/* ======================================================================== */
/* ================================ INCLUDES ============================== */
/* ======================================================================== */
-
-extern void m68040_fpu_op0(void);
-extern void m68040_fpu_op1(void);
-extern void m68881_mmu_ops();
+struct m68ki_cpu_core;
+extern void m68040_fpu_op0(struct m68ki_cpu_core *state);
+extern void m68040_fpu_op1(struct m68ki_cpu_core *state);
+extern void m68851_mmu_ops(struct m68ki_cpu_core *state);
extern unsigned char m68ki_cycles[][0x10000];
-extern void (*m68ki_instruction_jump_table[0x10000])(void); /* opcode handler jump table */
extern void m68ki_build_opcode_table(void);
#include "m68kops.h"
34, /* 7: TRAPV */
34, /* 8: Privilege Violation */
34, /* 9: Trace */
- 34, /* 10: 1010 */
- 34, /* 11: 1111 */
+ 4, /* 10: 1010 */
+ 4, /* 11: 1111 */
4, /* 12: RESERVED */
4, /* 13: Coprocessor Protocol Violation (unemulated) */
4, /* 14: Format Error */
case M68K_REG_A6: return cpu->dar[14];
case M68K_REG_A7: return cpu->dar[15];
case M68K_REG_PC: return MASK_OUT_ABOVE_32(cpu->pc);
- case M68K_REG_SR: return cpu->t1_flag |
- cpu->t0_flag |
+ case M68K_REG_SR: return cpu->t1_flag |
+ cpu->t0_flag |
(cpu->s_flag << 11) |
(cpu->m_flag << 11) |
- cpu->int_mask |
+ cpu->int_mask |
((cpu->x_flag & XFLAG_SET) >> 4) |
((cpu->n_flag & NFLAG_SET) >> 4) |
((!cpu->not_z_flag) << 2) |
{
case CPU_TYPE_000: return (unsigned int)M68K_CPU_TYPE_68000;
case CPU_TYPE_010: return (unsigned int)M68K_CPU_TYPE_68010;
- case CPU_TYPE_EC020: return (unsigned int)M68K_CPU_TYPE_68EC020;
+ case CPU_TYPE_EC020: return (unsigned int)M68K_CPU_TYPE_68EC020;
case CPU_TYPE_020: return (unsigned int)M68K_CPU_TYPE_68020;
+ case CPU_TYPE_EC030: return (unsigned int)M68K_CPU_TYPE_68EC030;
+ case CPU_TYPE_030: return (unsigned int)M68K_CPU_TYPE_68030;
+ case CPU_TYPE_EC040: return (unsigned int)M68K_CPU_TYPE_68EC040;
+ case CPU_TYPE_LC040: return (unsigned int)M68K_CPU_TYPE_68LC040;
case CPU_TYPE_040: return (unsigned int)M68K_CPU_TYPE_68040;
}
return M68K_CPU_TYPE_INVALID;
return 0;
}
-void m68k_set_reg(m68k_register_t regnum, unsigned int value)
+void m68k_set_reg(void *context, m68k_register_t regnum, unsigned int value)
{
+ m68ki_cpu_core* state = context != NULL ?(m68ki_cpu_core*)context : &m68ki_cpu;
switch(regnum)
{
case M68K_REG_D0: REG_D[0] = MASK_OUT_ABOVE_32(value); return;
case M68K_REG_A5: REG_A[5] = MASK_OUT_ABOVE_32(value); return;
case M68K_REG_A6: REG_A[6] = MASK_OUT_ABOVE_32(value); return;
case M68K_REG_A7: REG_A[7] = MASK_OUT_ABOVE_32(value); return;
- case M68K_REG_PC: m68ki_jump(MASK_OUT_ABOVE_32(value)); return;
- case M68K_REG_SR: m68ki_set_sr_noint_nosp(value); return;
+ case M68K_REG_PC:
+ m68ki_jump(state, MASK_OUT_ABOVE_32(value)); return;
+ case M68K_REG_SR:
+ m68ki_set_sr_noint_nosp(state, value); return;
case M68K_REG_SP: REG_SP = MASK_OUT_ABOVE_32(value); return;
