3b1emu: src/memory.c@8b24770dea79 (annotated)

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src/memory.c@8b24770dea79 (annotated)

src/memory.c

Fri, 18 Jan 2013 17:18:50 +0000

author: Philip Pemberton <philpem@philpem.me.uk>
date: Fri, 18 Jan 2013 17:18:50 +0000
changeset 129: 8b24770dea79
parent 121: 15ae2788e848
child 132: 8a7dc9b5b1db
child 136: f7d78dfb45d0
permissions: -rw-r--r--

[memory] Emulate main memory read wrap-around

3B1s with 512K or 1MB of base memory have a decoding quirk which causes reads
to 'wrap around'. That is to say, on a 512K machine, reading from addresses 0,
512K, 1024K or 1536K will address the same RAM byte. On a 1MB machine,
addresses 0 and 1024K address the same RAM byte.

Emulating this incorrectly causes P4TEST to report an incorrect amount of
available base RAM.

 #include <stdio.h>
 #include <stdlib.h>
 #include <stdint.h>
 #include <stdbool.h>
 #include <assert.h>
 #include "musashi/m68k.h"
 #include "state.h"
 #include "utils.h"
 #include "memory.h"
 // The value which will be returned if the CPU attempts to read from empty memory
 // TODO (FIXME?) - need to figure out if R/W ops wrap around. This seems to appease the UNIX kernel and P4TEST.
 #define EMPTY 0xFFFFFFFFUL
 //#define EMPTY 0x55555555UL
 //#define EMPTY 0x00000000UL
 /******************
  * Memory mapping
  ******************/
 #define MAPRAM(addr) (((uint16_t)state.map[addr*2] << 8) + ((uint16_t)state.map[(addr*2)+1]))
 uint32_t mapAddr(uint32_t addr, bool writing)/*{{{*/
 {
 	if (addr < 0x400000) {
 		// RAM access. Check against the Map RAM
 		// Start by getting the original page address
 		uint16_t page = (addr >> 12) & 0x3FF;
 		// Look it up in the map RAM and get the physical page address
 		uint32_t new_page_addr = MAPRAM(page) & 0x3FF;
 		// Update the Page Status bits
 		uint8_t pagebits = (MAPRAM(page) >> 13) & 0x03;
 		// Pagebits --
 		//   0 = not present
 		//   1 = present but not accessed
 		//   2 = present, accessed (read from)
 		//   3 = present, dirty (written to)
 		switch (pagebits) {
 			case 0:
 				// Page not present
 				// This should cause a page fault
 				LOGS("Whoa! Pagebit update, when the page is not present!");
 				break;
 			case 1:
 				// Page present -- first access
 				state.map[page*2] &= 0x9F;	// turn off "present" bit (but not write enable!)
 				if (writing)
 					state.map[page*2] |= 0x60;		// Page written to (dirty)
 				else
 					state.map[page*2] |= 0x40;		// Page accessed but not written
 				break;
 			case 2:
 			case 3:
 				// Page present, 2nd or later access
 				if (writing)
 					state.map[page*2] |= 0x60;		// Page written to (dirty)
 				break;
 		}
 		// Return the address with the new physical page spliced in
 		return (new_page_addr << 12) + (addr & 0xFFF);
 	} else {
 		// I/O, VRAM or MapRAM space; no mapping is performed or required
 		// TODO: assert here?
 		return addr;
 	}
 }/*}}}*/
 MEM_STATUS checkMemoryAccess(uint32_t addr, bool writing)/*{{{*/
 {
 	// Get the page bits for this page.
 	uint16_t page = (addr >> 12) & 0x3FF;
 	uint8_t pagebits = (MAPRAM(page) >> 13) & 0x07;
 	// Check page is present (but only for RAM zone)
 	if ((addr < 0x400000) && ((pagebits & 0x03) == 0)) {
 		LOG("Page not mapped in: addr %08X, page %04X, mapbits %04X", addr, page, MAPRAM(page));
 		return MEM_PAGEFAULT;
 	}
 	// Are we in Supervisor mode?
 	if (m68k_get_reg(NULL, M68K_REG_SR) & 0x2000)
 		// Yes. We can do anything we like.
 		return MEM_ALLOWED;
 	// If we're here, then we must be in User mode.
 	// Check that the user didn't access memory outside of the RAM area
 	if (addr >= 0x400000) {
 		LOGS("User accessed privileged memory");
 		return MEM_UIE;
 	}
 	// User attempt to access the kernel
 	// A19, A20, A21, A22 low (kernel access): RAM addr before paging; not in Supervisor mode
 	if (((addr >> 19) & 0x0F) == 0) {
 		LOGS("Attempt by user code to access kernel space");
 		return MEM_KERNEL;
 	}
 	// Check page is write enabled
 	if (writing && ((pagebits & 0x04) == 0)) {
 		LOG("Page not write enabled: inaddr %08X, page %04X, mapram %04X [%02X %02X], pagebits %d",
 				addr, page, MAPRAM(page), state.map[page*2], state.map[(page*2)+1], pagebits);
 		return MEM_PAGE_NO_WE;
 	}
 	// Page access allowed.
 	return MEM_ALLOWED;
 }/*}}}*/
 /********************************************************
  * m68k memory read/write support functions for Musashi
  ********************************************************/
 /**
  * @brief	Check memory access permissions for a write operation.
