| nkeynes@10 | 1 | /**
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| nkeynes@586 | 2 | * $Id$
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| nkeynes@10 | 3 | *
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| nkeynes@54 | 4 | * This file defines the internal functions exported/used by the SH4 core,
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| nkeynes@54 | 5 | * except for disassembly functions defined in sh4dasm.h
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| nkeynes@10 | 6 | *
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| nkeynes@10 | 7 | * Copyright (c) 2005 Nathan Keynes.
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| nkeynes@10 | 8 | *
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| nkeynes@10 | 9 | * This program is free software; you can redistribute it and/or modify
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| nkeynes@10 | 10 | * it under the terms of the GNU General Public License as published by
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| nkeynes@10 | 11 | * the Free Software Foundation; either version 2 of the License, or
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| nkeynes@10 | 12 | * (at your option) any later version.
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| nkeynes@10 | 13 | *
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| nkeynes@10 | 14 | * This program is distributed in the hope that it will be useful,
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| nkeynes@10 | 15 | * but WITHOUT ANY WARRANTY; without even the implied warranty of
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| nkeynes@10 | 16 | * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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| nkeynes@10 | 17 | * GNU General Public License for more details.
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| nkeynes@1 | 18 | */
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| nkeynes@30 | 19 |
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| nkeynes@1 | 20 | #ifndef sh4core_H
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| nkeynes@1 | 21 | #define sh4core_H 1
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| nkeynes@1 | 22 |
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| nkeynes@27 | 23 | #include <glib/gtypes.h>
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| nkeynes@1 | 24 | #include <stdint.h>
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| nkeynes@23 | 25 | #include <stdio.h>
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| nkeynes@378 | 26 | #include "mem.h"
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| nkeynes@586 | 27 | #include "sh4/sh4.h"
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| nkeynes@1 | 28 |
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| nkeynes@1 | 29 | #ifdef __cplusplus
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| nkeynes@1 | 30 | extern "C" {
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| nkeynes@1 | 31 | #endif
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| nkeynes@1 | 32 |
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| nkeynes@586 | 33 | /* Breakpoint data structure */
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| nkeynes@586 | 34 | extern struct breakpoint_struct sh4_breakpoints[MAX_BREAKPOINTS];
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| nkeynes@586 | 35 | extern int sh4_breakpoint_count;
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| nkeynes@586 | 36 | extern sh4ptr_t sh4_main_ram;
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| nkeynes@591 | 37 | extern gboolean sh4_starting;
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| nkeynes@27 | 38 |
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| nkeynes@27 | 39 | /**
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| nkeynes@586 | 40 | * Cached direct pointer to the current instruction page. If AT is on, this
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| nkeynes@586 | 41 | * is derived from the ITLB, otherwise this will be the entire memory region.
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| nkeynes@586 | 42 | * This is actually a fairly useful optimization, as we can make a lot of
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| nkeynes@586 | 43 | * assumptions about the "current page" that we can't make in general for
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| nkeynes@586 | 44 | * arbitrary virtual addresses.
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| nkeynes@27 | 45 | */
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| nkeynes@586 | 46 | struct sh4_icache_struct {
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| nkeynes@586 | 47 | sh4ptr_t page; // Page pointer (NULL if no page)
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| nkeynes@586 | 48 | sh4vma_t page_vma; // virtual address of the page.
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| nkeynes@586 | 49 | sh4addr_t page_ppa; // physical address of the page
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| nkeynes@586 | 50 | uint32_t mask; // page mask
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| nkeynes@586 | 51 | };
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| nkeynes@586 | 52 | extern struct sh4_icache_struct sh4_icache;
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| nkeynes@586 | 53 |
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| nkeynes@27 | 54 | /**
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| nkeynes@586 | 55 | * Test if a given address is contained in the current icache entry
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| nkeynes@27 | 56 | */
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| nkeynes@586 | 57 | #define IS_IN_ICACHE(addr) (sh4_icache.page_vma == ((addr) & sh4_icache.mask))
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| nkeynes@27 | 58 | /**
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| nkeynes@586 | 59 | * Return a pointer for the given vma, under the assumption that it is
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| nkeynes@586 | 60 | * actually contained in the current icache entry.
