate == true);
CHECK(shift->data.type == ShiftType::LSL);
CHECK(shift->data.operand == 30);
CHECK(ldr->rd == 10);
CHECK(ldr->rn == 2);
CHECK(ldr->load == false);
CHECK(ldr->write == true);
CHECK(ldr->byte == false);
CHECK(ldr->up == true);
CHECK(ldr->pre == true);
ldr->load = true;
ldr->byte = true;
ldr->write = false;
shift->data.type = ShiftType::ROR;
CHECK(instruction.disassemble() == "LDRB R10,[R2,+R6,ROR #30]");
ldr->up = false;
ldr->pre = false;
CHECK(instruction.disassemble() == "LDRB R10,[R2],-R6,ROR #30");
ldr->offset = static_cast<uint16_t>(9023);
CHECK(instruction.disassemble() == "LDRB R10,[R2],-#9023");
ldr->pre = true;
CHECK(instruction.disassemble() == "LDRB R10,[R2,-#9023]");
}
TEST_CASE("Halfword Transfer", TAG) {
uint32_t raw = 0b00110001101011110010000010110110;
Instruction instruction(raw);
HalfwordTransfer* ldr = nullptr;
REQUIRE((ldr = std::get_if<HalfwordTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::CC);
// offset is not immediate
CHECK(ldr->imm == 0);
// hence this offset is a register number (rm)
CHECK(ldr->offset == 6);
CHECK(ldr->half == true);
CHECK(ldr->sign == false);
CHECK(ldr->rd == 2);
CHECK(ldr->rn == 15);
CHECK(ldr->load == false);
CHECK(ldr->write == true);
CHECK(ldr->up == true);
CHECK(ldr->pre == true);
CHECK(instruction.disassemble() == "STRCCH R2,[R15,+R6]!");
ldr->pre = false;
ldr->load = true;
ldr->sign = true;
ldr->up = false;
CHECK(instruction.disassemble() == "LDRCCSH R2,[R15],-R6");
ldr->half = false;
CHECK(instruction.disassemble() == "LDRCCSB R2,[R15],-R6");
ldr->load = false;
// not a register anymore
ldr->imm = 1;
ldr->offset = 90;
CHECK(instruction.disassemble() == "STRCCSB R2,[R15],-#90");
}
TEST_CASE("Block Data Transfer", TAG) {
uint32_t raw = 0b10011001010101110100000101101101;
Instruction instruction(raw);
BlockDataTransfer* ldm = nullptr;
REQUIRE((ldm = std::get_if<BlockDataTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::LS);
{
uint16_t regs = 0;
regs |= 1 << 0;
regs |= 1 << 2;
regs |= 1 << 3;
regs |= 1 << 5;
regs |= 1 << 6;
regs |= 1 << 8;
regs |= 1 << 14;
CHECK(ldm->regs == regs);
}
CHECK(ldm->rn == 7);
CHECK(ldm->load == true);
CHECK(ldm->write == false);
CHECK(ldm->s == true);
CHECK(ldm->up == false);
CHECK(ldm->pre == true);
CHECK(instruction.disassemble() == "LDMLSDB R7,{R0,R2,R3,R5,R6,R8,R14}^");
ldm->write = true;
ldm->s = false;
ldm->up = true;
CHECK(instruction.disassemble() == "LDMLSIB R7!,{R0,R2,R3,R5,R6,R8,R14}");
ldm->regs &= ~(1 << 6);
ldm->regs &= ~(1 << 3);
ldm->regs &= ~(1 << 8);
ldm->load = false;
ldm->pre = false;
CHECK(instruction.disassemble() == "STMLSIA R7!,{R0,R2,R5,R14}");
}
TEST_CASE("PSR Transfer", TAG) {
PsrTransfer* msr = nullptr;
SECTION("MRS") {
uint32_t raw = 0b01000001010011111010000000000000;
Instruction instruction(raw);
PsrTransfer* mrs = nullptr;
REQUIRE((mrs = std::get_if<PsrTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::MI);
CHECK(mrs->type == PsrTransfer::Type::Mrs);
// Operand is a register in the case of MRS (PSR -> Register)
CHECK(mrs->operand == 10);