  * @note	This used to be a single macro (merged with ACCESS_CHECK_RD), but
  * 			gcc throws warnings when you have a return-with-value in a void
  * 			function, even if the return-with-value is completely unreachable.
  * 			Similarly it doesn't like it if you have a return without a value
  * 			in a non-void function, even if it's impossible to ever reach the
  * 			return-with-no-value. UGH!
  */
 /*{{{ macro: ACCESS_CHECK_WR(address, bits)*/
 #define ACCESS_CHECK_WR(address, bits)								\
 	do {															\
 		bool fault = false;											\
 		MEM_STATUS st;												\
 		switch (st = checkMemoryAccess(address, true)) {			\
 			case MEM_ALLOWED:										\
 				/* Access allowed */								\
 				break;												\
 			case MEM_PAGEFAULT:										\
 				/* Page fault */									\
 				state.genstat = 0x8BFF | (state.pie ? 0x0400 : 0);	\
 				fault = true;										\
 				break;												\
 			case MEM_UIE:											\
 				/* User access to memory above 4MB */				\
 				state.genstat = 0x9AFF | (state.pie ? 0x0400 : 0);	\
 				fault = true;										\
 				break;												\
 			case MEM_KERNEL:										\
 			case MEM_PAGE_NO_WE:									\
 				/* kernel access or page not write enabled */		\
 				/* XXX: is this the correct value? */				\
 				state.genstat = 0x9BFF | (state.pie ? 0x0400 : 0);	\
 				fault = true;										\
 				break;												\
 		}															\
 																	\
 		if (fault) {												\
 			if (bits >= 16)											\
 				state.bsr0 = 0x7C00;								\
 			else													\
 				state.bsr0 = (address & 1) ? 0x7E00 : 0x7D00;		\
 			state.bsr0 |= (address >> 16);							\
 			state.bsr1 = address & 0xffff;							\
 			LOG("Bus Error while writing, addr %08X, statcode %d", address, st);		\
 			if (state.ee) m68k_pulse_bus_error();					\
 			return;													\
 		}															\
 	} while (0)
 /*}}}*/
 /**
  * @brief Check memory access permissions for a read operation.
  * @note	This used to be a single macro (merged with ACCESS_CHECK_WR), but
  * 			gcc throws warnings when you have a return-with-value in a void
  * 			function, even if the return-with-value is completely unreachable.
  * 			Similarly it doesn't like it if you have a return without a value
  * 			in a non-void function, even if it's impossible to ever reach the
  * 			return-with-no-value. UGH!
  */
 /*{{{ macro: ACCESS_CHECK_RD(address, bits)*/
 #define ACCESS_CHECK_RD(address, bits)								\
 	do {															\
 		bool fault = false;											\
 		MEM_STATUS st;												\
 		switch (st = checkMemoryAccess(address, false)) {			\
 			case MEM_ALLOWED:										\
 				/* Access allowed */								\
 				break;												\
 			case MEM_PAGEFAULT:										\
 				/* Page fault */									\
 				state.genstat = 0xCBFF | (state.pie ? 0x0400 : 0);	\
 				fault = true;										\
 				break;												\
 			case MEM_UIE:											\
 				/* User access to memory above 4MB */				\
 				state.genstat = 0xDAFF | (state.pie ? 0x0400 : 0);	\
 				fault = true;										\
 				break;												\
 			case MEM_KERNEL:										\
 			case MEM_PAGE_NO_WE:									\
 				/* kernel access or page not write enabled */		\
 				/* XXX: is this the correct value? */				\
 				state.genstat = 0xDBFF | (state.pie ? 0x0400 : 0);	\
 				fault = true;										\
 				break;												\
 		}															\
 																	\
 		if (fault) {												\
 			if (bits >= 16)											\
 				state.bsr0 = 0x7C00;								\
 			else													\
 				state.bsr0 = (address & 1) ? 0x7E00 : 0x7D00;		\
 			state.bsr0 |= (address >> 16);							\
 			state.bsr1 = address & 0xffff;							\
 			LOG("Bus Error while reading, addr %08X, statcode %d", address, st);		\
 			if (state.ee) m68k_pulse_bus_error();					\
 			if (bits == 32)											\
 				return EMPTY & 0xFFFFFFFF;									\
 			else													\
 				return EMPTY & ((1UL << bits)-1);								\
 		}															\
 	} while (0)
 /*}}}*/
 bool access_check_dma(int reading)
 {
 	// Check memory access permissions
 	bool access_ok;
 	switch (checkMemoryAccess(state.dma_address, !reading)) {
 		case MEM_PAGEFAULT:
 			// Page fault
 			state.genstat = 0xABFF
 				| (reading ? 0x4000 : 0)
 				| (state.pie ? 0x0400 : 0);
 			access_ok = false;
 			break;
 		case MEM_UIE:
 			// User access to memory above 4MB
 			// FIXME? Shouldn't be possible with DMA... assert this?
