frontend: pandora: work around r20a vs r21 versioning

[pcsx_rearmed.git] / frontend / plugin_lib.c

/*
 * (C) notaz, 2010-2011
 *
 * This work is licensed under the terms of the GNU GPLv2 or later.
 * See the COPYING file in the top-level directory.
 */

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdarg.h>
#include <stdint.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <pthread.h>

#include "libpicofe/fonts.h"
#include "libpicofe/input.h"
#include "libpicofe/plat.h"
#include "libpicofe/arm/neon_scale2x.h"
#include "libpicofe/arm/neon_eagle2x.h"
#include "plugin_lib.h"
#include "menu.h"
#include "main.h"
#include "plat.h"
#include "pcnt.h"
#include "pl_gun_ts.h"
#include "cspace.h"
#include "psemu_plugin_defs.h"
#include "../libpcsxcore/new_dynarec/new_dynarec.h"
#include "../libpcsxcore/psxmem_map.h"
#include "../plugins/dfinput/externals.h"

int in_type1, in_type2;
int in_a1[2] = { 127, 127 }, in_a2[2] = { 127, 127 };
int in_adev[2] = { -1, -1 }, in_adev_axis[2][2] = {{ 0, 1 }, { 0, 1 }};
int in_adev_is_nublike[2];
int in_keystate, in_state_gun;
int in_enable_vibration;
void *tsdev;
void *pl_vout_buf;
int g_layer_x, g_layer_y, g_layer_w, g_layer_h;
static int pl_vout_w, pl_vout_h, pl_vout_bpp; /* output display/layer */
static int pl_vout_scale_w, pl_vout_scale_h, pl_vout_yoffset;
static int psx_w, psx_h, psx_bpp;
static int vsync_cnt;
static int is_pal, frame_interval, frame_interval1024;
static int vsync_usec_time;

// platform hooks
void (*pl_plat_clear)(void);
void (*pl_plat_blit)(int doffs, const void *src, int w, int h,
                     int sstride, int bgr24);
void (*pl_plat_hud_print)(int x, int y, const char *str, int bpp);


static __attribute__((noinline)) int get_cpu_ticks(void)
{
        static unsigned long last_utime;
        static int fd;
        unsigned long utime, ret;
        char buf[128];

        if (fd == 0)
                fd = open("/proc/self/stat", O_RDONLY);
        lseek(fd, 0, SEEK_SET);
        buf[0] = 0;
        read(fd, buf, sizeof(buf));
        buf[sizeof(buf) - 1] = 0;

        sscanf(buf, "%*d %*s %*c %*d %*d %*d %*d %*d %*u %*u %*u %*u %*u %lu", &utime);
        ret = utime - last_utime;
        if (ret > 200)
                ret = 0;
        last_utime = utime;
        return ret;
}

static void hud_print(void *fb, int w, int x, int y, const char *text)
{
        if (pl_plat_hud_print)
                pl_plat_hud_print(x, y, text, pl_vout_bpp);
        else if (pl_vout_bpp == 16)
                basic_text_out16_nf(fb, w, x, y, text);
}

static void hud_printf(void *fb, int w, int x, int y, const char *texto, ...)
{
        va_list args;
        char    buffer[256];

        va_start(args, texto);
        vsnprintf(buffer, sizeof(buffer), texto, args);
        va_end(args);

        hud_print(fb, w, x, y, buffer);
}

static void print_msg(int h, int border)
{
        hud_print(pl_vout_buf, pl_vout_w, border + 2, h - 10, hud_msg);
}

static void print_fps(int h, int border)
{
        hud_printf(pl_vout_buf, pl_vout_w, border + 2, h - 10,
                "%2d %4.1f", pl_rearmed_cbs.flips_per_sec,
                pl_rearmed_cbs.vsps_cur);
}

static void print_cpu_usage(int w, int h, int border)
{
        hud_printf(pl_vout_buf, pl_vout_w, pl_vout_w - border - 28, h - 10,
                "%3d", pl_rearmed_cbs.cpu_usage);
}