CHECK(mrs->spsr == true);
CHECK(instruction.disassemble() == "MRSMI R10,SPSR_all");
}
SECTION("MSR") {
uint32_t raw = 0b11100001001010011111000000001000;
Instruction instruction(raw);
PsrTransfer* msr = nullptr;
REQUIRE((msr = std::get_if<PsrTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
CHECK(msr->type == PsrTransfer::Type::Msr);
// Operand is a register in the case of MSR (Register -> PSR)
CHECK(msr->operand == 8);
CHECK(msr->spsr == false);
CHECK(instruction.disassemble() == "MSR CPSR_all,R8");
}
SECTION("MSR_flg with register operand") {
uint32_t raw = 0b01100001001010001111000000001000;
Instruction instruction(raw);
REQUIRE((msr = std::get_if<PsrTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::VS);
CHECK(msr->type == PsrTransfer::Type::Msr_flg);
CHECK(msr->imm == 0);
CHECK(msr->operand == 8);
CHECK(msr->spsr == false);
CHECK(instruction.disassemble() == "MSRVS CPSR_flg,R8");
}
SECTION("MSR_flg with immediate operand") {
uint32_t raw = 0b11100011011010001111011101101000;
Instruction instruction(raw);
REQUIRE((msr = std::get_if<PsrTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
CHECK(msr->type == PsrTransfer::Type::Msr_flg);
CHECK(msr->imm == 1);
// 104 (32 bits) rotated by 2 * 7
CHECK(msr->operand == 27262976);
CHECK(msr->spsr == true);
CHECK(instruction.disassemble() == "MSR SPSR_flg,#27262976");
}
}
TEST_CASE("Data Processing", TAG) {
using OpCode = DataProcessing::OpCode;
uint32_t raw = 0b11100000000111100111101101100001;
Instruction instruction(raw);
DataProcessing* alu = nullptr;
Shift* shift = nullptr;
REQUIRE((alu = std::get_if<DataProcessing>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
// operand 2 is a shifted register
REQUIRE((shift = std::get_if<Shift>(&alu->operand)));
CHECK(shift->rm == 1);
CHECK(shift->data.immediate == true);
CHECK(shift->data.type == ShiftType::ROR);
CHECK(shift->data.operand == 22);
CHECK(alu->rd == 7);
CHECK(alu->rn == 14);
CHECK(alu->set == true);
CHECK(alu->opcode == OpCode::AND);
CHECK(instruction.disassemble() == "ANDS R7,R14,R1,ROR #22");
shift->data.immediate = false;
shift->data.operand = 2;
alu->set = false;
CHECK(instruction.disassemble() == "AND R7,R14,R1,ROR R2");
alu->operand = static_cast<uint32_t>(3300012);
CHECK(instruction.disassemble() == "AND R7,R14,#3300012");
SECTION("set-only operations") {
alu->set = true;
alu->opcode = OpCode::TST;
CHECK(instruction.disassemble() == "TST R14,#3300012");
alu->opcode = OpCode::TEQ;
CHECK(instruction.disassemble() == "TEQ R14,#3300012");
alu->opcode = OpCode::CMP;
CHECK(instruction.disassemble() == "CMP R14,#3300012");
alu->opcode = OpCode::CMN;
CHECK(instruction.disassemble() == "CMN R14,#3300012");
}
SECTION("destination operations") {
alu->opcode = OpCode::EOR;
CHECK(instruction.disassemble() == "EOR R7,R14,#3300012");
alu->opcode = OpCode::SUB;
CHECK(instruction.disassemble() == "SUB R7,R14,#3300012");
alu->opcode = OpCode::RSB;
CHECK(instruction.disassemble() == "RSB R7,R14,#3300012");
alu->opcode = OpCode::SUB;