 			state.genstat = 0xBAFF
 				| (reading ? 0x4000 : 0)
 				| (state.pie ? 0x0400 : 0);
 			access_ok = false;
 			break;
 		case MEM_KERNEL:
 		case MEM_PAGE_NO_WE:
 			// Kernel access or page not write enabled
 			/* XXX: is this correct? */
 			state.genstat = 0xBBFF
 				| (reading ? 0x4000 : 0)
 				| (state.pie ? 0x0400 : 0);
 			access_ok = false;
 			break;
 		case MEM_ALLOWED:
 			access_ok = true;
 			break;
 	}
 	if (!access_ok) {
 		state.bsr0 = 0x3C00;
 		state.bsr0 |= (state.dma_address >> 16);
 		state.bsr1 = state.dma_address & 0xffff;
 		if (state.ee) m68k_set_irq(7);
 		printf("BUS ERROR FROM DMA: genstat=%04X, bsr0=%04X, bsr1=%04X\n", state.genstat, state.bsr0, state.bsr1);
 	}
 	return (access_ok);
 }
 // Logging macros
 #define LOG_NOT_HANDLED_R(bits)															\
 	if (!handled) printf("unhandled read%02d, addr=0x%08X\n", bits, address);
 #define LOG_NOT_HANDLED_W(bits)															\
 	if (!handled) printf("unhandled write%02d, addr=0x%08X, data=0x%08X\n", bits, address, data);
 /********************************************************
  * I/O read/write functions
  ********************************************************/
 /**
  * Issue a warning if a read operation is made with an invalid size
  */
 inline static void ENFORCE_SIZE(int bits, uint32_t address, bool read, int allowed, char *regname)
 {
 	assert((bits == 8) || (bits == 16) || (bits == 32));
 	if ((bits & allowed) == 0) {
 		printf("WARNING: %s 0x%08X (%s) with invalid size %d!\n", read ? "read from" : "write to", address, regname, bits);
 	}
 }
 inline static void ENFORCE_SIZE_R(int bits, uint32_t address, int allowed, char *regname)
 {
 	ENFORCE_SIZE(bits, address, true, allowed, regname);
 }
 inline static void ENFORCE_SIZE_W(int bits, uint32_t address, int allowed, char *regname)
 {
 	ENFORCE_SIZE(bits, address, false, allowed, regname);
 }
 void IoWrite(uint32_t address, uint32_t data, int bits)/*{{{*/
 {
 	bool handled = false;
 	if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x010000:				// General Status Register
 				if (bits == 16)
 					state.genstat = (data & 0xffff);
 				else if (bits == 8) {
 					if (address & 0)
 						state.genstat = data;
 					else
 						state.genstat = data << 8;
 				}
 				handled = true;
 				break;
 			case 0x030000:				// Bus Status Register 0
 				break;
 			case 0x040000:				// Bus Status Register 1
 				break;
 			case 0x050000:				// Phone status
 				break;
 			case 0x060000:				// DMA Count
 				ENFORCE_SIZE_W(bits, address, 16, "DMACOUNT");
 				state.dma_count = (data & 0x3FFF);
 				state.idmarw = ((data & 0x4000) == 0x4000);
 				state.dmaen = ((data & 0x8000) == 0x8000);
 				// This handles the "dummy DMA transfer" mentioned in the docs
 				// disabled because it causes the floppy test to fail
 #if 0
 				if (!state.idmarw){
 					if (access_check_dma(true)){
 						uint32_t newAddr = mapAddr(state.dma_address, true);
 						// RAM access
 						if (newAddr <= 0x1fffff)
 							WR16(state.base_ram, newAddr, state.base_ram_size - 1, 0xFF);
 						else if (address <= 0x3FFFFF)
 							WR16(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1, 0xFF);
 					}
 				}
 #endif
 				state.dma_count++;
 				handled = true;
 				break;
 			case 0x070000:				// Line Printer Status Register
 				break;
 			case 0x080000:				// Real Time Clock
 				break;
 			case 0x090000:				// Phone registers
 				switch (address & 0x0FF000) {
 					case 0x090000:		// Handset relay
 					case 0x098000:
 						break;
 					case 0x091000:		// Line select 2
 					case 0x099000:
 						break;
 					case 0x092000:		// Hook relay 1
 					case 0x09A000:
 						break;
 					case 0x093000:		// Hook relay 2
 					case 0x09B000:
 						break;
 					case 0x094000:		// Line 1 hold
 					case 0x09C000:
 						break;
 					case 0x095000:		// Line 2 hold
 					case 0x09D000:
 						break;
 					case 0x096000:		// Line 1 A-lead
 					case 0x09E000:
 						break;
 					case 0x097000:		// Line 2 A-lead
 					case 0x09F000:
 						break;
 				}
 				break;
 			case 0x0A0000:				// Miscellaneous Control Register
 				ENFORCE_SIZE_W(bits, address, 16, "MISCCON");
 				// TODO: handle the ctrl bits properly
 				if (data & 0x8000){
 					state.timer_enabled = 1;
 				}else{
 					state.timer_enabled = 0;
 					state.timer_asserted = 0;
 				}
 				state.dma_reading = (data & 0x4000);
 				if (state.leds != ((~data & 0xF00) >> 8)) {
 					state.leds = (~data & 0xF00) >> 8;
 #ifdef SHOW_LEDS
 					printf("LEDs: %s %s %s %s\n",
 							(state.leds & 8) ? "R" : "-",
 							(state.leds & 4) ? "G" : "-",
 							(state.leds & 2) ? "Y" : "-",
 							(state.leds & 1) ? "R" : "-");
 #endif
 				}
 				handled = true;
 				break;
 			case 0x0B0000:				// TM/DIALWR
 				break;
 			case 0x0C0000:				// Clear Status Register
 				state.genstat = 0xFFFF;
 				state.bsr0 = 0xFFFF;
 				state.bsr1 = 0xFFFF;
 				handled = true;
 				break;
 			case 0x0D0000:				// DMA Address Register
 				if (address & 0x004000) {
 					// A14 high -- set most significant bits
 					state.dma_address = (state.dma_address & 0x1fe) | ((address & 0x3ffe) << 8);
 				} else {
 					// A14 low -- set least significant bits
 					state.dma_address = (state.dma_address & 0x3ffe00) | (address & 0x1fe);
 				}
 				handled = true;
 				break;
 			case 0x0E0000:				// Disk Control Register
 				{
 					bool fd_selected;
 					bool hd_selected;
 					ENFORCE_SIZE_W(bits, address, 16, "DISKCON");
 					// B7 = FDD controller reset
 					if ((data & 0x80) == 0) wd2797_reset(&state.fdc_ctx);
 					// B6 = drive 0 select
 					fd_selected = (data & 0x40) != 0;
 					// B5 = motor enable -- TODO
 					// B4 = HDD controller reset
 					if ((data & 0x10) == 0) wd2010_reset(&state.hdc_ctx);
 					// B3 = HDD0 select
 					hd_selected = (data & 0x08) != 0;
 					// B2,1,0 = HDD0 head select -- TODO?