// draw 192x8 status of 24 sound channels
static __attribute__((noinline)) void draw_active_chans(int vout_w, int vout_h)
{
        extern void spu_get_debug_info(int *chans_out, int *run_chans,
                int *fmod_chans_out, int *noise_chans_out); // hack
        int live_chans, run_chans, fmod_chans, noise_chans;

        static const unsigned short colors[2] = { 0x1fe3, 0x0700 };
        unsigned short *dest = (unsigned short *)pl_vout_buf +
                vout_w * (vout_h - 10) + vout_w / 2 - 192/2;
        unsigned short *d, p;
        int c, x, y;

        if (dest == NULL || pl_vout_bpp != 16)
                return;

        spu_get_debug_info(&live_chans, &run_chans, &fmod_chans, &noise_chans);

        for (c = 0; c < 24; c++) {
                d = dest + c * 8;
                p = !(live_chans & (1<<c)) ? (run_chans & (1<<c) ? 0x01c0 : 0) :
                     (fmod_chans & (1<<c)) ? 0xf000 :
                     (noise_chans & (1<<c)) ? 0x001f :
                     colors[c & 1];
                for (y = 0; y < 8; y++, d += vout_w)
                        for (x = 0; x < 8; x++)
                                d[x] = p;
        }
}

static void print_hud(int w, int h, int xborder)
{
        if (h < 16)
                return;

        if (w < pl_vout_w)
                xborder += (pl_vout_w - w) / 2;
        if (h > pl_vout_h)
                h = pl_vout_h;

        if (g_opts & OPT_SHOWSPU)
                draw_active_chans(w, h);

        if (hud_msg[0] != 0)
                print_msg(h, xborder);
        else if (g_opts & OPT_SHOWFPS)
                print_fps(h, xborder);

        if (g_opts & OPT_SHOWCPU)
                print_cpu_usage(w, h, xborder);
}

/* update scaler target size according to user settings */
static void update_layer_size(int w, int h)
{
        float mult;
        int imult;

        switch (g_scaler) {
        case SCALE_1_1:
                g_layer_w = w; g_layer_h = h;
                break;

        case SCALE_2_2:
                g_layer_w = w; g_layer_h = h;
                if (w * 2 <= g_menuscreen_w)
                        g_layer_w = w * 2;
                if (h * 2 <= g_menuscreen_h)
                        g_layer_h = h * 2;
                break;

        case SCALE_4_3v2:
                if (h > g_menuscreen_h || (240 < h && h <= 360))
                        goto fractional_4_3;

                // 4:3 that prefers integer scaling
                imult = g_menuscreen_h / h;
                g_layer_w = w * imult;
                g_layer_h = h * imult;
                mult = (float)g_layer_w / (float)g_layer_h;
                if (mult < 1.25f || mult > 1.666f)
                        g_layer_w = 4.0f/3.0f * (float)g_layer_h;
                printf("  -> %dx%d %.1f\n", g_layer_w, g_layer_h, mult);
                break;

        fractional_4_3:
        case SCALE_4_3:
                mult = 240.0f / (float)h * 4.0f / 3.0f;
                if (h > 256)
                        mult *= 2.0f;
                g_layer_w = mult * (float)g_menuscreen_h;
                g_layer_h = g_menuscreen_h;
                printf("  -> %dx%d %.1f\n", g_layer_w, g_layer_h, mult);
                break;

        case SCALE_FULLSCREEN:
                g_layer_w = g_menuscreen_w;
                g_layer_h = g_menuscreen_h;
                break;

        default:
                break;
        }

        g_layer_x = g_menuscreen_w / 2 - g_layer_w / 2;
        g_layer_y = g_menuscreen_h / 2 - g_layer_h / 2;
        if (g_layer_x < 0) g_layer_x = 0;
        if (g_layer_y < 0) g_layer_y = 0;
        if (g_layer_w > g_menuscreen_w) g_layer_w = g_menuscreen_w;
        if (g_layer_h > g_menuscreen_h) g_layer_h = g_menuscreen_h;
}

