// SPDX-FileCopyrightText: 2019-2022 Connor McLaughlin // SPDX-License-Identifier: (GPL-3.0 OR CC-BY-NC-ND-4.0) #pragma once #include "common/bitfield.h" #include "types.h" #include #include #include #include #include #include class StateWrapper; namespace Bus { enum : u32 { RAM_BASE = 0x00000000, RAM_2MB_SIZE = 0x200000, RAM_2MB_MASK = RAM_2MB_SIZE - 1, RAM_8MB_SIZE = 0x800000, RAM_8MB_MASK = RAM_8MB_SIZE - 1, RAM_MIRROR_END = 0x800000, RAM_MIRROR_SIZE = 0x800000, EXP1_BASE = 0x1F000000, EXP1_SIZE = 0x800000, EXP1_MASK = EXP1_SIZE - 1, HW_BASE = 0x1F801000, HW_SIZE = 0x1000, MEMCTRL_BASE = 0x1F801000, MEMCTRL_SIZE = 0x40, MEMCTRL_MASK = MEMCTRL_SIZE - 1, PAD_BASE = 0x1F801040, PAD_SIZE = 0x10, PAD_MASK = PAD_SIZE - 1, SIO_BASE = 0x1F801050, SIO_SIZE = 0x10, SIO_MASK = SIO_SIZE - 1, MEMCTRL2_BASE = 0x1F801060, MEMCTRL2_SIZE = 0x10, MEMCTRL2_MASK = MEMCTRL2_SIZE - 1, INTC_BASE = 0x1F801070, INTC_SIZE = 0x10, INTERRUPT_CONTROLLER_MASK = INTC_SIZE - 1, DMA_BASE = 0x1F801080, DMA_SIZE = 0x80, DMA_MASK = DMA_SIZE - 1, TIMERS_BASE = 0x1F801100, TIMERS_SIZE = 0x40, TIMERS_MASK = TIMERS_SIZE - 1, CDROM_BASE = 0x1F801800, CDROM_SIZE = 0x10, CDROM_MASK = CDROM_SIZE - 1, GPU_BASE = 0x1F801810, GPU_SIZE = 0x10, GPU_MASK = GPU_SIZE - 1, MDEC_BASE = 0x1F801820, MDEC_SIZE = 0x10, MDEC_MASK = MDEC_SIZE - 1, SPU_BASE = 0x1F801C00, SPU_SIZE = 0x400, SPU_MASK = 0x3FF, EXP2_BASE = 0x1F802000, EXP2_SIZE = 0x2000, EXP2_MASK = EXP2_SIZE - 1, EXP3_BASE = 0x1FA00000, EXP3_SIZE = 0x200000, EXP3_MASK = EXP3_SIZE - 1, BIOS_BASE = 0x1FC00000, BIOS_SIZE = 0x80000, BIOS_MASK = 0x7FFFF, }; enum : u32 { MEMCTRL_REG_COUNT = 9 }; enum : TickCount { RAM_READ_TICKS = 6 }; enum : u32 { RAM_2MB_CODE_PAGE_COUNT = (RAM_2MB_SIZE + (HOST_PAGE_SIZE + 1)) / HOST_PAGE_SIZE, RAM_8MB_CODE_PAGE_COUNT = (RAM_8MB_SIZE + (HOST_PAGE_SIZE + 1)) / HOST_PAGE_SIZE, MEMORY_LUT_PAGE_SIZE = 4096, MEMORY_LUT_PAGE_SHIFT = 12, MEMORY_LUT_SIZE = 0x100000, // 0x100000000 >> 12 MEMORY_LUT_SLOTS = MEMORY_LUT_SIZE * 3 * 2, // [size][read_write] FASTMEM_LUT_PAGE_SIZE = 4096, FASTMEM_LUT_PAGE_MASK = FASTMEM_LUT_PAGE_SIZE - 1, FASTMEM_LUT_PAGE_SHIFT = 12, FASTMEM_LUT_PAGES_PER_CODE_PAGE = HOST_PAGE_SIZE / FASTMEM_LUT_PAGE_SIZE, FASTMEM_LUT_NUM_PAGES = 0x100000, // 0x100000000 >> 12 FASTMEM_LUT_NUM_SLOTS = FASTMEM_LUT_NUM_PAGES * 2, }; #ifdef ENABLE_MMAP_FASTMEM // Fastmem region size is 4GB to cover the entire 32-bit address space. static constexpr size_t FASTMEM_ARENA_SIZE = UINT64_C(0x100000000); #endif bool AllocateMemory(); void ReleaseMemory(); bool Initialize(); void Shutdown(); void Reset(); bool DoState(StateWrapper& sw); using MemoryReadHandler = u32 (*)(VirtualMemoryAddress address); using MemoryWriteHandler = void (*)(VirtualMemoryAddress, u32); void** GetMemoryHandlers(bool isolate_cache, bool swap_caches); template ALWAYS_INLINE_RELEASE static FP* OffsetHandlerArray(void** handlers, MemoryAccessSize