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collapseos/emul/z80/sms.c
Virgil Dupras 7d568bd782 sms: simplify and solidify ports-related drivers
Add _TRA!, _THA!, _TRB!, _THB! routines to easily handle those pins'
value without stepping on other pins like the drivers previously
did. For SDC driver, it's going to be important soon because it turns
out that I can't get away with "always on" CS, so I'll need a scheme
where it's important that TH/TR pins have stable values.
2020-11-02 18:53:57 -05:00

381 lines
9.5 KiB
C

#include <stdlib.h>
#include <stdio.h>
#include <stdbool.h>
#include <unistd.h>
#include <xcb/xcb.h>
#define XK_MISCELLANY
#include <X11/keysymdef.h>
#include "emul.h"
#include "sms_vdp.h"
#include "sms_ports.h"
#include "sms_pad.h"
#include "sms_spi.h"
#include "ps2_kbd.h"
#include "sdc.h"
#define RAMSTART 0xc000
#define VDP_CMD_PORT 0xbf
#define VDP_DATA_PORT 0xbe
#define PORTS_CTL_PORT 0x3f
#define PORTS_IO1_PORT 0xdc
#define PORTS_IO2_PORT 0xdd
#define SDC_CTL 0x05
#define SDC_SPI 0x04
#define MAX_ROMSIZE 0x8000
static xcb_connection_t *conn;
static xcb_screen_t *screen;
/* graphics contexts */
static xcb_gcontext_t fg;
/* win */
static xcb_drawable_t win;
// pixels to draw. We draw them in one shot.
static xcb_rectangle_t rectangles[VDP_SCREENW*VDP_SCREENH];
static Machine *m;
static VDP vdp;
static bool vdp_changed;
static Ports ports;
static Pad pad;
static Kbd kbd;
static bool use_kbd = false;
static SDC sdc;
static SPI spi;
static uint8_t iord_vdp_cmd()
{
return vdp_cmd_rd(&vdp);
}
static uint8_t iord_vdp_data()
{
return vdp_data_rd(&vdp);
}
static uint8_t iord_ports_io1()
{
return ports_A_rd(&ports);
}
static uint8_t iord_ports_io2()
{
return ports_B_rd(&ports);
}
static uint8_t iord_pad()
{
return pad_rd(&pad);
}
static uint8_t iord_kbd()
{
return kbd_rd(&kbd);
}
static uint8_t iord_ports_ctl()
{
return ports_ctl_rd(&ports);
}
static void iowr_vdp_cmd(uint8_t val)
{
vdp_cmd_wr(&vdp, val);
}
static void iowr_vdp_data(uint8_t val)
{
vdp_changed = true;
vdp_data_wr(&vdp, val);
}
static void iowr_ports_ctl(uint8_t val)
{
ports_ctl_wr(&ports, val);
}
static byte iord_spi()
{
return spi_rd(&spi);
}
static byte spix_sdc(byte val) { return sdc_spix(&sdc, val); }
void create_window()
{
uint32_t mask;
uint32_t values[2];
/* Create the window */
win = xcb_generate_id(conn);
mask = XCB_CW_BACK_PIXEL | XCB_CW_EVENT_MASK;
values[0] = screen->white_pixel;
values[1] = XCB_EVENT_MASK_EXPOSURE | XCB_EVENT_MASK_KEY_PRESS |
XCB_EVENT_MASK_KEY_RELEASE;
xcb_create_window(
conn,
screen->root_depth,
win,
screen->root,
0, 0,
500, 500,
10,
XCB_WINDOW_CLASS_INPUT_OUTPUT,
screen->root_visual,
mask, values);
fg = xcb_generate_id(conn);
mask = XCB_GC_FOREGROUND | XCB_GC_GRAPHICS_EXPOSURES;
values[0] = screen->black_pixel;
values[1] = 0;
xcb_create_gc(conn, fg, screen->root, mask, values);
/* Map the window on the screen */
xcb_map_window(conn, win);
}
// To make things simple with X11, we only support monochrome display, which is
// inverted: As soon as the color of the pixel is non-black, we show a black
// pixel. If the pixel is white, we show black.