// XXX: this is platform specific really
static inline int resolution_ok(int w, int h)
{
        return w <= 1024 && h <= 512;
}

static void pl_vout_set_mode(int w, int h, int raw_w, int raw_h, int bpp)
{
        int vout_w, vout_h, vout_bpp;
        int buf_yoffset = 0;

        // special h handling, Wipeout likes to change it by 1-6
        static int vsync_cnt_ms_prev;
        if ((unsigned int)(vsync_cnt - vsync_cnt_ms_prev) < 5*60)
                h = (h + 7) & ~7;
        vsync_cnt_ms_prev = vsync_cnt;

        psx_w = raw_w;
        psx_h = raw_h;
        psx_bpp = bpp;
        vout_w = w;
        vout_h = h;
        vout_bpp = bpp;
        if (pl_rearmed_cbs.only_16bpp)
                vout_bpp = 16;

        // don't use very low heights
        if (vout_h < 192) {
                buf_yoffset = (192 - vout_h) / 2;
                vout_h = 192;
        }

        pl_vout_scale_w = pl_vout_scale_h = 1;
#ifdef __ARM_NEON__
        if (soft_filter) {
                if (resolution_ok(w * 2, h * 2) && bpp == 16) {
                        pl_vout_scale_w = 2;
                        pl_vout_scale_h = 2;
                }
                else {
                        // filter unavailable
                        hud_msg[0] = 0;
                }
        }
        else if (scanlines != 0 && scanline_level != 100 && bpp == 16) {
                if (h <= 256)
                        pl_vout_scale_h = 2;
        }
#endif
        vout_w *= pl_vout_scale_w;
        vout_h *= pl_vout_scale_h;

        update_layer_size(vout_w, vout_h);

        pl_vout_buf = plat_gvideo_set_mode(&vout_w, &vout_h, &vout_bpp);
        if (pl_vout_buf == NULL && pl_plat_blit == NULL)
                fprintf(stderr, "failed to set mode %dx%d@%d\n",
                        vout_w, vout_h, vout_bpp);
        else {
                pl_vout_w = vout_w;
                pl_vout_h = vout_h;
                pl_vout_bpp = vout_bpp;
                pl_vout_yoffset = buf_yoffset;
        }
        if (pl_vout_buf != NULL)
                pl_vout_buf = (char *)pl_vout_buf
                        + pl_vout_yoffset * pl_vout_w * pl_vout_bpp / 8;

        menu_notify_mode_change(pl_vout_w, pl_vout_h, pl_vout_bpp);
}

static void pl_vout_flip(const void *vram, int stride, int bgr24, int w, int h)
{
        static int doffs_old, clear_counter;
        unsigned char *dest = pl_vout_buf;
        const unsigned short *src = vram;
        int dstride = pl_vout_w, h1 = h;
        int doffs;

        pcnt_start(PCNT_BLIT);

        if (vram == NULL) {
                // blanking
                if (pl_plat_clear)
                        pl_plat_clear();
                else
                        memset(pl_vout_buf, 0,
                                dstride * pl_vout_h * pl_vout_bpp / 8);
                goto out_hud;
        }

        // borders
        doffs = (dstride - w * pl_vout_scale_w) / 2 & ~1;

        if (doffs > doffs_old)
                clear_counter = 2;
        doffs_old = doffs;

        if (clear_counter > 0) {
                if (pl_plat_clear)
                        pl_plat_clear();
                else
                        memset(pl_vout_buf, 0,
                                dstride * pl_vout_h * pl_vout_bpp / 8);
                clear_counter--;
        }

        if (pl_plat_blit)
        {
                pl_plat_blit(doffs, src, w, h, stride, bgr24);
                goto out_hud;
        }

        if (dest == NULL)
                goto out;

        dest += doffs * 2;

        if (bgr24)
        {
                if (pl_rearmed_cbs.only_16bpp) {
                        for (; h1-- > 0; dest += dstride * 2, src += stride)
                        {
                                bgr888_to_rgb565(dest, src, w * 3);
                        }
                }
                else {
                        dest -= doffs * 2;
                        dest += (doffs / 8) * 24;