CHECK(instruction.disassemble() == "SUB R7,R14,#3300012");
alu->opcode = OpCode::ADC;
CHECK(instruction.disassemble() == "ADC R7,R14,#3300012");
alu->opcode = OpCode::SBC;
CHECK(instruction.disassemble() == "SBC R7,R14,#3300012");
alu->opcode = OpCode::RSC;
CHECK(instruction.disassemble() == "RSC R7,R14,#3300012");
alu->opcode = OpCode::ORR;
CHECK(instruction.disassemble() == "ORR R7,R14,#3300012");
alu->opcode = OpCode::MOV;
CHECK(instruction.disassemble() == "MOV R7,#3300012");
alu->opcode = OpCode::BIC;
CHECK(instruction.disassemble() == "BIC R7,R14,#3300012");
alu->opcode = OpCode::MVN;
CHECK(instruction.disassemble() == "MVN R7,#3300012");
}
}
TEST_CASE("Coprocessor Data Transfer", TAG) {
uint32_t raw = 0b10101101101001011111000101000110;
Instruction instruction(raw);
CoprocessorDataTransfer* ldc = nullptr;
REQUIRE((ldc = std::get_if<CoprocessorDataTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::GE);
CHECK(ldc->offset == 70);
CHECK(ldc->cpn == 1);
CHECK(ldc->crd == 15);
CHECK(ldc->rn == 5);
CHECK(ldc->load == false);
CHECK(ldc->write == true);
CHECK(ldc->len == false);
CHECK(ldc->up == true);
CHECK(ldc->pre == true);
CHECK(instruction.disassemble() == "STCGE p1,c15,[R5,#70]!");
ldc->load = true;
ldc->pre = false;
ldc->write = false;
ldc->len = true;
CHECK(instruction.disassemble() == "LDCGEL p1,c15,[R5],#70");
}
TEST_CASE("Coprocessor Operand Operation", TAG) {
uint32_t raw = 0b11101110101001011111000101000110;
Instruction instruction(raw);
CoprocessorDataOperation* cdp = nullptr;
REQUIRE((cdp = std::get_if<CoprocessorDataOperation>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
CHECK(cdp->crm == 6);
CHECK(cdp->cp == 2);
CHECK(cdp->cpn == 1);
CHECK(cdp->crd == 15);
CHECK(cdp->crn == 5);
CHECK(cdp->cp_opc == 10);
CHECK(instruction.disassemble() == "CDP p1,10,c15,c5,c6,2");
}
TEST_CASE("Coprocessor Register Transfer", TAG) {
uint32_t raw = 0b11101110101001011111000101010110;
Instruction instruction(raw);
CoprocessorRegisterTransfer* mrc = nullptr;
REQUIRE(
(mrc = std::get_if<CoprocessorRegisterTransfer>(&instruction.data)));
CHECK(instruction.condition == Condition::AL);
CHECK(mrc->crm == 6);
CHECK(mrc->cp == 2);
CHECK(mrc->cpn == 1);
CHECK(mrc->rd == 15);
CHECK(mrc->crn == 5);
CHECK(mrc->load == false);
CHECK(mrc->cp_opc == 5);
CHECK(instruction.disassemble() == "MCR p1,5,R15,c5,c6,2");
}
TEST_CASE("Software Interrupt", TAG) {
uint32_t raw = 0b00001111101010101010101010101010;
Instruction instruction(raw);
CHECK(instruction.condition == Condition::EQ);
CHECK(instruction.disassemble() == "SWIEQ");
}

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tests/cpu/arm/meson.build Normal file
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tests_sources += files(
'instruction.cc',
'exec.cc'
)

1
tests/cpu/meson.build Normal file
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subdir('arm')

8
tests/main.cc Normal file
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#include "util/loglevel.hh"
#include <catch2/catch_session.hpp>
int
main(int argc, char* argv[]) {
