lxdream.org :: lxdream/src/sh4/sh4.c r526:ba3da45b5754 (annotated)

tree revision 541:6986c644d58a

filename	src/sh4/sh4.c
changeset	526:ba3da45b5754
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author	nkeynes
date	Wed Nov 21 11:45:33 2007 +0000 (16 years ago)
permissions	-rw-r--r--
last change	Add config guard around GTK display device

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nkeynes@378	1	/**
nkeynes@502	2	* $Id: sh4.c,v 1.7 2007-11-08 11:54:16 nkeynes Exp $
nkeynes@378	3	*
nkeynes@378	4	* SH4 parent module for all CPU modes and SH4 peripheral
nkeynes@378	5	* modules.
nkeynes@378	6	*
nkeynes@378	7	* Copyright (c) 2005 Nathan Keynes.
nkeynes@378	8	*
nkeynes@378	9	* This program is free software; you can redistribute it and/or modify
nkeynes@378	10	* it under the terms of the GNU General Public License as published by
nkeynes@378	11	* the Free Software Foundation; either version 2 of the License, or
nkeynes@378	12	* (at your option) any later version.
nkeynes@378	13	*
nkeynes@378	14	* This program is distributed in the hope that it will be useful,
nkeynes@378	15	* but WITHOUT ANY WARRANTY; without even the implied warranty of
nkeynes@378	16	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
nkeynes@378	17	* GNU General Public License for more details.
nkeynes@378	18	*/
nkeynes@378	19
nkeynes@378	20	#define MODULE sh4_module
nkeynes@378	21	#include <math.h>
nkeynes@378	22	#include "dream.h"
nkeynes@422	23	#include "dreamcast.h"
nkeynes@378	24	#include "sh4/sh4core.h"
nkeynes@378	25	#include "sh4/sh4mmio.h"
nkeynes@378	26	#include "sh4/intc.h"
nkeynes@422	27	#include "sh4/xltcache.h"
nkeynes@422	28	#include "sh4/sh4stat.h"
nkeynes@378	29	#include "mem.h"
nkeynes@378	30	#include "clock.h"
nkeynes@378	31	#include "syscall.h"
nkeynes@378	32
nkeynes@401	33	#define EXV_EXCEPTION 0x100 /* General exception vector */
nkeynes@401	34	#define EXV_TLBMISS 0x400 /* TLB-miss exception vector */
nkeynes@401	35	#define EXV_INTERRUPT 0x600 /* External interrupt vector */
nkeynes@401	36
nkeynes@378	37	void sh4_init( void );
nkeynes@526	38	void sh4_xlat_init( void );
nkeynes@378	39	void sh4_reset( void );
nkeynes@378	40	void sh4_start( void );
nkeynes@378	41	void sh4_stop( void );
nkeynes@378	42	void sh4_save_state( FILE *f );
nkeynes@378	43	int sh4_load_state( FILE *f );
nkeynes@378	44
nkeynes@378	45	uint32_t sh4_run_slice( uint32_t );
nkeynes@378	46	uint32_t sh4_xlat_run_slice( uint32_t );
nkeynes@378	47