size, MemoryAccessType type) { return reinterpret_cast(handlers + (((static_cast(size) * 2) + static_cast(type)) * MEMORY_LUT_SIZE)); } CPUFastmemMode GetFastmemMode(); void* GetFastmemBase(); void UpdateFastmemViews(CPUFastmemMode mode); bool CanUseFastmemForAddress(VirtualMemoryAddress address); void SetExpansionROM(std::vector data); extern std::bitset g_ram_code_bits; extern u8* g_ram; // 2MB-8MB RAM extern u32 g_ram_size; // Active size of RAM. extern u32 g_ram_mask; // Active address bits for RAM. extern u8* g_bios; // 512K BIOS ROM extern std::array g_exp1_access_time; extern std::array g_exp2_access_time; extern std::array g_bios_access_time; extern std::array g_cdrom_access_time; extern std::array g_spu_access_time; /// Returns true if the address specified is writable (RAM). ALWAYS_INLINE static bool IsRAMAddress(PhysicalMemoryAddress address) { return address < RAM_MIRROR_END; } /// Returns the code page index for a RAM address. ALWAYS_INLINE static u32 GetRAMCodePageIndex(PhysicalMemoryAddress address) { return (address & g_ram_mask) / HOST_PAGE_SIZE; } /// Returns true if the specified page contains code. bool IsRAMCodePage(u32 index); /// Flags a RAM region as code, so we know when to invalidate blocks. void SetRAMCodePage(u32 index); /// Unflags a RAM region as code, the code cache will no longer be notified when writes occur. void ClearRAMCodePage(u32 index); /// Clears all code bits for RAM regions. void ClearRAMCodePageFlags(); /// Returns true if the specified address is in a code page. bool IsCodePageAddress(PhysicalMemoryAddress address); /// Returns true if the range specified overlaps with a code page. bool HasCodePagesInRange(PhysicalMemoryAddress start_address, u32 size); /// Returns the number of cycles stolen by DMA RAM access. ALWAYS_INLINE TickCount GetDMARAMTickCount(u32 word_count) { // DMA is using DRAM Hyper Page mode, allowing it to access DRAM rows at 1 clock cycle per word (effectively around // 17 clks per 16 words, due to required row address loading, probably plus some further minimal overload due to // refresh cycles). This is making DMA much faster than CPU memory accesses (CPU DRAM access takes 1 opcode cycle // plus 6 waitstates, ie. 7 cycles in total). return static_cast(word_count + ((word_count + 15) / 16)); } enum class MemoryRegion { RAM, RAMMirror1, RAMMirror2, RAMMirror3, EXP1, Scratchpad, BIOS, Count }; std::optional GetMemoryRegionForAddress(PhysicalMemoryAddress address); PhysicalMemoryAddress GetMemoryRegionStart(MemoryRegion region); PhysicalMemoryAddress GetMemoryRegionEnd(MemoryRegion region); u8* GetMemoryRegionPointer(MemoryRegion region); std::optional SearchMemory(PhysicalMemoryAddress start_address, const u8* pattern, const u8* mask, u32 pattern_length); // TTY Logging. void AddTTYCharacter(char ch); void AddTTYString(const std::string_view& str); } // namespace Bus