                        for (; h1-- > 0; dest += dstride * 3, src += stride)
                        {
                                bgr888_to_rgb888(dest, src, w * 3);
                        }
                }
        }
#ifdef __ARM_NEON__
        else if (soft_filter == SOFT_FILTER_SCALE2X && pl_vout_scale_w == 2)
        {
                neon_scale2x_16_16(src, (void *)dest, w,
                        stride * 2, dstride * 2, h);
        }
        else if (soft_filter == SOFT_FILTER_EAGLE2X && pl_vout_scale_w == 2)
        {
                neon_eagle2x_16_16(src, (void *)dest, w,
                        stride * 2, dstride * 2, h);
        }
        else if (scanlines != 0 && scanline_level != 100)
        {
                int l = scanline_level * 2048 / 100;
                int stride_0 = pl_vout_scale_h >= 2 ? 0 : stride;

                h1 *= pl_vout_scale_h;
                for (; h1 >= 2; h1 -= 2)
                {
                        bgr555_to_rgb565(dest, src, w * 2);
                        dest += dstride * 2, src += stride_0;

                        bgr555_to_rgb565_b(dest, src, w * 2, l);
                        dest += dstride * 2, src += stride;
                }
        }
#endif
        else
        {
                for (; h1-- > 0; dest += dstride * 2, src += stride)
                {
                        bgr555_to_rgb565(dest, src, w * 2);
                }
        }

out_hud:
        print_hud(w * pl_vout_scale_w, h * pl_vout_scale_h, 0);

out:
        pcnt_end(PCNT_BLIT);

        // let's flip now
        pl_vout_buf = plat_gvideo_flip();
        if (pl_vout_buf != NULL)
                pl_vout_buf = (char *)pl_vout_buf
                        + pl_vout_yoffset * pl_vout_w * pl_vout_bpp / 8;

        pl_rearmed_cbs.flip_cnt++;
}

static int pl_vout_open(void)
{
        struct timeval now;

        // force mode update on pl_vout_set_mode() call from gpulib/vout_pl
        pl_vout_buf = NULL;

        plat_gvideo_open(is_pal);

        gettimeofday(&now, 0);
        vsync_usec_time = now.tv_usec;
        while (vsync_usec_time >= frame_interval)
                vsync_usec_time -= frame_interval;

        return 0;
}

static void pl_vout_close(void)
{
        plat_gvideo_close();
}

static void pl_set_gpu_caps(int caps)
{
        pl_rearmed_cbs.gpu_caps = caps;
}

void *pl_prepare_screenshot(int *w, int *h, int *bpp)
{
        void *ret = plat_prepare_screenshot(w, h, bpp);
        if (ret != NULL)
                return ret;

        *w = pl_vout_w;
        *h = pl_vout_h;
        *bpp = pl_vout_bpp;

        return pl_vout_buf;
}

/* display/redering mode switcher */
static int dispmode_default(void)
{
        pl_rearmed_cbs.gpu_neon.enhancement_enable = 0;
        soft_filter = SOFT_FILTER_NONE;
        snprintf(hud_msg, sizeof(hud_msg), "default mode");
        return 1;
}