void draw_pixels()
{
xcb_get_geometry_reply_t *geom;
geom = xcb_get_geometry_reply(conn, xcb_get_geometry(conn, win), NULL);
xcb_clear_area(
conn, 0, win, 0, 0, geom->width, geom->height);
// Figure out inner size to maximize our screen's aspect ratio
int psize = geom->height / VDP_SCREENH;
if (geom->width / VDP_SCREENW < psize) {
// width is the constraint
psize = geom->width / VDP_SCREENW;
}
int innerw = psize * VDP_SCREENW;
int innerh = psize * VDP_SCREENH;
int innerx = (geom->width - innerw) / 2;
int innery = (geom->height - innerh) / 2;
free(geom);
int drawcnt = 0;
for (int i=0; i<VDP_SCREENW; i++) {
for (int j=0; j<VDP_SCREENH; j++) {
if (vdp_pixel(&vdp, i, j)) {
int x = innerx + (i*psize);
int y = innery + (j*psize);
rectangles[drawcnt].x = x;
rectangles[drawcnt].y = y;
rectangles[drawcnt].height = psize;
rectangles[drawcnt].width = psize;
drawcnt++;
}
}
}
if (drawcnt) {
xcb_poly_fill_rectangle(
conn, win, fg, drawcnt, rectangles);
}
vdp_changed = false;
xcb_flush(conn);
}
// Returns true to exist event loop
static bool _handle_keypress(xcb_generic_event_t *e)
{
xcb_key_press_event_t *ev = (xcb_key_press_event_t *)e;
if (ev->detail == 0x09) { // ESC
return true;
}
bool ispressed = e->response_type == XCB_KEY_PRESS;
// change keycode into symbol
xcb_get_keyboard_mapping_reply_t* km = xcb_get_keyboard_mapping_reply(
conn, xcb_get_keyboard_mapping(conn, ev->detail, 1), NULL);
if (km->length) {
xcb_keysym_t* keysyms = (xcb_keysym_t*)(km + 1);
if (use_kbd) {
if ((keysyms[0] == XK_Shift_L) || (keysyms[0] == XK_Shift_R)) {
kbd_pressshift(&kbd, ispressed);
} else if (ispressed) {
fprintf(stderr, "pressing %x\n", keysyms[0]);
kbd_presskey(&kbd, keysyms[0]);
}
} else { // pad
switch (keysyms[0]) {
case 'w':
pad_setbtn(&pad, PAD_BTN_UP, ispressed);
break;
case 'a':
pad_setbtn(&pad, PAD_BTN_LEFT, ispressed);
break;
case 's':
pad_setbtn(&pad, PAD_BTN_DOWN, ispressed);
break;
case 'd':
pad_setbtn(&pad, PAD_BTN_RIGHT, ispressed);
break;
case 'h':
pad_setbtn(&pad, PAD_BTN_A, ispressed);
break;
case 'j':
pad_setbtn(&pad, PAD_BTN_B, ispressed);
break;
case 'k':
pad_setbtn(&pad, PAD_BTN_C, ispressed);
break;
case 'l':
pad_setbtn(&pad, PAD_BTN_START, ispressed);
break;
}
}
}
free(km);
return false;
}
void event_loop()
{
while (1) {
for (int i=0; i<100; i++) {
if (!emul_step()) {
fprintf(stderr, "CPU halted, quitting\n");
usleep(1000 * 1000);
break;
}
spi_pulse(&spi);
}
if (vdp_changed) {
// To avoid overdrawing, we'll let the CPU run a bit to finish its
// drawing operation.
for (int i=0; i<10000; i++) {
if (!emul_step()) {
fprintf(stderr, "CPU halted, quitting\n");
usleep(1000 * 1000);
break;
}
spi_pulse(&spi);
}
draw_pixels();
}
// A low tech way of checking when the window was closed. The proper way
// involving WM_DELETE is too complicated.
xcb_get_geometry_reply_t *geom;
geom = xcb_get_geometry_reply(conn, xcb_get_geometry(conn, win), NULL);
if (geom == NULL) {
return; // window has been closed.
} else {
free(geom);
}
xcb_generic_event_t *e = xcb_poll_for_event(conn);
if (!e) {
continue;
}
switch (e->response_type & ~0x80) {
/* ESC to exit */
case XCB_KEY_RELEASE:
case XCB_KEY_PRESS:
if (_handle_keypress(e)) return;
break;
case XCB_EXPOSE: {
draw_pixels();
break;
}
default: {
break;
}
}
free(e);
}
}
static void usage()
{
fprintf(stderr, "Usage: ./sms [-k] [-c sdcard.img] /path/to/rom\n");
}
static byte spi_dbg(byte val)
{
fprintf(stderr, "SPI XCH: %x\n", val);
return val+1;
}
int main(int argc, char *argv[])
{
if (argc < 2) {
usage();
return 1;
}
vdp_init(&vdp);
vdp_changed = false;
ports_init(&ports);
pad_init(&pad, &ports.THA);
kbd_init(&kbd, &ports.THA);
sdc_init(&sdc);
spi_init(&spi, &ports.THB, &ports.TRB, spix_sdc);
int ch;
while ((ch = getopt(argc, argv, "kc:")) != -1) {
switch (ch) {
case 'k':
use_kbd = true;
break;
case 'c':
fprintf(stderr, "Setting up SD card image with %s\n", optarg);
sdc.fp = fopen(optarg, "r+");
if (sdc.fp == NULL) {
fprintf(stderr, "Can't open file\n");
return 1;
}
break;
}
}
if (optind != argc-1) {
usage();
return 1;
}
FILE *fp = fopen(argv[optind], "r");
if (fp == NULL) {
fprintf(stderr, "Can't open %s\n", argv[1]);
return 1;
}
m = emul_init();
m->ramstart = RAMSTART;
int i = 0;
int c;
while ((c = fgetc(fp)) != EOF && i < MAX_ROMSIZE) {
m->mem[i++] = c & 0xff;
}
pclose(fp);
if (c != EOF) {
fprintf(stderr, "ROM image too large.\n");
return 1;
}
if (use_kbd) {
ports.portA_rd = iord_kbd;
} else {
ports.portA_rd = iord_pad;
}
ports.portB_rd = iord_spi;
m->iord[VDP_CMD_PORT] = iord_vdp_cmd;
m->iord[VDP_DATA_PORT] = iord_vdp_data;
m->iord[PORTS_IO1_PORT] = iord_ports_io1;
m->iord[PORTS_IO2_PORT] = iord_ports_io2;
m->iord[PORTS_CTL_PORT] = iord_ports_ctl;
m->iowr[VDP_CMD_PORT] = iowr_vdp_cmd;
m->iowr[VDP_DATA_PORT] = iowr_vdp_data;
m->iowr[PORTS_CTL_PORT] = iowr_ports_ctl;
conn = xcb_connect(NULL, NULL);
screen = xcb_setup_roots_iterator(xcb_get_setup(conn)).data;
create_window();
draw_pixels();
event_loop();
emul_printdebug();
if (sdc.fp) {
fclose(sdc.fp);
}
return 0;
}