 					if (hd_selected && !state.hd_selected){
 						state.fd_selected = false;
 						state.hd_selected = true;
 					}else if (fd_selected && !state.fd_selected){
 						state.hd_selected = false;
 						state.fd_selected = true;
 					}
 					handled = true;
 					break;
 				}
 			case 0x0F0000:				// Line Printer Data Register
 				break;
 		}
 	} else if ((address >= 0xC00000) && (address <= 0xFFFFFF)) {
 		// I/O register space, zone B
 		switch (address & 0xF00000) {
 			case 0xC00000:				// Expansion slots
 			case 0xD00000:
 				switch (address & 0xFC0000) {
 					case 0xC00000:		// Expansion slot 0
 					case 0xC40000:		// Expansion slot 1
 					case 0xC80000:		// Expansion slot 2
 					case 0xCC0000:		// Expansion slot 3
 					case 0xD00000:		// Expansion slot 4
 					case 0xD40000:		// Expansion slot 5
 					case 0xD80000:		// Expansion slot 6
 					case 0xDC0000:		// Expansion slot 7
 						fprintf(stderr, "NOTE: WR%d to expansion card space, addr=0x%08X, data=0x%08X\n", bits, address, data);
 						handled = true;
 						break;
 				}
 				break;
 			case 0xE00000:				// HDC, FDC, MCR2 and RTC data bits
 			case 0xF00000:
 				switch (address & 0x070000) {
 					case 0x000000:		// [ef][08]xxxx ==> WD2010 hard disc controller
 						wd2010_write_reg(&state.hdc_ctx, (address >> 1) & 7, data);
 						handled = true;
 						break;
 					case 0x010000:		// [ef][19]xxxx ==> WD2797 floppy disc controller
 						/*ENFORCE_SIZE_W(bits, address, 16, "FDC REGISTERS");*/
 						wd2797_write_reg(&state.fdc_ctx, (address >> 1) & 3, data);
 						handled = true;
 						break;
 					case 0x020000:		// [ef][2a]xxxx ==> Miscellaneous Control Register 2
 						// MCR2 - UNIX PC Rev. P5.1 HDD head select b3 and potential HDD#2 select
 						wd2010_write_reg(&state.hdc_ctx, UNIXPC_REG_MCR2, data);
 						handled = true;
 						break;
 					case 0x030000:		// [ef][3b]xxxx ==> Real Time Clock data bits
 						break;
 					case 0x040000:		// [ef][4c]xxxx ==> General Control Register
 						switch (address & 0x077000) {
 							case 0x040000:		// [ef][4c][08]xxx ==> EE
 								// Error Enable. If =0, Level7 intrs and bus errors are masked.
