VRac/M6502/perl.c

#include <EXTERN.h>
#include <perl.h>
#include "M6502.h"
#include "config.h"

static PerlInterpreter *my_perl;

static M6502 *R;

void pull_R(void) {
        R->A = SvIV( get_sv("M6502::A", FALSE) );
        R->P = SvIV( get_sv("M6502::P", FALSE) );
        R->X = SvIV( get_sv("M6502::X", FALSE) );
        R->Y = SvIV( get_sv("M6502::Y", FALSE) );
        R->S = SvIV( get_sv("M6502::S", FALSE) );
        R->PC.W = SvIV( get_sv("M6502::PC", FALSE) );
        R->IPeriod = SvIV( get_sv("M6502::IPeriod", FALSE) );
        R->IRequest = SvIV( get_sv("M6502::IRequest", FALSE) );
        R->IAutoReset = SvIV( get_sv("M6502::IAutoReset", FALSE) );
        R->TrapBadOps = SvIV( get_sv("M6502::TrapBadOps", FALSE) );
        R->Trap = SvIV( get_sv("M6502::Trap", FALSE) );
        R->Trace = SvIV( get_sv("M6502::Trace", FALSE) );
        printf("pull_R finished\n");
        dump_R;
}

void push_R(void) {
        debugf(("push_R"));
        dSP;
        ENTER;
        SAVETMPS;
        PUSHMARK(SP);
        XPUSHs( sv_2mortal( newSViv( R->A ) ) );
        XPUSHs( sv_2mortal( newSViv( R->P ) ) );
        XPUSHs( sv_2mortal( newSViv( R->X ) ) );
        XPUSHs( sv_2mortal( newSViv( R->Y ) ) );
        XPUSHs( sv_2mortal( newSViv( R->S ) ) );
        XPUSHs( sv_2mortal( newSViv( R->PC.W ) ) );
        XPUSHs( sv_2mortal( newSViv( R->IPeriod ) ) );
        XPUSHs( sv_2mortal( newSViv( R->ICount ) ) );
        XPUSHs( sv_2mortal( newSViv( R->IRequest ) ) );
        XPUSHs( sv_2mortal( newSViv( R->IAutoReset ) ) );
        XPUSHs( sv_2mortal( newSViv( R->TrapBadOps ) ) );
        XPUSHs( sv_2mortal( newSViv( R->Trap ) ) );
        XPUSHs( sv_2mortal( newSViv( R->Trace ) ) );
        PUTBACK;
        call_pv("M6502::push_R", G_DISCARD );
        debugf(("push_R called"));
        dump_R;
        FREETMPS;
        LEAVE;
}

byte Debug6502(M6502 *R) {
        dump_R;
        return 1; // continue emulation
}

/** Rd6502()/Wr6502/Op6502() *********************************/
/** These functions are called when access to RAM occurs.   **/
/** They allow to control memory access. Op6502 is the same **/
/** as Rd6502, but used to read *opcodes* only, when many   **/
/** checks can be skipped to make it fast. It is only       **/
/** required if there is a #define FAST_RDOP.               **/
/************************************ TO BE WRITTEN BY USER **/

byte mem(word Addr) {
        byte byte;
        int count;
        debugf(("mem(%04x)", Addr));
        dSP;
        ENTER;
        SAVETMPS;
        PUSHMARK(SP);
        XPUSHs( sv_2mortal( newSViv( Addr ) ) );
        PUTBACK;
        count = call_pv("M6502::read", G_ARRAY | G_EVAL );
        debugf(("got %d values", count));
        SPAGAIN;
        if (SvTrue(ERRSV)) {
                display_message("ERROR: %s", SvPV_nolen( ERRSV ) );
                exit(1);
        }
        if ( count != 1 ) {
                printf("expect 1 return value, got %d", count);
                exit(1);
        }
        SV *sv;
        sv = POPs;
        byte = SvIV(sv);
        FREETMPS;
        LEAVE;
        debugf(("mem(%04x) = %02x", Addr, byte));
        return byte;
}