case M68K_REG_USP: if(FLAG_S)
REG_USP = MASK_OUT_ABOVE_32(value);
case M68K_REG_CAAR: REG_CAAR = MASK_OUT_ABOVE_32(value); return;
case M68K_REG_PPC: REG_PPC = MASK_OUT_ABOVE_32(value); return;
case M68K_REG_IR: REG_IR = MASK_OUT_ABOVE_16(value); return;
- case M68K_REG_CPU_TYPE: m68k_set_cpu_type(value); return;
+ case M68K_REG_CPU_TYPE:
+ m68k_set_cpu_type(state, value); return;
default: return;
}
}
}
/* Set the CPU type. */
-void m68k_set_cpu_type(unsigned int cpu_type)
+void m68k_set_cpu_type(struct m68ki_cpu_core *state, unsigned int cpu_type)
{
switch(cpu_type)
{
HAS_FPU = 0;
return;
case M68K_CPU_TYPE_SCC68070:
- m68k_set_cpu_type(M68K_CPU_TYPE_68010);
+ m68k_set_cpu_type(state, M68K_CPU_TYPE_68010);
CPU_ADDRESS_MASK = 0xffffffff;
CPU_TYPE = CPU_TYPE_SCC070;
return;
case M68K_CPU_TYPE_68LC040:
CPU_TYPE = CPU_TYPE_LC040;
CPU_ADDRESS_MASK = 0xffffffff;
- m68ki_cpu.sr_mask = 0xf71f; /* T1 T0 S M -- I2 I1 I0 -- -- -- X N Z V C */
- m68ki_cpu.cyc_instruction = m68ki_cycles[4];
- m68ki_cpu.cyc_exception = m68ki_exception_cycle_table[4];
- m68ki_cpu.cyc_bcc_notake_b = -2;
- m68ki_cpu.cyc_bcc_notake_w = 0;
- m68ki_cpu.cyc_dbcc_f_noexp = 0;
- m68ki_cpu.cyc_dbcc_f_exp = 4;
- m68ki_cpu.cyc_scc_r_true = 0;
- m68ki_cpu.cyc_movem_w = 2;
- m68ki_cpu.cyc_movem_l = 2;
- m68ki_cpu.cyc_shift = 0;
- m68ki_cpu.cyc_reset = 518;
+ state->sr_mask = 0xf71f; /* T1 T0 S M -- I2 I1 I0 -- -- -- X N Z V C */
+ state->cyc_instruction = m68ki_cycles[4];
+ state->cyc_exception = m68ki_exception_cycle_table[4];
+ state->cyc_bcc_notake_b = -2;
+ state->cyc_bcc_notake_w = 0;
+ state->cyc_dbcc_f_noexp = 0;
+ state->cyc_dbcc_f_exp = 4;
+ state->cyc_scc_r_true = 0;
+ state->cyc_movem_w = 2;
+ state->cyc_movem_l = 2;
+ state->cyc_shift = 0;
+ state->cyc_reset = 518;
HAS_PMMU = 1;
HAS_FPU = 0;
return;
}
}
-uint m68k_get_address_mask() {
- return m68ki_cpu.address_mask;
+uint m68k_get_address_mask(m68ki_cpu_core *state) {
+ return state->address_mask;
}
/* Execute some instructions until we use up num_cycles clock cycles */
/* ASG: removed per-instruction interrupt checks */
-int m68k_execute(int num_cycles)
+int m68k_execute(m68ki_cpu_core *state, int num_cycles)
{
/* eat up any reset cycles */
if (RESET_CYCLES) {
m68ki_initial_cycles = num_cycles;
/* See if interrupts came in */
- m68ki_check_interrupts();
+ m68ki_check_interrupts(state);
/* Make sure we're not stopped */
if(!CPU_STOPPED)
{
/* Return point if we had an address error */
- m68ki_set_address_error_trap(); /* auto-disable (see m68kcpu.h) */
+ m68ki_set_address_error_trap(state); /* auto-disable (see m68kcpu.h) */
#ifdef M68K_BUSERR_THING
m68ki_check_bus_error_trap();
/* Main loop. Keep going until we run out of clock cycles */
do
{
-#ifdef M68K_BUSERR_THING
- int i;
-#endif
- /* Set tracing accodring to T1. (T0 is done inside instruction) */
+ /* Set tracing according to T1. (T0 is done inside instruction) */