matar::set_log_level(matar::LogLevel::Off);
return Catch::Session().run(argc, argv);
}

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#include "memory.hh"
#include <catch2/catch_test_macros.hpp>
static constexpr auto TAG = "[memory]";
using namespace matar;
class MemFixture {
public:
MemFixture()
: memory(std::array<uint8_t, Memory::BIOS_SIZE>(),
std::vector<uint8_t>(Header::HEADER_SIZE)) {}
protected:
Memory memory;
};
TEST_CASE_METHOD(MemFixture, "bios", TAG) {
memory.write(0, 0xAC);
CHECK(memory.read(0) == 0xAC);
memory.write(0x3FFF, 0x48);
CHECK(memory.read(0x3FFF) == 0x48);
memory.write(0x2A56, 0x10);
CHECK(memory.read(0x2A56) == 0x10);
}
TEST_CASE_METHOD(MemFixture, "board wram", TAG) {
memory.write(0x2000000, 0xAC);
CHECK(memory.read(0x2000000) == 0xAC);
memory.write(0x203FFFF, 0x48);
CHECK(memory.read(0x203FFFF) == 0x48);
memory.write(0x2022A56, 0x10);
CHECK(memory.read(0x2022A56) == 0x10);
}
TEST_CASE_METHOD(MemFixture, "chip wram", TAG) {
memory.write(0x3000000, 0xAC);
CHECK(memory.read(0x3000000) == 0xAC);
memory.write(0x3007FFF, 0x48);
CHECK(memory.read(0x3007FFF) == 0x48);
memory.write(0x3002A56, 0x10);
CHECK(memory.read(0x3002A56) == 0x10);
}
TEST_CASE_METHOD(MemFixture, "palette ram", TAG) {
memory.write(0x5000000, 0xAC);
CHECK(memory.read(0x5000000) == 0xAC);
memory.write(0x50003FF, 0x48);
CHECK(memory.read(0x50003FF) == 0x48);
memory.write(0x5000156, 0x10);
CHECK(memory.read(0x5000156) == 0x10);
}
TEST_CASE_METHOD(MemFixture, "video ram", TAG) {
memory.write(0x6000000, 0xAC);
CHECK(memory.read(0x6000000) == 0xAC);
memory.write(0x6017FFF, 0x48);
CHECK(memory.read(0x6017FFF) == 0x48);
memory.write(0x6012A56, 0x10);
CHECK(memory.read(0x6012A56) == 0x10);
}
TEST_CASE_METHOD(MemFixture, "oam obj ram", TAG) {
memory.write(0x7000000, 0xAC);
CHECK(memory.read(0x7000000) == 0xAC);
memory.write(0x70003FF, 0x48);
CHECK(memory.read(0x70003FF) == 0x48);
memory.write(0x7000156, 0x10);
CHECK(memory.read(0x7000156) == 0x10);
}
TEST_CASE("rom", TAG) {
// 32 megabyte ROM
Memory memory(std::array<uint8_t, Memory::BIOS_SIZE>(),
std::vector<uint8_t>(32 * 1024 * 1024));
SECTION("ROM1") {
memory.write(0x8000000, 0xAC);
CHECK(memory.read(0x8000000) == 0xAC);
memory.write(0x9FFFFFF, 0x48);
CHECK(memory.read(0x9FFFFFF) == 0x48);
memory.write(0x8ef0256, 0x10);
CHECK(memory.read(0x8ef0256) == 0x10);
}
SECTION("ROM2") {
memory.write(0xA000000, 0xAC);
CHECK(memory.read(0xA000000) == 0xAC);
memory.write(0xBFFFFFF, 0x48);
CHECK(memory.read(0xBFFFFFF) == 0x48);
memory.write(0xAEF0256, 0x10);
CHECK(memory.read(0xAEF0256) == 0x10);
}
SECTION("ROM3") {
memory.write(0xC000000, 0xAC);
CHECK(memory.read(0xC000000) == 0xAC);
memory.write(0xDFFFFFF, 0x48);
CHECK(memory.read(0xDFFFFFF) == 0x48);
memory.write(0xCEF0256, 0x10);
CHECK(memory.read(0xCEF0256) == 0x10);
}
}

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tests/meson.build Normal file
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tests_deps = [
lib
]
src = include_directories('../src')
tests_sources = files(