#ifdef __ARM_NEON__
static int dispmode_doubleres(void)
{
        if (!(pl_rearmed_cbs.gpu_caps & GPU_CAP_SUPPORTS_2X)
            || !resolution_ok(psx_w * 2, psx_h * 2) || psx_bpp != 16)
                return 0;

        dispmode_default();
        pl_rearmed_cbs.gpu_neon.enhancement_enable = 1;
        snprintf(hud_msg, sizeof(hud_msg), "double resolution");
        return 1;
}

static int dispmode_scale2x(void)
{
        if (!resolution_ok(psx_w * 2, psx_h * 2) || psx_bpp != 16)
                return 0;

        dispmode_default();
        soft_filter = SOFT_FILTER_SCALE2X;
        snprintf(hud_msg, sizeof(hud_msg), "scale2x");
        return 1;
}

static int dispmode_eagle2x(void)
{
        if (!resolution_ok(psx_w * 2, psx_h * 2) || psx_bpp != 16)
                return 0;

        dispmode_default();
        soft_filter = SOFT_FILTER_EAGLE2X;
        snprintf(hud_msg, sizeof(hud_msg), "eagle2x");
        return 1;
}
#endif

static int (*dispmode_switchers[])(void) = {
        dispmode_default,
#ifdef __ARM_NEON__
        dispmode_doubleres,
        dispmode_scale2x,
        dispmode_eagle2x,
#endif
};

static int dispmode_current;

void pl_switch_dispmode(void)
{
        if (pl_rearmed_cbs.gpu_caps & GPU_CAP_OWNS_DISPLAY)
                return;

        while (1) {
                dispmode_current++;
                if (dispmode_current >=
                    sizeof(dispmode_switchers) / sizeof(dispmode_switchers[0]))
                        dispmode_current = 0;
                if (dispmode_switchers[dispmode_current]())
                        break;
        }
}

#ifndef MAEMO
/* adjust circle-like analog inputs to better match
 * more square-like analogs in PSX */
static void update_analog_nub_adjust(int *x_, int *y_)
{
        #define d 16
        static const int scale[] =
                { 0 - d*2,  0 - d*2,  0 - d*2, 12 - d*2,
                 30 - d*2, 60 - d*2, 75 - d*2, 60 - d*2, 60 - d*2 };
        int x = abs(*x_);
        int y = abs(*y_);
        int scale_x = scale[y / 16];
        int scale_y = scale[x / 16];

        if (x) {
                x += d + (x * scale_x >> 8);
                if (*x_ < 0)
                        x = -x;
        }
        if (y) {
                y += d + (y * scale_y >> 8);
                if (*y_ < 0)
                        y = -y;
        }

        *x_ = x;
        *y_ = y;
        #undef d
}

static void update_analogs(void)
{
        int *nubp[2] = { in_a1, in_a2 };
        int vals[2];
        int i, a, v, ret;

        for (i = 0; i < 2; i++)
        {
                if (in_adev[i] < 0)
                        continue;

                for (a = 0; a < 2; a++) {
                        vals[a] = 0;

                        ret = in_update_analog(in_adev[i], in_adev_axis[i][a], &v);
                        if (ret == 0)
                                vals[a] = 128 * v / IN_ABS_RANGE;
                }

                if (in_adev_is_nublike[i])
                        update_analog_nub_adjust(&vals[0], &vals[1]);

                for (a = 0; a < 2; a++) {
                        v = vals[a] + 127;
                        if (v < 0) v = 0;
                        else if (v > 255) v = 255;
                        nubp[i][a] = v;
                }

        }
        //printf("%4d %4d %4d %4d\n", in_a1[0], in_a1[1], in_a2[0], in_a2[1]);
}

static void update_input(void)
{
        int actions[IN_BINDTYPE_COUNT] = { 0, };
        unsigned int emu_act;

        in_update(actions);
        if (in_type1 == PSE_PAD_TYPE_ANALOGPAD)
                update_analogs();
        emu_act = actions[IN_BINDTYPE_EMU];
        in_state_gun = (emu_act & SACTION_GUN_MASK) >> SACTION_GUN_TRIGGER;

        emu_act &= ~SACTION_GUN_MASK;
        if (emu_act) {
                int which = 0;
                for (; !(emu_act & 1); emu_act >>= 1, which++)
                        ;
                emu_act = which;
        }
        emu_set_action(emu_act);

        in_keystate = actions[IN_BINDTYPE_PLAYER12];
}
#else /* MAEMO */
extern void update_input(void);
#endif

void pl_update_gun(int *xn, int *yn, int *xres, int *yres, int *in)
{
        if (tsdev)
                pl_gun_ts_update(tsdev, xn, yn, in);