nkeynes@378	48	struct dreamcast_module sh4_module = { "SH4", sh4_init, sh4_reset,
nkeynes@378	49	NULL, sh4_run_slice, sh4_stop,
nkeynes@378	50	sh4_save_state, sh4_load_state };
nkeynes@378	51
nkeynes@378	52	struct sh4_registers sh4r;
nkeynes@378	53	struct breakpoint_struct sh4_breakpoints[MAX_BREAKPOINTS];
nkeynes@378	54	int sh4_breakpoint_count = 0;
nkeynes@502	55	extern sh4ptr_t sh4_main_ram;
nkeynes@526	56	static gboolean sh4_use_translator = FALSE;
nkeynes@378	57
nkeynes@378	58	void sh4_set_use_xlat( gboolean use )
nkeynes@378	59	{
nkeynes@526	60	// No-op if the translator was not built
nkeynes@526	61	#ifdef SH4_TRANSLATOR
nkeynes@378	62	if( use ) {
nkeynes@378	63	xlat_cache_init();
nkeynes@378	64	sh4_x86_init();
nkeynes@378	65	sh4_module.run_time_slice = sh4_xlat_run_slice;
nkeynes@378	66	} else {
nkeynes@378	67	sh4_module.run_time_slice = sh4_run_slice;
nkeynes@378	68	}
nkeynes@526	69	sh4_use_translator = use;
nkeynes@526	70	#endif
nkeynes@378	71	}
nkeynes@378	72
nkeynes@378	73	void sh4_init(void)
nkeynes@378	74	{
nkeynes@378	75	register_io_regions( mmio_list_sh4mmio );
nkeynes@418	76	sh4_main_ram = mem_get_region_by_name(MEM_REGION_MAIN);
nkeynes@378	77	MMU_init();
nkeynes@378	78	sh4_reset();
nkeynes@378	79	}
nkeynes@378	80
nkeynes@378	81	void sh4_reset(void)
nkeynes@378	82	{
nkeynes@526	83	if( sh4_use_translator ) {
nkeynes@472	84	xlat_flush_cache();
nkeynes@472	85	}
nkeynes@472	86
nkeynes@378	87	/* zero everything out, for the sake of having a consistent state. */
nkeynes@378	88	memset( &sh4r, 0, sizeof(sh4r) );
nkeynes@378	89
nkeynes@378	90	/* Resume running if we were halted */
nkeynes@378	91	sh4r.sh4_state = SH4_STATE_RUNNING;
nkeynes@378	92
nkeynes@378	93	sh4r.pc = 0xA0000000;
nkeynes@378	94	sh4r.new_pc= 0xA0000002;
nkeynes@378	95	sh4r.vbr = 0x00000000;
nkeynes@378	96	sh4r.fpscr = 0x00040001;
nkeynes@378	97	sh4r.sr = 0x700000F0;
nkeynes@378	98	sh4r.fr_bank = &sh4r.fr[0][0];
nkeynes@378	99
nkeynes@378	100	/* Mem reset will do this, but if we want to reset _just_ the SH4... */
nkeynes@378	101	MMIO_WRITE( MMU, EXPEVT, EXC_POWER_RESET );
nkeynes@378	102
nkeynes@378	103	/* Peripheral modules */
nkeynes@378	104	CPG_reset();
nkeynes@378	105	INTC_reset();
nkeynes@378	106	MMU_reset();
nkeynes@378	107	TMU_reset();
nkeynes@378	108	SCIF_reset();
nkeynes@401	109	sh4_stats_reset();
nkeynes@378	110	}
nkeynes@378	111
nkeynes@378	112	void sh4_stop(void)
nkeynes@378	113	{
nkeynes@526	114	if( sh4_use_translator ) {
nkeynes@502	115	/* If we were running with the translator, update new_pc and in_delay_slot */