 								ENFORCE_SIZE_W(bits, address, 16, "EE");
 								state.ee = ((data & 0x8000) == 0x8000);
 								handled = true;
 								break;
 							case 0x041000:		// [ef][4c][19]xxx ==> PIE
 								ENFORCE_SIZE_W(bits, address, 16, "PIE");
 								state.pie = ((data & 0x8000) == 0x8000);
 								handled = true;
 								break;
 							case 0x042000:		// [ef][4c][2A]xxx ==> BP
 								break;
 							case 0x043000:		// [ef][4c][3B]xxx ==> ROMLMAP
 								ENFORCE_SIZE_W(bits, address, 16, "ROMLMAP");
 								state.romlmap = ((data & 0x8000) == 0x8000);
 								handled = true;
 								break;
 							case 0x044000:		// [ef][4c][4C]xxx ==> L1 MODEM
 								ENFORCE_SIZE_W(bits, address, 16, "L1 MODEM");
 								break;
 							case 0x045000:		// [ef][4c][5D]xxx ==> L2 MODEM
 								ENFORCE_SIZE_W(bits, address, 16, "L2 MODEM");
 								break;
 							case 0x046000:		// [ef][4c][6E]xxx ==> D/N CONNECT
 								ENFORCE_SIZE_W(bits, address, 16, "D/N CONNECT");
 								break;
 							case 0x047000:		// [ef][4c][7F]xxx ==> Whole screen reverse video
 								ENFORCE_SIZE_W(bits, address, 16, "WHOLE SCREEN REVERSE VIDEO");
 								break;
 						}
 					case 0x050000:		// [ef][5d]xxxx ==> 8274
 						break;
 					case 0x060000:		// [ef][6e]xxxx ==> Control regs
 						switch (address & 0x07F000) {
 							default:
 								break;
 						}
 						break;
 					case 0x070000:		// [ef][7f]xxxx ==> 6850 Keyboard Controller
 						// TODO: figure out which sizes are valid (probably just 8 and 16)
 						// ENFORCE_SIZE_W(bits, address, 16, "KEYBOARD CONTROLLER");
 						if (bits == 8) {
 							printf("KBD WR %02X => %02X\n", (address >> 1) & 3, data);
 							keyboard_write(&state.kbd, (address >> 1) & 3, data);
 							handled = true;
 						} else if (bits == 16) {
 							printf("KBD WR %02X => %04X\n", (address >> 1) & 3, data);
 							keyboard_write(&state.kbd, (address >> 1) & 3, data >> 8);
 							handled = true;
 						}
 						break;
 				}
 		}
 	}
 	LOG_NOT_HANDLED_W(bits);
 }/*}}}*/
 uint32_t IoRead(uint32_t address, int bits)/*{{{*/
 {
 	bool handled = false;
 	uint32_t data = EMPTY & 0xFFFFFFFF;
 	if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x010000:				// General Status Register
 				/* ENFORCE_SIZE_R(bits, address, 16, "GENSTAT"); */
 				if (bits == 32) {
 					return ((uint32_t)state.genstat << 16) + (uint32_t)state.genstat;
 				} else if (bits == 16) {
 					return (uint16_t)state.genstat;
 				} else {
 					return (uint8_t)(state.genstat & 0xff);
 				}
 				break;
 			case 0x030000:				// Bus Status Register 0
 				ENFORCE_SIZE_R(bits, address, 16, "BSR0");
 				return ((uint32_t)state.bsr0 << 16) + (uint32_t)state.bsr0;
 				break;
 			case 0x040000:				// Bus Status Register 1
 				ENFORCE_SIZE_R(bits, address, 16, "BSR1");
 				return ((uint32_t)state.bsr1 << 16) + (uint32_t)state.bsr1;
 				break;
 			case 0x050000:				// Phone status
 				ENFORCE_SIZE_R(bits, address, 8 | 16, "PHONE STATUS");
 				break;
 			case 0x060000:				// DMA Count
 				// TODO: U/OERR- is always inactive (bit set)... or should it be = DMAEN+?
 				// Bit 14 is always unused, so leave it set
 				ENFORCE_SIZE_R(bits, address, 16, "DMACOUNT");
 				return (state.dma_count & 0x3fff) | 0xC000;
 				break;
 			case 0x070000:				// Line Printer Status Register
 				data = 0x00120012;	// no parity error, no line printer error, no irqs from FDD or HDD
 				data |= wd2797_get_irq(&state.fdc_ctx) ? 0x00080008 : 0;
 				data |= wd2010_get_irq(&state.hdc_ctx) ? 0x00040004 : 0;
 				return data;
 				break;
 			case 0x080000:				// Real Time Clock
 				printf("READ NOTIMP: Realtime Clock\n");
 				break;
 			case 0x090000:				// Phone registers
 				switch (address & 0x0FF000) {
 					case 0x090000:		// Handset relay
 					case 0x098000:
 						break;
 					case 0x091000:		// Line select 2
 					case 0x099000:
 						break;
 					case 0x092000:		// Hook relay 1
 					case 0x09A000:
 						break;
 					case 0x093000:		// Hook relay 2
 					case 0x09B000:
 						break;
 					case 0x094000:		// Line 1 hold
 					case 0x09C000:
 						break;
 					case 0x095000:		// Line 2 hold
 					case 0x09D000:
 						break;
 					case 0x096000:		// Line 1 A-lead
 					case 0x09E000:
 						break;
 					case 0x097000:		// Line 2 A-lead
 					case 0x09F000:
 						break;
 				}
 				break;
 			case 0x0A0000:				// Miscellaneous Control Register -- write only!
 				handled = true;
 				break;
 			case 0x0B0000:				// TM/DIALWR
 				break;
 			case 0x0C0000:				// Clear Status Register -- write only!