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| nkeynes@27 | 61 | */
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| nkeynes@586 | 62 | #define GET_ICACHE_PTR(addr) (sh4_icache.page + ((addr)-sh4_icache.page_vma))
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| nkeynes@27 | 63 | /**
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| nkeynes@586 | 64 | * Return the physical (external) address for the given vma, assuming that it is
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| nkeynes@586 | 65 | * actually contained in the current icache entry.
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| nkeynes@27 | 66 | */
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| nkeynes@586 | 67 | #define GET_ICACHE_PHYS(addr) (sh4_icache.page_ppa + ((addr)-sh4_icache.page_vma))
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| nkeynes@27 | 68 |
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| nkeynes@589 | 69 | /**
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| nkeynes@589 | 70 | * Return the virtual (vma) address for the first address past the end of the
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| nkeynes@589 | 71 | * cache entry. Assumes that there is in fact a current icache entry.
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| nkeynes@589 | 72 | */
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| nkeynes@589 | 73 | #define GET_ICACHE_END() (sh4_icache.page_vma + (~sh4_icache.mask) + 1)
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| nkeynes@589 | 74 |
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| nkeynes@586 | 75 | /* SH4 module functions */
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| nkeynes@1 | 76 | void sh4_init( void );
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| nkeynes@1 | 77 | void sh4_reset( void );
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| nkeynes@1 | 78 | void sh4_run( void );
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| nkeynes@1 | 79 | void sh4_stop( void );
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| nkeynes@617 | 80 | uint32_t sh4_run_slice( uint32_t nanos ); // Run single timeslice using emulator
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| nkeynes@617 | 81 | uint32_t sh4_xlat_run_slice( uint32_t nanos ); // Run single timeslice using translator
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| nkeynes@617 | 82 | uint32_t sh4_sleep_run_slice( uint32_t nanos ); // Run single timeslice while the CPU is asleep
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| nkeynes@586 | 83 |
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| nkeynes@586 | 84 | /* SH4 peripheral module functions */
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| nkeynes@586 | 85 | void CPG_reset( void );
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| nkeynes@586 | 86 | void DMAC_reset( void );
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| nkeynes@586 | 87 | void DMAC_run_slice( uint32_t );
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| nkeynes@586 | 88 | void DMAC_save_state( FILE * );
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| nkeynes@586 | 89 | int DMAC_load_state( FILE * );
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| nkeynes@586 | 90 | void INTC_reset( void );
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| nkeynes@586 | 91 | void INTC_save_state( FILE *f );
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| nkeynes@586 | 92 | int INTC_load_state( FILE *f );
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| nkeynes@586 | 93 | void MMU_init( void );
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| nkeynes@586 | 94 | void MMU_reset( void );
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| nkeynes@586 | 95 | void MMU_save_state( FILE *f );
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| nkeynes@586 | 96 | int MMU_load_state( FILE *f );
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| nkeynes@586 | 97 | void MMU_ldtlb();
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| nkeynes@586 | 98 | void SCIF_reset( void );
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| nkeynes@586 | 99 | void SCIF_run_slice( uint32_t );
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| nkeynes@586 | 100 | void SCIF_save_state( FILE *f );
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| nkeynes@586 | 101 | int SCIF_load_state( FILE *f );
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| nkeynes@586 | 102 | void SCIF_update_line_speed(void);
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| nkeynes@669 | 103 | void TMU_init( void );
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| nkeynes@586 | 104 | void TMU_reset( void );
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| nkeynes@586 | 105 | void TMU_run_slice( uint32_t );
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| nkeynes@586 | 106 | void TMU_save_state( FILE * );