m68ki_trace_t1(); /* auto-disable (see m68kcpu.h) */
/* Set the address space for reads */
REG_PPC = REG_PC;
/* Record previous D/A register state (in case of bus error) */
+//#define M68K_BUSERR_THING
#ifdef M68K_BUSERR_THING
- for (i = 15; i >= 0; i--){
+ for (int i = 15; i >= 0; i--){
REG_DA_SAVE[i] = REG_DA[i];
}
#endif
/* Read an instruction and call its handler */
- REG_IR = m68ki_read_imm_16();
- m68ki_instruction_jump_table[REG_IR]();
+ REG_IR = m68ki_read_imm_16(state);
+ m68ki_instruction_jump_table[REG_IR](state);
USE_CYCLES(CYC_INSTRUCTION[REG_IR]);
/* Trace m68k_exception, if necessary */
/* The first call to this function initializes the opcode handler jump table */
if(!emulation_initialized)
- {
+ {
m68ki_build_opcode_table();
emulation_initialized = 1;
}
}
/* Trigger a Bus Error exception */
-void m68k_pulse_bus_error(void)
+void m68k_pulse_bus_error(m68ki_cpu_core *state)
{
- m68ki_exception_bus_error();
+ m68ki_exception_bus_error(state);
}
/* Pulse the RESET line on the CPU */
-void m68k_pulse_reset(void)
+void m68k_pulse_reset(m68ki_cpu_core *state)
{
- /* Disable the PMMU on reset */
- m68ki_cpu.pmmu_enabled = 0;
+ /* Disable the PMMU/HMMU on reset, if any */
+ state->pmmu_enabled = 0;
+// state->hmmu_enabled = 0;
+
+ state->mmu_tc = 0;
+ state->mmu_tt0 = 0;
+ state->mmu_tt1 = 0;
/* Clear all stop levels and eat up all remaining cycles */
CPU_STOPPED = 0;
/* Interrupt mask to level 7 */
FLAG_INT_MASK = 0x0700;
CPU_INT_LEVEL = 0;
- m68ki_cpu.virq_state = 0;
+ state->virq_state = 0;
/* Reset VBR */
REG_VBR = 0;
/* Go to supervisor mode */
- m68ki_set_sm_flag(SFLAG_SET | MFLAG_CLEAR);
+ m68ki_set_sm_flag(state, SFLAG_SET | MFLAG_CLEAR);
/* Invalidate the prefetch queue */
#if M68K_EMULATE_PREFETCH
#endif /* M68K_EMULATE_PREFETCH */
/* Read the initial stack pointer and program counter */
- m68ki_jump(0);
- REG_SP = m68ki_read_imm_32();
- REG_PC = m68ki_read_imm_32();
- m68ki_jump(REG_PC);
+ m68ki_jump(state, 0);
+ REG_SP = m68ki_read_imm_32(state);
+ REG_PC = m68ki_read_imm_32(state);
+ m68ki_jump(state, REG_PC);
CPU_RUN_MODE = RUN_MODE_NORMAL;
RESET_CYCLES = CYC_EXCEPTION[EXCEPTION_RESET];
+
+ /* flush the MMU's cache */
+ pmmu_atc_flush(state);
+
+ if(CPU_TYPE_IS_EC020_PLUS(CPU_TYPE))
+ {
+ // clear instruction cache
+ m68ki_ic_clear(state);
+ }
}
/* Pulse the HALT line on the CPU */
#if M68K_SEPARATE_READS
/* Read data immediately following the PC */
-inline unsigned int m68k_read_immediate_16(unsigned int address) {
+inline unsigned int m68k_read_immediate_16(m68ki_cpu_core *state, unsigned int address) {
#if M68K_EMULATE_PREFETCH == OPT_ON
- for (int i = 0; i < read_ranges; i++) {
- if(address >= read_addr[i] && address < read_upper[i]) {
- return be16toh(((unsigned short *)(read_data[i] + (address - read_addr[i])))[0]);
+ for (int i = 0; i < state->read_ranges; i++) {
+ if(address >= state->read_addr[i] && address < state->read_upper[i]) {