 				handled = true;
 				break;
 			case 0x0D0000:				// DMA Address Register
 				break;
 			case 0x0E0000:				// Disk Control Register
 				break;
 			case 0x0F0000:				// Line Printer Data Register
 				break;
 		}
 	} else if ((address >= 0xC00000) && (address <= 0xFFFFFF)) {
 		// I/O register space, zone B
 		switch (address & 0xF00000) {
 			case 0xC00000:				// Expansion slots
 			case 0xD00000:
 				switch (address & 0xFC0000) {
 					case 0xC00000:		// Expansion slot 0
 					case 0xC40000:		// Expansion slot 1
 					case 0xC80000:		// Expansion slot 2
 					case 0xCC0000:		// Expansion slot 3
 					case 0xD00000:		// Expansion slot 4
 					case 0xD40000:		// Expansion slot 5
 					case 0xD80000:		// Expansion slot 6
 					case 0xDC0000:		// Expansion slot 7
 						fprintf(stderr, "NOTE: RD%d from expansion card space, addr=0x%08X\n", bits, address);
 						handled = true;
 						break;
 				}
 				break;
 			case 0xE00000:				// HDC, FDC, MCR2 and RTC data bits
 			case 0xF00000:
 				switch (address & 0x070000) {
 					case 0x000000:		// [ef][08]xxxx ==> WD1010 hard disc controller
 						return (wd2010_read_reg(&state.hdc_ctx, (address >> 1) & 7));
 						break;
 					case 0x010000:		// [ef][19]xxxx ==> WD2797 floppy disc controller
 						/*ENFORCE_SIZE_R(bits, address, 16, "FDC REGISTERS");*/
 						return wd2797_read_reg(&state.fdc_ctx, (address >> 1) & 3);
 						break;
 					case 0x020000:		// [ef][2a]xxxx ==> Miscellaneous Control Register 2
 						break;
 					case 0x030000:		// [ef][3b]xxxx ==> Real Time Clock data bits
 						break;
 					case 0x040000:		// [ef][4c]xxxx ==> General Control Register
 						switch (address & 0x077000) {
 							case 0x040000:		// [ef][4c][08]xxx ==> EE
 							case 0x041000:		// [ef][4c][19]xxx ==> PIE
 							case 0x042000:		// [ef][4c][2A]xxx ==> BP
 							case 0x043000:		// [ef][4c][3B]xxx ==> ROMLMAP
 							case 0x044000:		// [ef][4c][4C]xxx ==> L1 MODEM
 							case 0x045000:		// [ef][4c][5D]xxx ==> L2 MODEM
 							case 0x046000:		// [ef][4c][6E]xxx ==> D/N CONNECT
 								// All write-only registers... TODO: bus error?
 								handled = true;
 								break;
 							case 0x047000:		// [ef][4c][7F]xxx ==> Whole screen reverse video [FIXME: not in TRM]
 								break;
 						}
 						break;
 					case 0x050000:		// [ef][5d]xxxx ==> 8274
 						break;
 					case 0x060000:		// [ef][6e]xxxx ==> Control regs
 						switch (address & 0x07F000) {
 							default:
 								break;
 						}
 						break;
 					case 0x070000:		// [ef][7f]xxxx ==> 6850 Keyboard Controller
 						// TODO: figure out which sizes are valid (probably just 8 and 16)
 						//ENFORCE_SIZE_R(bits, address, 16, "KEYBOARD CONTROLLER");
 						{
 							if (bits == 8) {
 								return keyboard_read(&state.kbd, (address >> 1) & 3);
 							} else {
 								return keyboard_read(&state.kbd, (address >> 1) & 3) << 8;
 							}
 							return data;
 						}
 						break;
 				}
 		}
 	}
 	LOG_NOT_HANDLED_R(bits);
 	return data;
 }/*}}}*/
 /********************************************************
  * m68k memory read/write support functions for Musashi
  ********************************************************/
 /**
  * @brief Read M68K memory, 32-bit
  */
 uint32_t m68k_read_memory_32(uint32_t address)/*{{{*/
 {
 	uint32_t data = EMPTY & 0xFFFFFFFF;
 	// If ROMLMAP is set, force system to access ROM
 	if (!state.romlmap)
 		address |= 0x800000;
 	// Check access permissions
 	ACCESS_CHECK_RD(address, 32);
 	if ((address >= 0x800000) && (address <= 0xBFFFFF)) {
 		// ROM access
 		return RD32(state.rom, address, ROM_SIZE - 1);
 	} else if (address <= 0x3fffff) {
 		// RAM access
 		uint32_t newAddr = mapAddr(address, false);
 		if (newAddr <= 0x1fffff) {
 			// Base memory wraps around
 			return RD32(state.base_ram, newAddr, state.base_ram_size - 1);
 		} else {
 			if ((newAddr <= (state.exp_ram_size + 0x200000 - 1)) && (newAddr >= 0x200000))
 				return RD32(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1);
 			else
 				return EMPTY & 0xffffffff;
 		}
 	} else if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x000000:				// Map RAM access
 				if (address > 0x4007FF) fprintf(stderr, "NOTE: RD32 from MapRAM mirror, addr=0x%08X\n", address);
 				return RD32(state.map, address, 0x7FF);
 				break;
 			case 0x020000:				// Video RAM
 				if (address > 0x427FFF) fprintf(stderr, "NOTE: RD32 from VideoRAM mirror, addr=0x%08X\n", address);
 				return RD32(state.vram, address, 0x7FFF);
 				break;
 			default:
 				return IoRead(address, 32);
 		}
 	} else {
 		return IoRead(address, 32);
 	}
 	return data;
 }/*}}}*/
 /**
  * @brief Read M68K memory, 16-bit
  */
 uint32_t m68k_read_memory_16(uint32_t address)/*{{{*/
 {
 	uint16_t data = EMPTY & 0xFFFF;
 	// If ROMLMAP is set, force system to access ROM
 	if (!state.romlmap)
 		address |= 0x800000;
 	// Check access permissions
 	ACCESS_CHECK_RD(address, 16);
 	if ((address >= 0x800000) && (address <= 0xBFFFFF)) {
 		// ROM access
 		data = RD16(state.rom, address, ROM_SIZE - 1);
 	} else if (address <= 0x3fffff) {
 		// RAM access
 		uint32_t newAddr = mapAddr(address, false);
 		if (newAddr <= 0x1fffff) {
 			// Base memory wraps around