byte Rd6502(register word Addr) {
        byte Value;
//      Value = mem(Addr);
        Value = 0x42;
        debugf(("Rd6502(%04x) = %02x", Addr, Value));
        return Value;
}

void Wr6502(register word Addr,register byte Value) {
        debugf(("Wr6502(%04x,%02x)", Addr, Value));
        dSP;
        ENTER;
        SAVETMPS;
        PUSHMARK(SP);
        XPUSHs( sv_2mortal( newSViv( Addr ) ) );
        XPUSHs( sv_2mortal( newSViv( Value ) ) );
        PUTBACK;
        call_pv("Arch::write", G_DISCARD );
        FREETMPS;
        LEAVE;
}

byte Op6502(register word Addr) {
        byte Op;
        Op = mem(Addr);
        debugf(("Op6502(%04x,%02x) PC:%04x", Addr, Op, R->PC.W));
        return Op;
}

/** Loop6502() ***********************************************/
/** 6502 emulation calls this function periodically to      **/
/** check if the system hardware requires any interrupts.   **/
/** This function must return one of following values:      **/
/** INT_NONE, INT_IRQ, INT_NMI, or INT_QUIT to exit the     **/
/** emulation loop.                                         **/
/************************************ TO BE WRITTEN BY USER **/

int hw_int = INT_NONE;

byte Loop6502(register M6502 *R) {
        debugf(("Loop6502"));
        dump_R;
        return hw_int;
}

/** Patch6502() **********************************************/
/** Emulation calls this function when it encounters an     **/
/** unknown opcode. This can be used to patch the code to   **/
/** emulate BIOS calls, such as disk and tape access. The   **/
/** function should return 1 if the exception was handled,  **/
/** or 0 if the opcode was truly illegal.                   **/
/************************************ TO BE WRITTEN BY USER **/
byte Patch6502(register byte Op,register M6502 *R) {
        debugf(("Patch6502(%02x)", Op));
        dump_R;
        hw_int = INT_QUIT;
        return 0;
}

void run_forever(void) {
        printf("entered run_forever\n");

        R = malloc(sizeof(M6502));
        if (!R) {
                printf("can't alloc %d bytes for M6502", sizeof(M6502));
                exit(1);
        }

        printf("reset CPU\n");
        Reset6502(R);

        printf("call Arch::init\n");
        dSP;
        PUSHMARK(SP);
        call_pv("Arch::init", G_DISCARD | G_NOARGS );
        FREETMPS;
        LEAVE;

        int cycles = 1;
        while ( cycles ) {
                dSP;
                PUSHMARK(SP);
                call_pv("Arch::cli", G_DISCARD | G_NOARGS );
                pull_R;
                FREETMPS;
                LEAVE;
                cycles = SvIV( get_sv("M6502::run_for", FALSE) );
                if ( cycles > 0 ) {
                        printf("run CPU for %d cycles\n", cycles);
                        dump_R;
                        //Run6502(R);
                        Exec6502(R, cycles);
                        dump_R;
                        push_R;
                        printf("end of %d cycles CPU run\n", cycles);
                } else {
                        printf("no cpu cycles set for run\n");
                        cycles = 1; // never exit, prevents segfault
                }
        }
        free(R);
}