+ return be16toh(((unsigned short *)(state->read_data[i] + (address - state->read_addr[i])))[0]);
}
}
#endif
-
+
return m68k_read_memory_16(address);
}
-inline unsigned int m68k_read_immediate_32(unsigned int address) {
+inline unsigned int m68k_read_immediate_32(m68ki_cpu_core *state, unsigned int address) {
#if M68K_EMULATE_PREFETCH == OPT_ON
- for (int i = 0; i < read_ranges; i++) {
- if(address >= read_addr[i] && address < read_upper[i]) {
- return be32toh(((unsigned int *)(read_data[i] + (address - read_addr[i])))[0]);
+ for (int i = 0; i < state->read_ranges; i++) {
+ if(address >= state->read_addr[i] && address < state->read_upper[i]) {
+ return be32toh(((unsigned int *)(state->read_data[i] + (address - state->read_addr[i])))[0]);
}
}
#endif
}
/* Read data relative to the PC */
-inline unsigned int m68k_read_pcrelative_8(unsigned int address) {
- for (int i = 0; i < read_ranges; i++) {
- if(address >= read_addr[i] && address < read_upper[i]) {
- return read_data[i][address - read_addr[i]];
+inline unsigned int m68k_read_pcrelative_8(m68ki_cpu_core *state, unsigned int address) {
+ for (int i = 0; i < state->read_ranges; i++) {
+ if(address >= state->read_addr[i] && address < state->read_upper[i]) {
+ return state->read_data[i][address - state->read_addr[i]];
}
}
-
+
return m68k_read_memory_8(address);
}
-inline unsigned int m68k_read_pcrelative_16(unsigned int address) {
- for (int i = 0; i < read_ranges; i++) {
- if(address >= read_addr[i] && address < read_upper[i]) {
- return be16toh(((unsigned short *)(read_data[i] + (address - read_addr[i])))[0]);
+inline unsigned int m68k_read_pcrelative_16(m68ki_cpu_core *state, unsigned int address) {
+ for (int i = 0; i < state->read_ranges; i++) {
+ if(address >= state->read_addr[i] && address < state->read_upper[i]) {
+ return be16toh(((unsigned short *)(state->read_data[i] + (address - state->read_addr[i])))[0]);
}
}
return m68k_read_memory_16(address);
}
-inline unsigned int m68k_read_pcrelative_32(unsigned int address) {
- for (int i = 0; i < read_ranges; i++) {
- if(address >= read_addr[i] && address < read_upper[i]) {
- return be32toh(((unsigned int *)(read_data[i] + (address - read_addr[i])))[0]);
+inline unsigned int m68k_read_pcrelative_32(m68ki_cpu_core *state, unsigned int address) {
+ for (int i = 0; i < state->read_ranges; i++) {
+ if(address >= state->read_addr[i] && address < state->read_upper[i]) {
+ return be32toh(((unsigned int *)(state->read_data[i] + (address - state->read_addr[i])))[0]);
}
}
}
#endif
+
+uint m68ki_read_imm16_addr_slowpath(m68ki_cpu_core *state, uint32_t pc, address_translation_cache *cache)
+{
+ uint32_t address = ADDRESS_68K(pc);
+ uint32_t pc_address_diff = pc - address;
+ for (int i = 0; i < state->read_ranges; i++) {
+ if(address >= state->read_addr[i] && address < state->read_upper[i]) {
+ cache->lower = state->read_addr[i] + pc_address_diff;