'main.cc',
'bus.cc',
'memory.cc'
)
subdir('cpu')
subdir('util')
catch2 = dependency('catch2', version: '>=3.4.0', static: true)
catch2_tests = executable(
'matar_tests',
tests_sources,
dependencies: catch2,
link_with: tests_deps,
include_directories: [inc, src],
build_by_default: false,
)
test('catch2 tests', catch2_tests)

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#include "util/bits.hh"
#include <catch2/catch_test_macros.hpp>
static constexpr auto TAG = "[util][bits]";
TEST_CASE("8 bits", TAG) {
uint8_t num = 45;
CHECK(get_bit(num, 0));
CHECK(!get_bit(num, 1));
CHECK(get_bit(num, 5));
CHECK(!get_bit(num, 6));
CHECK(!get_bit(num, 7));
set_bit(num, 6);
CHECK(get_bit(num, 6));
rst_bit(num, 6);
CHECK(!get_bit(num, 6));
chg_bit(num, 5, false);
CHECK(!get_bit(num, 5));
chg_bit(num, 5, true);
CHECK(get_bit(num, 5));
// 0b0110
CHECK(bit_range(num, 1, 4) == 6);
}
TEST_CASE("16 bits", TAG) {
uint16_t num = 34587;
CHECK(get_bit(num, 0));
CHECK(get_bit(num, 1));
CHECK(!get_bit(num, 5));
CHECK(!get_bit(num, 14));
CHECK(get_bit(num, 15));
set_bit(num, 14);
CHECK(get_bit(num, 14));
rst_bit(num, 14);
CHECK(!get_bit(num, 14));
chg_bit(num, 5, true);
CHECK(get_bit(num, 5));
// num = 45
chg_bit(num, 5, false);
CHECK(!get_bit(num, 5));
// 0b1000110
CHECK(bit_range(num, 2, 8) == 70);
}
TEST_CASE("32 bits", TAG) {
uint32_t num = 3194142523;
CHECK(get_bit(num, 0));
CHECK(get_bit(num, 1));
CHECK(get_bit(num, 12));
CHECK(get_bit(num, 29));
CHECK(!get_bit(num, 30));
CHECK(get_bit(num, 31));
set_bit(num, 30);
CHECK(get_bit(num, 30));
rst_bit(num, 30);
CHECK(!get_bit(num, 30));
chg_bit(num, 12, false);
CHECK(!get_bit(num, 12));
chg_bit(num, 12, true);
CHECK(get_bit(num, 12));
// 0b10011000101011111100111
CHECK(bit_range(num, 3, 25) == 5003239);
}
TEST_CASE("64 bits", TAG) {
uint64_t num = 58943208889991935;
CHECK(get_bit(num, 0));
CHECK(get_bit(num, 1));
CHECK(!get_bit(num, 10));
CHECK(get_bit(num, 55));
CHECK(!get_bit(num, 60));
set_bit(num, 63);
CHECK(get_bit(num, 63));
rst_bit(num, 63);
CHECK(!get_bit(num, 63));
chg_bit(num, 10, true);
CHECK(get_bit(num, 10));
chg_bit(num, 10, false);
CHECK(!get_bit(num, 10));
// 0b011010001
CHECK(bit_range(num, 39, 47) == 209);
}

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#include "util/crypto.hh"
#include <catch2/catch_test_macros.hpp>
static constexpr auto TAG = "[util][crypto]";
TEST_CASE("sha256 matar", TAG) {
std::array<uint8_t, 5> data = { 'm', 'a', 't', 'a', 'r' };
CHECK(crypto::sha256(data) ==
"3b02a908fd5743c0e868675bb6ae77d2a62b3b5f7637413238e2a1e0e94b6a53");
}
TEST_CASE("sha256 forgis", TAG) {
std::array<uint8_t, 32> data = { 'i', ' ', 'p', 'u', 't', ' ', 't', 'h',
'e', ' ', 'n', 'e', 'w', ' ', 'f', 'o',
'r', 'g', 'i', 's', ' ', 'o', 'n', ' ',
't', 'h', 'e', ' ', 'j', 'e', 'e', 'p' };
CHECK(crypto::sha256(data) ==
"cfddca2ce2673f355518cbe2df2a8522693c54723a469e8b36a4f68b90d2b759");
}

4
tests/util/meson.build Normal file
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tests_sources += files(
'bits.cc',
'crypto.cc'
)