/**
 * main code
 *
 **/

int main(int argc, char **argv) {
        char *command_line[] = {"", "-e", EMU_START };
        my_perl = perl_alloc();
        perl_construct(my_perl);
        if (perl_parse(my_perl, xs_init, 3, command_line, (char **)NULL)) {
                printf("Failed to parse initial: %s\n", EMU_START );
                return 0;
        }
        perl_run(my_perl);
        if (SvTRUE(ERRSV)) {
                printf("Failed to execute\n");
                return 0;
        } else {
                run_forever();
        }
        perl_destruct(my_perl);
        perl_free(my_perl);
        return 0;
}
1	#include <EXTERN.h>
2	#include <perl.h>
3	#include "M6502.h"
4	#include "config.h"
5
6	static PerlInterpreter *my_perl;
7
8	static M6502 *R;
9
10	void pull_R(void) {
11	R->A = SvIV( get_sv("M6502::A", FALSE) );
12	R->P = SvIV( get_sv("M6502::P", FALSE) );
13	R->X = SvIV( get_sv("M6502::X", FALSE) );
14	R->Y = SvIV( get_sv("M6502::Y", FALSE) );
15	R->S = SvIV( get_sv("M6502::S", FALSE) );
16	R->PC.W = SvIV( get_sv("M6502::PC", FALSE) );
17	R->IPeriod = SvIV( get_sv("M6502::IPeriod", FALSE) );
18	R->IRequest = SvIV( get_sv("M6502::IRequest", FALSE) );
19	R->IAutoReset = SvIV( get_sv("M6502::IAutoReset", FALSE) );
20	R->TrapBadOps = SvIV( get_sv("M6502::TrapBadOps", FALSE) );
21	R->Trap = SvIV( get_sv("M6502::Trap", FALSE) );
22	R->Trace = SvIV( get_sv("M6502::Trace", FALSE) );
23	printf("pull_R finished\n");
24	dump_R;
25	}
26
27	void push_R(void) {
28	debugf(("push_R"));
29	dSP;
30	ENTER;
31	SAVETMPS;
32	PUSHMARK(SP);
33	XPUSHs( sv_2mortal( newSViv( R->A ) ) );
34	XPUSHs( sv_2mortal( newSViv( R->P ) ) );
35	XPUSHs( sv_2mortal( newSViv( R->X ) ) );
36	XPUSHs( sv_2mortal( newSViv( R->Y ) ) );
37	XPUSHs( sv_2mortal( newSViv( R->S ) ) );
38	XPUSHs( sv_2mortal( newSViv( R->PC.W ) ) );
39	XPUSHs( sv_2mortal( newSViv( R->IPeriod ) ) );
40	XPUSHs( sv_2mortal( newSViv( R->ICount ) ) );
41	XPUSHs( sv_2mortal( newSViv( R->IRequest ) ) );
42	XPUSHs( sv_2mortal( newSViv( R->IAutoReset ) ) );
43	XPUSHs( sv_2mortal( newSViv( R->TrapBadOps ) ) );
44	XPUSHs( sv_2mortal( newSViv( R->Trap ) ) );
45	XPUSHs( sv_2mortal( newSViv( R->Trace ) ) );
46	PUTBACK;
47	call_pv("M6502::push_R", G_DISCARD );
48	debugf(("push_R called"));
49	dump_R;
50	FREETMPS;
51	LEAVE;
52	}
53
54	byte Debug6502(M6502 *R) {
55	dump_R;
56	return 1; // continue emulation
57	}
58
59	/ Rd6502()/Wr6502/Op6502() *******************************/
60	/ These functions are called when access to RAM occurs. /
61	/ They allow to control memory access. Op6502 is the same /
62	/** as Rd6502, but used to read opcodes only, when many **/
63	/ checks can be skipped to make it fast. It is only /
64	/ required if there is a #define FAST_RDOP. /
65	/********************************** TO BE WRITTEN BY USER /
66
67	byte mem(word Addr) {
68	byte byte;
69	int count;
70	debugf(("mem(%04x)", Addr));
71	dSP;
72	ENTER;
73	SAVETMPS;
74	PUSHMARK(SP);
75	XPUSHs( sv_2mortal( newSViv( Addr ) ) );
76	PUTBACK;
77	count = call_pv("M6502::read", G_ARRAY \| G_EVAL );
78	debugf(("got %d values", count));
79	SPAGAIN;
80	if (SvTrue(ERRSV)) {
81	display_message("ERROR: %s", SvPV_nolen( ERRSV ) );
82	exit(1);
83	}
84	if ( count != 1 ) {
85	printf("expect 1 return value, got %d", count);
86	exit(1);
87	}
88	SV *sv;
89	sv = POPs;
90	byte = SvIV(sv);
91	FREETMPS;