+ cache->upper = state->read_upper[i] + pc_address_diff;
+ cache->offset = state->read_data[i] - cache->lower;
+ REG_PC += 2;
+ return be16toh(((unsigned short *)(state->read_data[i] + (address - state->read_addr[i])))[0]);
+ }
+ }
+
+ m68ki_set_fc(FLAG_S | FUNCTION_CODE_USER_PROGRAM); /* auto-disable (see m68kcpu.h) */
+ state->mmu_tmp_fc = FLAG_S | FUNCTION_CODE_USER_PROGRAM;
+ state->mmu_tmp_rw = 1;
+ state->mmu_tmp_sz = M68K_SZ_WORD;
+ m68ki_check_address_error(state, REG_PC, MODE_READ, FLAG_S | FUNCTION_CODE_USER_PROGRAM); /* auto-disable (see m68kcpu.h) */
+
+#if M68K_EMULATE_PREFETCH
+{
+ uint result;
+ if(REG_PC != CPU_PREF_ADDR)
+ {
+ CPU_PREF_DATA = m68ki_ic_readimm16(state, REG_PC);
+ CPU_PREF_ADDR = state->mmu_tmp_buserror_occurred ? ((uint32)~0) : REG_PC;
+ }
+ result = MASK_OUT_ABOVE_16(CPU_PREF_DATA);
+ REG_PC += 2;
+ if (!state->mmu_tmp_buserror_occurred) {
+ // prefetch only if no bus error occurred in opcode fetch
+ CPU_PREF_DATA = m68ki_ic_readimm16(state, REG_PC);
+ CPU_PREF_ADDR = state->mmu_tmp_buserror_occurred ? ((uint32)~0) : REG_PC;
+ // ignore bus error on prefetch
+ state->mmu_tmp_buserror_occurred = 0;
+ }
+ return result;
+}
+#else
+ REG_PC += 2;
+
+ return m68k_read_immediate_16(address);
+#endif /* M68K_EMULATE_PREFETCH */
+}
+
+
+
void m68k_add_ram_range(uint32_t addr, uint32_t upper, unsigned char *ptr)
{
+ m68ki_cpu.code_translation_cache.lower = 0;
+ m68ki_cpu.code_translation_cache.upper = 0;
if ((addr == 0 && upper == 0) || upper < addr)
return;
- for (int i = 0; i < write_ranges; i++) {
- if (write_addr[i] == addr) {
+ for (int i = 0; i < m68ki_cpu.write_ranges; i++) {
+ if (m68ki_cpu.write_addr[i] == addr) {
uint8_t changed = 0;
- if (write_upper[i] != upper) {
- write_upper[i] = upper;
+ if (m68ki_cpu.write_upper[i] != upper) {
+ m68ki_cpu.write_upper[i] = upper;
changed = 1;
}
- if (write_data[i] != ptr) {
- write_data[i] = ptr;
+ if (m68ki_cpu.write_data[i] != ptr) {
+ m68ki_cpu.write_data[i] = ptr;
changed = 1;
}
if (changed) {
- printf("[MUSASHI] Adjusted mapped write range %d: %.8X-%.8X (%p)\n", write_ranges, addr, upper, ptr);
+ printf("[MUSASHI] Adjusted mapped write range %d: %.8X-%.8X (%p)\n", m68ki_cpu.write_ranges, addr, upper, ptr);
}
return;
}
}
- if (read_ranges + 1 < 8) {
- read_addr[read_ranges] = addr;
- read_upper[read_ranges] = upper;
- read_data[read_ranges] = ptr;
- read_ranges++;
- printf("[MUSASHI] Mapped read range %d: %.8X-%.8X (%p)\n", read_ranges, addr, upper, ptr);
+ if (m68ki_cpu.read_ranges + 1 < 8) {
+ m68ki_cpu.read_addr[m68ki_cpu.read_ranges] = addr;
+ m68ki_cpu.read_upper[m68ki_cpu.read_ranges] = upper;
+ m68ki_cpu.read_data[m68ki_cpu.read_ranges] = ptr;
+ m68ki_cpu.read_ranges++;
+ printf("[MUSASHI] Mapped read range %d: %.8X-%.8X (%p)\n", m68ki_cpu.read_ranges, addr, upper, ptr);
}
else {
printf("Can't Musashi map more than eight RAM/ROM read ranges.\n");
}
- if (write_ranges + 1 < 8) {
- write_addr[write_ranges] = addr;