        *xres = psx_w;
        *yres = psx_h;
}

#define MAX_LAG_FRAMES 3

#define tvdiff(tv, tv_old) \
        ((tv.tv_sec - tv_old.tv_sec) * 1000000 + tv.tv_usec - tv_old.tv_usec)

/* called on every vsync */
void pl_frame_limit(void)
{
        static struct timeval tv_old, tv_expect;
        static int vsync_cnt_prev, drc_active_vsyncs;
        struct timeval now;
        int diff, usadj;

        if (g_emu_resetting)
                return;

        vsync_cnt++;

        /* doing input here because the pad is polled
         * thousands of times per frame for some reason */
        update_input();

        pcnt_end(PCNT_ALL);
        gettimeofday(&now, 0);

        if (now.tv_sec != tv_old.tv_sec) {
                diff = tvdiff(now, tv_old);
                pl_rearmed_cbs.vsps_cur = 0.0f;
                if (0 < diff && diff < 2000000)
                        pl_rearmed_cbs.vsps_cur = 1000000.0f * (vsync_cnt - vsync_cnt_prev) / diff;
                vsync_cnt_prev = vsync_cnt;

                if (g_opts & OPT_SHOWFPS)
                        pl_rearmed_cbs.flips_per_sec = pl_rearmed_cbs.flip_cnt;
                pl_rearmed_cbs.flip_cnt = 0;
                if (g_opts & OPT_SHOWCPU)
                        pl_rearmed_cbs.cpu_usage = get_cpu_ticks();

                if (hud_new_msg > 0) {
                        hud_new_msg--;
                        if (hud_new_msg == 0)
                                hud_msg[0] = 0;
                }
                tv_old = now;
        }
#ifdef PCNT
        static int ya_vsync_count;
        if (++ya_vsync_count == PCNT_FRAMES) {
                pcnt_print(pl_rearmed_cbs.vsps_cur);
                ya_vsync_count = 0;
        }
#endif

        // tv_expect uses usec*1024 units instead of usecs for better accuracy
        tv_expect.tv_usec += frame_interval1024;
        if (tv_expect.tv_usec >= (1000000 << 10)) {
                tv_expect.tv_usec -= (1000000 << 10);
                tv_expect.tv_sec++;
        }
        diff = (tv_expect.tv_sec - now.tv_sec) * 1000000 + (tv_expect.tv_usec >> 10) - now.tv_usec;

        if (diff > MAX_LAG_FRAMES * frame_interval || diff < -MAX_LAG_FRAMES * frame_interval) {
                //printf("pl_frame_limit reset, diff=%d, iv %d\n", diff, frame_interval);
                tv_expect = now;
                diff = 0;
                // try to align with vsync
                usadj = vsync_usec_time;
                while (usadj < tv_expect.tv_usec - frame_interval)
                        usadj += frame_interval;
                tv_expect.tv_usec = usadj << 10;
        }

        if (!(g_opts & OPT_NO_FRAMELIM) && diff > frame_interval) {
                // yay for working usleep on pandora!
                //printf("usleep %d\n", diff - frame_interval / 2);
                usleep(diff - frame_interval);
        }

        if (pl_rearmed_cbs.frameskip) {
                if (diff < -frame_interval)
                        pl_rearmed_cbs.fskip_advice = 1;
                else if (diff >= 0)
                        pl_rearmed_cbs.fskip_advice = 0;