92	LEAVE;
93	debugf(("mem(%04x) = %02x", Addr, byte));
94	return byte;
95	}
96
97	byte Rd6502(register word Addr) {
98	byte Value;
99	// Value = mem(Addr);
100	Value = 0x42;
101	debugf(("Rd6502(%04x) = %02x", Addr, Value));
102	return Value;
103	}
104
105	void Wr6502(register word Addr,register byte Value) {
106	debugf(("Wr6502(%04x,%02x)", Addr, Value));
107	dSP;
108	ENTER;
109	SAVETMPS;
110	PUSHMARK(SP);
111	XPUSHs( sv_2mortal( newSViv( Addr ) ) );
112	XPUSHs( sv_2mortal( newSViv( Value ) ) );
113	PUTBACK;
114	call_pv("Arch::write", G_DISCARD );
115	FREETMPS;
116	LEAVE;
117	}
118
119	byte Op6502(register word Addr) {
120	byte Op;
121	Op = mem(Addr);
122	debugf(("Op6502(%04x,%02x) PC:%04x", Addr, Op, R->PC.W));
123	return Op;
124	}
125
126	/ Loop6502() *********************************************/
127	/ 6502 emulation calls this function periodically to /
128	/ check if the system hardware requires any interrupts. /
129	/ This function must return one of following values: /
130	/ INT_NONE, INT_IRQ, INT_NMI, or INT_QUIT to exit the /
131	/ emulation loop. /
132	/********************************** TO BE WRITTEN BY USER /
133
134	int hw_int = INT_NONE;
135
136	byte Loop6502(register M6502 *R) {
137	debugf(("Loop6502"));
138	dump_R;
139	return hw_int;
140	}
141
142	/ Patch6502() ********************************************/
143	/ Emulation calls this function when it encounters an /
144	/ unknown opcode. This can be used to patch the code to /
145	/ emulate BIOS calls, such as disk and tape access. The /
146	/ function should return 1 if the exception was handled, /
147	/ or 0 if the opcode was truly illegal. /
148	/********************************** TO BE WRITTEN BY USER /
149	byte Patch6502(register byte Op,register M6502 *R) {
150	debugf(("Patch6502(%02x)", Op));
151	dump_R;
152	hw_int = INT_QUIT;
153	return 0;
154	}
155
156	void run_forever(void) {
157	printf("entered run_forever\n");
158
159	R = malloc(sizeof(M6502));
160	if (!R) {
161	printf("can't alloc %d bytes for M6502", sizeof(M6502));
162	exit(1);
163	}
164
165	printf("reset CPU\n");
166	Reset6502(R);
167
168	printf("call Arch::init\n");
169	dSP;
170	PUSHMARK(SP);
171	call_pv("Arch::init", G_DISCARD \| G_NOARGS );
172	FREETMPS;
173	LEAVE;
174
175	int cycles = 1;
176	while ( cycles ) {
177	dSP;
178	PUSHMARK(SP);
179	call_pv("Arch::cli", G_DISCARD \| G_NOARGS );
180	pull_R;
181	FREETMPS;
182	LEAVE;
183	cycles = SvIV( get_sv("M6502::run_for", FALSE) );
184	if ( cycles > 0 ) {
185	printf("run CPU for %d cycles\n", cycles);
186	dump_R;
187	//Run6502(R);
188	Exec6502(R, cycles);
189	dump_R;
190	push_R;
191	printf("end of %d cycles CPU run\n", cycles);
192	} else {
193	printf("no cpu cycles set for run\n");
194	cycles = 1; // never exit, prevents segfault
195	}
196	}
197	free(R);
198	}
199
200	/**
201	* main code
202	*
203	**/
204
205	int main(int argc, char **argv) {
206	char *command_line[] = {"", "-e", EMU_START };
207	my_perl = perl_alloc();
208	perl_construct(my_perl);
209	if (perl_parse(my_perl, xs_init, 3, command_line, (char **)NULL)) {
210	printf("Failed to parse initial: %s\n", EMU_START );
211	return 0;
212	}
213	perl_run(my_perl);
214	if (SvTRUE(ERRSV)) {
215	printf("Failed to execute\n");
216	return 0;
217	} else {
218	run_forever();
219	}
220	perl_destruct(my_perl);
221	perl_free(my_perl);
222	return 0;
223	}