- write_upper[write_ranges] = upper;
- write_data[write_ranges] = ptr;
- write_ranges++;
- printf("[MUSASHI] Mapped write range %d: %.8X-%.8X (%p)\n", write_ranges, addr, upper, ptr);
+ if (m68ki_cpu.write_ranges + 1 < 8) {
+ m68ki_cpu.write_addr[m68ki_cpu.write_ranges] = addr;
+ m68ki_cpu.write_upper[m68ki_cpu.write_ranges] = upper;
+ m68ki_cpu.write_data[m68ki_cpu.write_ranges] = ptr;
+ m68ki_cpu.write_ranges++;
+ printf("[MUSASHI] Mapped write range %d: %.8X-%.8X (%p)\n", m68ki_cpu.write_ranges, addr, upper, ptr);
}
else {
printf("Can't Musashi map more than eight RAM write ranges.\n");
void m68k_add_rom_range(uint32_t addr, uint32_t upper, unsigned char *ptr)
{
+ m68ki_cpu.code_translation_cache.lower = 0;
+ m68ki_cpu.code_translation_cache.upper = 0;
if ((addr == 0 && upper == 0) || upper < addr)
return;
- for (int i = 0; i < read_ranges; i++) {
- if (read_addr[i] == addr) {
+ for (int i = 0; i < m68ki_cpu.read_ranges; i++) {
+ if (m68ki_cpu.read_addr[i] == addr) {
uint8_t changed = 0;
- if (read_upper[i] != upper) {
- read_upper[i] = upper;
+ if (m68ki_cpu.read_upper[i] != upper) {
+ m68ki_cpu.read_upper[i] = upper;
changed = 1;
}
- if (read_data[i] != ptr) {
- read_data[i] = ptr;
+ if (m68ki_cpu.read_data[i] != ptr) {
+ m68ki_cpu.read_data[i] = ptr;
changed = 1;
}
if (changed) {
- printf("[MUSASHI] Adjusted mapped read range %d: %.8X-%.8X (%p)\n", read_ranges, addr, upper, ptr);
+ printf("[MUSASHI] Adjusted mapped read range %d: %.8X-%.8X (%p)\n", m68ki_cpu.read_ranges, addr, upper, ptr);
}
return;
}
}
- if (read_ranges + 1 < 8) {
- read_addr[read_ranges] = addr;
- read_upper[read_ranges] = upper;
- read_data[read_ranges] = ptr;
- read_ranges++;
- printf("[MUSASHI] Mapped read range %d: %.8X-%.8X (%p)\n", read_ranges, addr, upper, ptr);
+ if (m68ki_cpu.read_ranges + 1 < 8) {
+ m68ki_cpu.read_addr[m68ki_cpu.read_ranges] = addr;
+ m68ki_cpu.read_upper[m68ki_cpu.read_ranges] = upper;
+ m68ki_cpu.read_data[m68ki_cpu.read_ranges] = ptr;
+ m68ki_cpu.read_ranges++;
+ printf("[MUSASHI] Mapped read range %d: %.8X-%.8X (%p)\n", m68ki_cpu.read_ranges, addr, upper, ptr);
}
else {
printf("Can't Musashi map more than eight RAM/ROM read ranges.\n");
}
}
+void m68k_clear_ranges()
+{
+ printf("[MUSASHI] Clearing all reads/write memory ranges.\n");
+ for (int i = 0; i < 8; i++) {
+ m68ki_cpu.read_upper[i] = 0;
+ m68ki_cpu.read_addr[i] = 0;
+ m68ki_cpu.read_data[i] = NULL;
+ m68ki_cpu.write_upper[i] = 0;
+ m68ki_cpu.write_addr[i] = 0;
+ m68ki_cpu.write_data[i] = NULL;
+ }
+ m68ki_cpu.write_ranges = 0;
+ m68ki_cpu.read_ranges = 0;
+ m68ki_cpu.code_translation_cache.lower = 0;
+ m68ki_cpu.code_translation_cache.upper = 0;
+}
+
/* ======================================================================== */
/* ============================== MAME STUFF ============================== */
/* ======================================================================== */