 			return RD16(state.base_ram, newAddr, state.base_ram_size - 1);
 		} else {
 			if ((newAddr <= (state.exp_ram_size + 0x200000 - 1)) && (newAddr >= 0x200000))
 				return RD16(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1);
 			else
 				return EMPTY & 0xffff;
 		}
 	} else if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x000000:				// Map RAM access
 				if (address > 0x4007FF) fprintf(stderr, "NOTE: RD16 from MapRAM mirror, addr=0x%08X\n", address);
 				data = RD16(state.map, address, 0x7FF);
 				break;
 			case 0x020000:				// Video RAM
 				if (address > 0x427FFF) fprintf(stderr, "NOTE: RD16 from VideoRAM mirror, addr=0x%08X\n", address);
 				data = RD16(state.vram, address, 0x7FFF);
 				break;
 			default:
 				data = IoRead(address, 16);
 		}
 	} else {
 		data = IoRead(address, 16);
 	}
 	return data;
 }/*}}}*/
 /**
  * @brief Read M68K memory, 8-bit
  */
 uint32_t m68k_read_memory_8(uint32_t address)/*{{{*/
 {
 	uint8_t data = EMPTY & 0xFF;
 	// If ROMLMAP is set, force system to access ROM
 	if (!state.romlmap)
 		address |= 0x800000;
 	// Check access permissions
 	ACCESS_CHECK_RD(address, 8);
 	if ((address >= 0x800000) && (address <= 0xBFFFFF)) {
 		// ROM access
 		data = RD8(state.rom, address, ROM_SIZE - 1);
 	} else if (address <= 0x3fffff) {
 		// RAM access
 		uint32_t newAddr = mapAddr(address, false);
 		if (newAddr <= 0x1fffff) {
 			// Base memory wraps around
 			return RD8(state.base_ram, newAddr, state.base_ram_size - 1);
 		} else {
 			if ((newAddr <= (state.exp_ram_size + 0x200000 - 1)) && (newAddr >= 0x200000))
 				return RD8(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1);
 			else
 				return EMPTY & 0xff;
 		}
 	} else if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x000000:				// Map RAM access
 				if (address > 0x4007FF) fprintf(stderr, "NOTE: RD8 from MapRAM mirror, addr=0x%08X\n", address);
 				data = RD8(state.map, address, 0x7FF);
 				break;
 			case 0x020000:				// Video RAM
 				if (address > 0x427FFF) fprintf(stderr, "NOTE: RD8 from VideoRAM mirror, addr=0x%08X\n", address);
 				data = RD8(state.vram, address, 0x7FFF);
 				break;
 			default:
 				data = IoRead(address, 8);
 		}
 	} else {
 		data = IoRead(address, 8);
 	}
 	return data;
 }/*}}}*/
 /**
  * @brief Write M68K memory, 32-bit
  */
 void m68k_write_memory_32(uint32_t address, uint32_t value)/*{{{*/
 {
 	// If ROMLMAP is set, force system to access ROM
 	if (!state.romlmap)
 		address |= 0x800000;
 	// Check access permissions
 	ACCESS_CHECK_WR(address, 32);
 	if ((address >= 0x800000) && (address <= 0xBFFFFF)) {
 		// ROM access
 	} else if (address <= 0x3FFFFF) {
 		// RAM access
 		uint32_t newAddr = mapAddr(address, true);
 		if (newAddr <= 0x1fffff) {
 			if (newAddr < state.base_ram_size) {
 				WR32(state.base_ram, newAddr, state.base_ram_size - 1, value);
 			}
 		} else {
 			if ((newAddr - 0x200000) < state.exp_ram_size) {
 				WR32(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1, value);
 			}
 		}
 	} else if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x000000:				// Map RAM access
 				if (address > 0x4007FF) fprintf(stderr, "NOTE: WR32 to MapRAM mirror, addr=0x%08X\n", address);
 				WR32(state.map, address, 0x7FF, value);
 				break;
 			case 0x020000:				// Video RAM
 				if (address > 0x427FFF) fprintf(stderr, "NOTE: WR32 to VideoRAM mirror, addr=0x%08X\n", address);
 				WR32(state.vram, address, 0x7FFF, value);
 				break;
 			default:
 				IoWrite(address, value, 32);
 		}
 	} else {
 		IoWrite(address, value, 32);
 	}
 }/*}}}*/
 /**
  * @brief Write M68K memory, 16-bit
  */
 void m68k_write_memory_16(uint32_t address, uint32_t value)/*{{{*/
 {
 	// If ROMLMAP is set, force system to access ROM
 	if (!state.romlmap)
 		address |= 0x800000;
 	// Check access permissions
 	ACCESS_CHECK_WR(address, 16);
 	if ((address >= 0x800000) && (address <= 0xBFFFFF)) {
 		// ROM access
 	} else if (address <= 0x3FFFFF) {
 		// RAM access
 		uint32_t newAddr = mapAddr(address, true);
 		if (newAddr <= 0x1fffff) {
 			if (newAddr < state.base_ram_size) {
 				WR16(state.base_ram, newAddr, state.base_ram_size - 1, value);
 			}
 		} else {
 			if ((newAddr - 0x200000) < state.exp_ram_size) {
 				WR16(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1, value);
 			}
 		}
 	} else if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x000000:				// Map RAM access
 				if (address > 0x4007FF) fprintf(stderr, "NOTE: WR16 to MapRAM mirror, addr=0x%08X, data=0x%04X\n", address, value);
 				WR16(state.map, address, 0x7FF, value);
 				break;
 			case 0x020000:				// Video RAM
 				if (address > 0x427FFF) fprintf(stderr, "NOTE: WR16 to VideoRAM mirror, addr=0x%08X, data=0x%04X\n", address, value);
 				WR16(state.vram, address, 0x7FFF, value);
 				break;
 			default:
 				IoWrite(address, value, 16);
 		}
 	} else {
 		IoWrite(address, value, 16);
 	}
 }/*}}}*/
 /**
  * @brief Write M68K memory, 8-bit
  */
 void m68k_write_memory_8(uint32_t address, uint32_t value)/*{{{*/
 {
 	// If ROMLMAP is set, force system to access ROM
 	if (!state.romlmap)
 		address |= 0x800000;
 	// Check access permissions
 	ACCESS_CHECK_WR(address, 8);
 	if ((address >= 0x800000) && (address <= 0xBFFFFF)) {
 		// ROM access (read only!)