nkeynes@502	116	sh4r.new_pc = sh4r.pc+2;
nkeynes@502	117	sh4r.in_delay_slot = FALSE;
nkeynes@502	118	}
nkeynes@378	119
nkeynes@378	120	}
nkeynes@378	121
nkeynes@378	122	void sh4_save_state( FILE *f )
nkeynes@378	123	{
nkeynes@526	124	if( sh4_use_translator ) {
nkeynes@401	125	/* If we were running with the translator, update new_pc and in_delay_slot */
nkeynes@401	126	sh4r.new_pc = sh4r.pc+2;
nkeynes@401	127	sh4r.in_delay_slot = FALSE;
nkeynes@401	128	}
nkeynes@401	129
nkeynes@378	130	fwrite( &sh4r, sizeof(sh4r), 1, f );
nkeynes@378	131	MMU_save_state( f );
nkeynes@378	132	INTC_save_state( f );
nkeynes@378	133	TMU_save_state( f );
nkeynes@378	134	SCIF_save_state( f );
nkeynes@378	135	}
nkeynes@378	136
nkeynes@378	137	int sh4_load_state( FILE * f )
nkeynes@378	138	{
nkeynes@526	139	if( sh4_use_translator ) {
nkeynes@472	140	xlat_flush_cache();
nkeynes@472	141	}
nkeynes@378	142	fread( &sh4r, sizeof(sh4r), 1, f );
nkeynes@412	143	sh4r.fr_bank = &sh4r.fr[(sh4r.fpscr&FPSCR_FR)>>21][0]; // Fixup internal FR pointer
nkeynes@378	144	MMU_load_state( f );
nkeynes@378	145	INTC_load_state( f );
nkeynes@378	146	TMU_load_state( f );
nkeynes@378	147	return SCIF_load_state( f );
nkeynes@378	148	}
nkeynes@378	149
nkeynes@378	150
nkeynes@378	151	void sh4_set_breakpoint( uint32_t pc, int type )
nkeynes@378	152	{
nkeynes@378	153	sh4_breakpoints[sh4_breakpoint_count].address = pc;
nkeynes@378	154	sh4_breakpoints[sh4_breakpoint_count].type = type;
nkeynes@378	155	sh4_breakpoint_count++;
nkeynes@378	156	}
nkeynes@378	157
nkeynes@378	158	gboolean sh4_clear_breakpoint( uint32_t pc, int type )
nkeynes@378	159	{
nkeynes@378	160	int i;
nkeynes@378	161
nkeynes@378	162	for( i=0; i<sh4_breakpoint_count; i++ ) {
nkeynes@378	163	if( sh4_breakpoints[i].address == pc &&
nkeynes@378	164	sh4_breakpoints[i].type == type ) {
nkeynes@378	165	while( ++i < sh4_breakpoint_count ) {
nkeynes@378	166	sh4_breakpoints[i-1].address = sh4_breakpoints[i].address;
nkeynes@378	167	sh4_breakpoints[i-1].type = sh4_breakpoints[i].type;
nkeynes@378	168	}
nkeynes@378	169	sh4_breakpoint_count--;
nkeynes@378	170	return TRUE;
nkeynes@378	171	}
nkeynes@378	172	}
nkeynes@378	173	return FALSE;
nkeynes@378	174	}
nkeynes@378	175
nkeynes@378	176	int sh4_get_breakpoint( uint32_t pc )
nkeynes@378	177	{
nkeynes@378	178	int i;
nkeynes@378	179	for( i=0; i<sh4_breakpoint_count; i++ ) {
nkeynes@378	180	if( sh4_breakpoints[i].address == pc )
nkeynes@378	181	return sh4_breakpoints[i].type;
nkeynes@378	182	}