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| nkeynes@586 | 107 | int TMU_load_state( FILE * );
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| nkeynes@586 | 108 | void TMU_update_clocks( void );
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| nkeynes@586 | 109 |
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| nkeynes@586 | 110 | /* SH4 instruction support methods */
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| nkeynes@401 | 111 | void sh4_sleep( void );
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| nkeynes@401 | 112 | void sh4_fsca( uint32_t angle, float *fr );
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| nkeynes@669 | 113 | void sh4_ftrv( float *fv );
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| nkeynes@586 | 114 | uint32_t sh4_read_sr(void);
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| nkeynes@586 | 115 | void sh4_write_sr(uint32_t val);
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| nkeynes@669 | 116 | void sh4_write_fpscr(uint32_t val);
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| nkeynes@669 | 117 | void sh4_switch_fr_banks(void);
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| nkeynes@401 | 118 | void signsat48(void);
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| nkeynes@597 | 119 | gboolean sh4_has_page( sh4vma_t vma );
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| nkeynes@378 | 120 |
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| nkeynes@586 | 121 | /* SH4 Memory */
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| nkeynes@603 | 122 | #define MMU_VMA_ERROR 0x80000000
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| nkeynes@586 | 123 | /**
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| nkeynes@586 | 124 | * Update the sh4_icache structure to contain the specified vma. If the vma
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| nkeynes@586 | 125 | * cannot be resolved, an MMU exception is raised and the function returns
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| nkeynes@586 | 126 | * FALSE. Otherwise, returns TRUE and updates sh4_icache accordingly.
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| nkeynes@586 | 127 | * Note: If the vma resolves to a non-memory area, sh4_icache will be
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| nkeynes@586 | 128 | * invalidated, but the function will still return TRUE.
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| nkeynes@586 | 129 | * @return FALSE if an MMU exception was raised, otherwise TRUE.
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| nkeynes@586 | 130 | */
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| nkeynes@586 | 131 | gboolean mmu_update_icache( sh4vma_t addr );
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| nkeynes@23 | 132 |
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| nkeynes@586 | 133 | /**
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| nkeynes@586 | 134 | * Resolve a virtual address through the TLB for a read operation, returning
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| nkeynes@586 | 135 | * the resultant P4 or external address. If the resolution fails, the
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| nkeynes@586 | 136 | * appropriate MMU exception is raised and the value MMU_VMA_ERROR is returned.
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| nkeynes@586 | 137 | * @return An external address (0x00000000-0x1FFFFFFF), a P4 address
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| nkeynes@586 | 138 | * (0xE0000000 - 0xFFFFFFFF), or MMU_VMA_ERROR.
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| nkeynes@586 | 139 | */
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| nkeynes@586 | 140 | sh4addr_t mmu_vma_to_phys_read( sh4vma_t addr );
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| nkeynes@586 | 141 | sh4addr_t mmu_vma_to_phys_write( sh4vma_t addr );
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| nkeynes@597 | 142 | sh4addr_t mmu_vma_to_phys_disasm( sh4vma_t addr );
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| nkeynes@1 | 143 |
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| nkeynes@527 | 144 | int64_t sh4_read_quad( sh4addr_t addr );
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| nkeynes@527 | 145 | int32_t sh4_read_long( sh4addr_t addr );
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| nkeynes@527 | 146 | int32_t sh4_read_word( sh4addr_t addr );
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| nkeynes@527 | 147 | int32_t sh4_read_byte( sh4addr_t addr );
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| nkeynes@527 | 148 | void sh4_write_quad( sh4addr_t addr, uint64_t val );
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| nkeynes@527 | 149 | void sh4_write_long( sh4addr_t addr, uint32_t val );