 	} else if (address <= 0x3FFFFF) {
 		// RAM access
 		uint32_t newAddr = mapAddr(address, true);
 		if (newAddr <= 0x1fffff) {
 			if (newAddr < state.base_ram_size) {
 				WR8(state.base_ram, newAddr, state.base_ram_size - 1, value);
 			}
 		} else {
 			if ((newAddr - 0x200000) < state.exp_ram_size) {
 				WR8(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1, value);
 			}
 		}
 	} else if ((address >= 0x400000) && (address <= 0x7FFFFF)) {
 		// I/O register space, zone A
 		switch (address & 0x0F0000) {
 			case 0x000000:				// Map RAM access
 				if (address > 0x4007FF) fprintf(stderr, "NOTE: WR8 to MapRAM mirror, addr=0x%08X, data=0x%04X\n", address, value);
 				WR8(state.map, address, 0x7FF, value);
 				break;
 			case 0x020000:				// Video RAM
 				if (address > 0x427FFF) fprintf(stderr, "NOTE: WR8 to VideoRAM mirror, addr=0x%08X, data=0x%04X\n", address, value);
 				WR8(state.vram, address, 0x7FFF, value);
 				break;
 			default:
 				IoWrite(address, value, 8);
 		}
 	} else {
 		IoWrite(address, value, 8);
 	}
 }/*}}}*/
 // for the disassembler
 uint32_t m68k_read_disassembler_32(uint32_t addr)
 {
 	if (addr < 0x400000) {
 		uint16_t page = (addr >> 12) & 0x3FF;
 		uint32_t new_page_addr = MAPRAM(page) & 0x3FF;
 		uint32_t newAddr = (new_page_addr << 12) + (addr & 0xFFF);
 		if (newAddr <= 0x1fffff) {
 			if (newAddr >= state.base_ram_size)
 				return EMPTY;
 			else
 				return RD32(state.base_ram, newAddr, state.base_ram_size - 1);
 		} else {
 			if ((newAddr <= (state.exp_ram_size + 0x200000 - 1)) && (newAddr >= 0x200000))
 				return RD32(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1);
 			else
 				return EMPTY;
 		}
 	} else {
 		printf(">>> WARNING Disassembler RD32 out of range 0x%08X\n", addr);
 		return EMPTY;
 	}
 }
 uint32_t m68k_read_disassembler_16(uint32_t addr)
 {
 	if (addr < 0x400000) {
 		uint16_t page = (addr >> 12) & 0x3FF;
 		uint32_t new_page_addr = MAPRAM(page) & 0x3FF;
 		uint32_t newAddr = (new_page_addr << 12) + (addr & 0xFFF);
 		if (newAddr <= 0x1fffff) {
 			if (newAddr >= state.base_ram_size)
 				return EMPTY & 0xffff;
 			else
 				return RD16(state.base_ram, newAddr, state.base_ram_size - 1);
 		} else {
 			if ((newAddr <= (state.exp_ram_size + 0x200000 - 1)) && (newAddr >= 0x200000))
 				return RD16(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1);
 			else
 				return EMPTY & 0xffff;
 		}
 	} else {
 		printf(">>> WARNING Disassembler RD16 out of range 0x%08X\n", addr);
 		return EMPTY & 0xffff;
 	}
 }
 uint32_t m68k_read_disassembler_8 (uint32_t addr)
 {
 	if (addr < 0x400000) {
 		uint16_t page = (addr >> 12) & 0x3FF;
 		uint32_t new_page_addr = MAPRAM(page) & 0x3FF;
 		uint32_t newAddr = (new_page_addr << 12) + (addr & 0xFFF);
 		if (newAddr <= 0x1fffff) {
 			if (newAddr >= state.base_ram_size)
 				return EMPTY & 0xff;
 			else
 				return RD8(state.base_ram, newAddr, state.base_ram_size - 1);
 		} else {
 			if ((newAddr <= (state.exp_ram_size + 0x200000 - 1)) && (newAddr >= 0x200000))
 				return RD8(state.exp_ram, newAddr - 0x200000, state.exp_ram_size - 1);
 			else
 				return EMPTY & 0xff;
 		}
 	} else {
 		printf(">>> WARNING Disassembler RD8 out of range 0x%08X\n", addr);
 		return EMPTY & 0xff;
 	}
 }

3b1emu / annotate

src/memory.c@8b24770dea79 (annotated)

src/memory.c