nkeynes@378	183	return 0;
nkeynes@378	184	}
nkeynes@378	185
nkeynes@401	186	void sh4_set_pc( int pc )
nkeynes@401	187	{
nkeynes@401	188	sh4r.pc = pc;
nkeynes@401	189	sh4r.new_pc = pc+2;
nkeynes@401	190	}
nkeynes@401	191
nkeynes@401	192
nkeynes@401	193	/***************************** Support methods *************************/
nkeynes@401	194
nkeynes@401	195	static void sh4_switch_banks( )
nkeynes@401	196	{
nkeynes@401	197	uint32_t tmp[8];
nkeynes@401	198
nkeynes@401	199	memcpy( tmp, sh4r.r, sizeof(uint32_t)*8 );
nkeynes@401	200	memcpy( sh4r.r, sh4r.r_bank, sizeof(uint32_t)*8 );
nkeynes@401	201	memcpy( sh4r.r_bank, tmp, sizeof(uint32_t)*8 );
nkeynes@401	202	}
nkeynes@401	203
nkeynes@401	204	void sh4_write_sr( uint32_t newval )
nkeynes@401	205	{
nkeynes@401	206	if( (newval ^ sh4r.sr) & SR_RB )
nkeynes@401	207	sh4_switch_banks();
nkeynes@401	208	sh4r.sr = newval;
nkeynes@401	209	sh4r.t = (newval&SR_T) ? 1 : 0;
nkeynes@401	210	sh4r.s = (newval&SR_S) ? 1 : 0;
nkeynes@401	211	sh4r.m = (newval&SR_M) ? 1 : 0;
nkeynes@401	212	sh4r.q = (newval&SR_Q) ? 1 : 0;
nkeynes@401	213	intc_mask_changed();
nkeynes@401	214	}
nkeynes@401	215
nkeynes@401	216	uint32_t sh4_read_sr( void )
nkeynes@401	217	{
nkeynes@401	218	/* synchronize sh4r.sr with the various bitflags */
nkeynes@401	219	sh4r.sr &= SR_MQSTMASK;
nkeynes@401	220	if( sh4r.t ) sh4r.sr \|= SR_T;
nkeynes@401	221	if( sh4r.s ) sh4r.sr \|= SR_S;
nkeynes@401	222	if( sh4r.m ) sh4r.sr \|= SR_M;
nkeynes@401	223	if( sh4r.q ) sh4r.sr \|= SR_Q;
nkeynes@401	224	return sh4r.sr;
nkeynes@401	225	}
nkeynes@401	226
nkeynes@401	227
nkeynes@401	228
nkeynes@401	229	#define RAISE( x, v ) do{ \
nkeynes@401	230	if( sh4r.vbr == 0 ) { \
nkeynes@401	231	ERROR( "%08X: VBR not initialized while raising exception %03X, halting", sh4r.pc, x ); \
nkeynes@401	232	dreamcast_stop(); return FALSE; \
nkeynes@401	233	} else { \
nkeynes@401	234	sh4r.spc = sh4r.pc; \
nkeynes@401	235	sh4r.ssr = sh4_read_sr(); \
nkeynes@401	236	sh4r.sgr = sh4r.r[15]; \
nkeynes@401	237	MMIO_WRITE(MMU,EXPEVT,x); \
nkeynes@401	238	sh4r.pc = sh4r.vbr + v; \
nkeynes@401	239	sh4r.new_pc = sh4r.pc + 2; \
nkeynes@401	240	sh4_write_sr( sh4r.ssr \|SR_MD\|SR_BL\|SR_RB ); \
nkeynes@401	241	if( sh4r.in_delay_slot ) { \
nkeynes@401	242	sh4r.in_delay_slot = 0; \
nkeynes@401	243	sh4r.spc -= 2; \
nkeynes@401	244	} \
nkeynes@401	245	} \
nkeynes@401	246	return TRUE; } while(0)
nkeynes@401	247
nkeynes@401	248	/**
nkeynes@401	249	* Raise a general CPU exception for the specified exception code.