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| nkeynes@527 | 150 | void sh4_write_word( sh4addr_t addr, uint32_t val );
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| nkeynes@527 | 151 | void sh4_write_byte( sh4addr_t addr, uint32_t val );
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| nkeynes@527 | 152 | int32_t sh4_read_phys_word( sh4addr_t addr );
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| nkeynes@586 | 153 | gboolean sh4_flush_store_queue( sh4addr_t addr );
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| nkeynes@10 | 154 |
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| nkeynes@586 | 155 | /* SH4 Exceptions */
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| nkeynes@586 | 156 | #define EXC_POWER_RESET 0x000 /* reset vector */
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| nkeynes@586 | 157 | #define EXC_MANUAL_RESET 0x020 /* reset vector */
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| nkeynes@586 | 158 | #define EXC_TLB_MISS_READ 0x040 /* TLB vector */
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| nkeynes@586 | 159 | #define EXC_TLB_MISS_WRITE 0x060 /* TLB vector */
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| nkeynes@586 | 160 | #define EXC_INIT_PAGE_WRITE 0x080
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| nkeynes@586 | 161 | #define EXC_TLB_PROT_READ 0x0A0
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| nkeynes@586 | 162 | #define EXC_TLB_PROT_WRITE 0x0C0
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| nkeynes@586 | 163 | #define EXC_DATA_ADDR_READ 0x0E0
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| nkeynes@586 | 164 | #define EXC_DATA_ADDR_WRITE 0x100
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| nkeynes@586 | 165 | #define EXC_TLB_MULTI_HIT 0x140
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| nkeynes@586 | 166 | #define EXC_SLOT_ILLEGAL 0x1A0
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| nkeynes@586 | 167 | #define EXC_ILLEGAL 0x180
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| nkeynes@586 | 168 | #define EXC_TRAP 0x160
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| nkeynes@586 | 169 | #define EXC_FPU_DISABLED 0x800
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| nkeynes@586 | 170 | #define EXC_SLOT_FPU_DISABLED 0x820
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| nkeynes@374 | 171 |
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| nkeynes@586 | 172 | #define EXV_EXCEPTION 0x100 /* General exception vector */
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| nkeynes@586 | 173 | #define EXV_TLBMISS 0x400 /* TLB-miss exception vector */
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| nkeynes@586 | 174 | #define EXV_INTERRUPT 0x600 /* External interrupt vector */
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| nkeynes@586 | 175 |
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| nkeynes@586 | 176 | gboolean sh4_raise_exception( int );
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| nkeynes@586 | 177 | gboolean sh4_raise_reset( int );
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| nkeynes@586 | 178 | gboolean sh4_raise_trap( int );
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| nkeynes@586 | 179 | gboolean sh4_raise_slot_exception( int, int );
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| nkeynes@586 | 180 | gboolean sh4_raise_tlb_exception( int );
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| nkeynes@586 | 181 | void sh4_accept_interrupt( void );
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| nkeynes@1 | 182 |
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| nkeynes@1 | 183 | #define SIGNEXT4(n) ((((int32_t)(n))<<28)>>28)
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| nkeynes@1 | 184 | #define SIGNEXT8(n) ((int32_t)((int8_t)(n)))
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| nkeynes@1 | 185 | #define SIGNEXT12(n) ((((int32_t)(n))<<20)>>20)
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| nkeynes@1 | 186 | #define SIGNEXT16(n) ((int32_t)((int16_t)(n)))
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| nkeynes@1 | 187 | #define SIGNEXT32(n) ((int64_t)((int32_t)(n)))
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| nkeynes@1 | 188 | #define SIGNEXT48(n) ((((int64_t)(n))<<16)>>16)
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| nkeynes@586 | 189 | #define ZEROEXT32(n) ((int64_t)((uint64_t)((uint32_t)(n))))
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| nkeynes@1 | 190 |
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| nkeynes@1 | 191 | /* Status Register (SR) bits */
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| nkeynes@1 | 192 | #define SR_MD 0x40000000 /* Processor mode ( User=0, Privileged=1 ) */
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| nkeynes@1 | 193 | #define SR_RB 0x20000000 /* Register bank (priviledged mode only) */