nkeynes@401	250	* (NOT for TRAPA or TLB exceptions)
nkeynes@401	251	*/
nkeynes@401	252	gboolean sh4_raise_exception( int code )
nkeynes@401	253	{
nkeynes@401	254	RAISE( code, EXV_EXCEPTION );
nkeynes@401	255	}
nkeynes@401	256
nkeynes@401	257	gboolean sh4_raise_trap( int trap )
nkeynes@401	258	{
nkeynes@401	259	MMIO_WRITE( MMU, TRA, trap<<2 );
nkeynes@401	260	return sh4_raise_exception( EXC_TRAP );
nkeynes@401	261	}
nkeynes@401	262
nkeynes@401	263	gboolean sh4_raise_slot_exception( int normal_code, int slot_code ) {
nkeynes@401	264	if( sh4r.in_delay_slot ) {
nkeynes@401	265	return sh4_raise_exception(slot_code);
nkeynes@401	266	} else {
nkeynes@401	267	return sh4_raise_exception(normal_code);
nkeynes@401	268	}
nkeynes@401	269	}
nkeynes@401	270
nkeynes@401	271	gboolean sh4_raise_tlb_exception( int code )
nkeynes@401	272	{
nkeynes@401	273	RAISE( code, EXV_TLBMISS );
nkeynes@401	274	}
nkeynes@401	275
nkeynes@401	276	void sh4_accept_interrupt( void )
nkeynes@401	277	{
nkeynes@401	278	uint32_t code = intc_accept_interrupt();
nkeynes@401	279	sh4r.ssr = sh4_read_sr();
nkeynes@401	280	sh4r.spc = sh4r.pc;
nkeynes@401	281	sh4r.sgr = sh4r.r[15];
nkeynes@401	282	sh4_write_sr( sh4r.ssr\|SR_BL\|SR_MD\|SR_RB );
nkeynes@401	283	MMIO_WRITE( MMU, INTEVT, code );
nkeynes@401	284	sh4r.pc = sh4r.vbr + 0x600;
nkeynes@401	285	sh4r.new_pc = sh4r.pc + 2;
nkeynes@401	286	// WARN( "Accepting interrupt %03X, from %08X => %08X", code, sh4r.spc, sh4r.pc );
nkeynes@401	287	}
nkeynes@401	288
nkeynes@401	289	void signsat48( void )
nkeynes@401	290	{
nkeynes@401	291	if( ((int64_t)sh4r.mac) < (int64_t)0xFFFF800000000000LL )
nkeynes@401	292	sh4r.mac = 0xFFFF800000000000LL;
nkeynes@401	293	else if( ((int64_t)sh4r.mac) > (int64_t)0x00007FFFFFFFFFFFLL )
nkeynes@401	294	sh4r.mac = 0x00007FFFFFFFFFFFLL;
nkeynes@401	295	}
nkeynes@401	296
nkeynes@401	297	void sh4_fsca( uint32_t anglei, float *fr )
nkeynes@401	298	{
nkeynes@401	299	float angle = (((float)(anglei&0xFFFF))/65536.0) * 2 * M_PI;
nkeynes@401	300	*fr++ = cosf(angle);
nkeynes@401	301	*fr = sinf(angle);
nkeynes@401	302	}
nkeynes@401	303
nkeynes@401	304	void sh4_sleep(void)
nkeynes@401	305	{
nkeynes@401	306	if( MMIO_READ( CPG, STBCR ) & 0x80 ) {
nkeynes@401	307	sh4r.sh4_state = SH4_STATE_STANDBY;
nkeynes@401	308	} else {
nkeynes@401	309	sh4r.sh4_state = SH4_STATE_SLEEP;
nkeynes@401	310	}
nkeynes@401	311	}
nkeynes@401	312
nkeynes@401	313	/**
nkeynes@401	314	* Compute the matrix tranform of fv given the matrix xf.
nkeynes@401	315	* Both fv and xf are word-swapped as per the sh4r.fr banks
nkeynes@401	316	*/
nkeynes@401	317	void sh4_ftrv( float target, float xf )
nkeynes@401	318	{
nkeynes@401	319	float fv[4] = { target[1], target[0], target[3], target[2] };
nkeynes@401	320	target[1] = xf[1] * fv[0] + xf[5]*fv[1] +
nkeynes@401	321	xf[9]fv[2] + xf[13]fv[3];
nkeynes@401	322	target[0] = xf[0] * fv[0] + xf[4]*fv[1] +
nkeynes@401	323	xf[8]fv[2] + xf[12]fv[3];
nkeynes@401	324	target[3] = xf[3] * fv[0] + xf[7]*fv[1] +
nkeynes@401	325	xf[11]fv[2] + xf[15]fv[3];
nkeynes@401	326	target[2] = xf[2] * fv[0] + xf[6]*fv[1] +
nkeynes@401	327	xf[10]fv[2] + xf[14]fv[3];
nkeynes@401	328	}
nkeynes@401	329