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| nkeynes@1 | 194 | #define SR_BL 0x10000000 /* Exception/interupt block (1 = masked) */
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| nkeynes@1 | 195 | #define SR_FD 0x00008000 /* FPU disable */
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| nkeynes@1 | 196 | #define SR_M 0x00000200
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| nkeynes@1 | 197 | #define SR_Q 0x00000100
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| nkeynes@1 | 198 | #define SR_IMASK 0x000000F0 /* Interrupt mask level */
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| nkeynes@1 | 199 | #define SR_S 0x00000002 /* Saturation operation for MAC instructions */
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| nkeynes@1 | 200 | #define SR_T 0x00000001 /* True/false or carry/borrow */
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| nkeynes@1 | 201 | #define SR_MASK 0x700083F3
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| nkeynes@1 | 202 | #define SR_MQSTMASK 0xFFFFFCFC /* Mask to clear the flags we're keeping separately */
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| nkeynes@586 | 203 | #define SR_MDRB 0x60000000 /* MD+RB mask for convenience */
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| nkeynes@1 | 204 |
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| nkeynes@1 | 205 | #define IS_SH4_PRIVMODE() (sh4r.sr&SR_MD)
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| nkeynes@1 | 206 | #define SH4_INTMASK() ((sh4r.sr&SR_IMASK)>>4)
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| nkeynes@265 | 207 | #define SH4_EVENT_PENDING() (sh4r.event_pending <= sh4r.slice_cycle && !sh4r.in_delay_slot)
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| nkeynes@1 | 208 |
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| nkeynes@1 | 209 | #define FPSCR_FR 0x00200000 /* FPU register bank */
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| nkeynes@1 | 210 | #define FPSCR_SZ 0x00100000 /* FPU transfer size (0=32 bits, 1=64 bits) */
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| nkeynes@1 | 211 | #define FPSCR_PR 0x00080000 /* Precision (0=32 bites, 1=64 bits) */
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| nkeynes@1 | 212 | #define FPSCR_DN 0x00040000 /* Denormalization mode (1 = treat as 0) */
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| nkeynes@1 | 213 | #define FPSCR_CAUSE 0x0003F000
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| nkeynes@1 | 214 | #define FPSCR_ENABLE 0x00000F80
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| nkeynes@1 | 215 | #define FPSCR_FLAG 0x0000007C
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| nkeynes@1 | 216 | #define FPSCR_RM 0x00000003 /* Rounding mode (0=nearest, 1=to zero) */
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| nkeynes@1 | 217 |
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| nkeynes@1 | 218 | #define IS_FPU_DOUBLEPREC() (sh4r.fpscr&FPSCR_PR)
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| nkeynes@1 | 219 | #define IS_FPU_DOUBLESIZE() (sh4r.fpscr&FPSCR_SZ)
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| nkeynes@1 | 220 | #define IS_FPU_ENABLED() ((sh4r.sr&SR_FD)==0)
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| nkeynes@1 | 221 |
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| nkeynes@669 | 222 | #define FR(x) sh4r.fr[0][(x)^1]
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| nkeynes@669 | 223 | #define DRF(x) *((double *)&sh4r.fr[0][(x)<<1])
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| nkeynes@669 | 224 | #define XF(x) sh4r.fr[1][(x)^1]
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| nkeynes@669 | 225 | #define XDR(x) *((double *)&sh4r.fr[1][(x)<<1])
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| nkeynes@669 | 226 | #define DRb(x,b) *((double *)&sh4r.fr[b][(x)<<1])
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| nkeynes@669 | 227 | #define DR(x) *((double *)&sh4r.fr[x&1][x&0x0E])
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| nkeynes@669 | 228 | #define FPULf (sh4r.fpul.f)
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| nkeynes@669 | 229 | #define FPULi (sh4r.fpul.i)
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| nkeynes@359 | 230 |
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| nkeynes@2 | 231 | #define SH4_WRITE_STORE_QUEUE(addr,val) sh4r.store_queue[(addr>>2)&0xF] = val;
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| nkeynes@1 | 232 |
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| nkeynes@1 | 233 | #ifdef __cplusplus
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| nkeynes@1 | 234 | }
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| nkeynes@1 | 235 | #endif
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| nkeynes@1 | 236 | #endif
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| nkeynes@359 | 237 |
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lxdream 0.9.1