                // recompilation is not that fast and may cause frame skip on
                // loading screens and such, resulting in flicker or glitches
                if (new_dynarec_did_compile) {
                        if (drc_active_vsyncs < 32)
                                pl_rearmed_cbs.fskip_advice = 0;
                        drc_active_vsyncs++;
                }
                else
                        drc_active_vsyncs = 0;
                new_dynarec_did_compile = 0;
        }

        pcnt_start(PCNT_ALL);
}

void pl_timing_prepare(int is_pal_)
{
        pl_rearmed_cbs.fskip_advice = 0;
        pl_rearmed_cbs.flips_per_sec = 0;
        pl_rearmed_cbs.cpu_usage = 0;

        is_pal = is_pal_;
        frame_interval = is_pal ? 20000 : 16667;
        frame_interval1024 = is_pal ? 20000*1024 : 17066667;

        // used by P.E.Op.S. frameskip code
        pl_rearmed_cbs.gpu_peops.fFrameRateHz = is_pal ? 50.0f : 59.94f;
        pl_rearmed_cbs.gpu_peops.dwFrameRateTicks =
                (100000*100 / (unsigned long)(pl_rearmed_cbs.gpu_peops.fFrameRateHz*100));
}

static void pl_get_layer_pos(int *x, int *y, int *w, int *h)
{
        *x = g_layer_x;
        *y = g_layer_y;
        *w = g_layer_w;
        *h = g_layer_h;
}

static void *pl_mmap(unsigned int size);
static void pl_munmap(void *ptr, unsigned int size);

struct rearmed_cbs pl_rearmed_cbs = {
        pl_get_layer_pos,
        pl_vout_open,
        pl_vout_set_mode,
        pl_vout_flip,
        pl_vout_close,

        .mmap = pl_mmap,
        .munmap = pl_munmap,
        .pl_set_gpu_caps = pl_set_gpu_caps,
};

/* watchdog */
static void *watchdog_thread(void *unused)
{
        int vsync_cnt_old = 0;
        int seen_dead = 0;
        int sleep_time = 5;

#if !defined(NDEBUG) || defined(DRC_DBG)
        // don't interfere with debug
        return NULL;
#endif
        while (1)
        {
                sleep(sleep_time);

                if (stop) {
                        seen_dead = 0;
                        sleep_time = 5;
                        continue;
                }
                if (vsync_cnt != vsync_cnt_old) {
                        vsync_cnt_old = vsync_cnt;
                        seen_dead = 0;
                        sleep_time = 2;
                        continue;
                }

                seen_dead++;
                sleep_time = 1;
                if (seen_dead > 1)
                        fprintf(stderr, "watchdog: seen_dead %d\n", seen_dead);
                if (seen_dead > 4) {
                        fprintf(stderr, "watchdog: lockup detected, aborting\n");
                        // we can't do any cleanup here really, the main thread is
                        // likely touching resources and would crash anyway
                        abort();
                }
        }
}

void pl_start_watchdog(void)
{
        pthread_attr_t attr;
        pthread_t tid;
        int ret;
        
        pthread_attr_init(&attr);
        pthread_attr_setdetachstate(&attr, PTHREAD_CREATE_DETACHED);

        ret = pthread_create(&tid, &attr, watchdog_thread, NULL);
        if (ret != 0)
                fprintf(stderr, "could not start watchdog: %d\n", ret);
}

static void *pl_emu_mmap(unsigned long addr, size_t size, int is_fixed,
        enum psxMapTag tag)
{
        return plat_mmap(addr, size, 0, is_fixed);
}

static void pl_emu_munmap(void *ptr, size_t size, enum psxMapTag tag)
{
        plat_munmap(ptr, size);
}

static void *pl_mmap(unsigned int size)
{
        return psxMapHook(0, size, 0, MAP_TAG_VRAM);
}

static void pl_munmap(void *ptr, unsigned int size)
{
        psxUnmapHook(ptr, size, MAP_TAG_VRAM);
}

void pl_init(void)
{
        extern unsigned int hSyncCount; // from psxcounters
        extern unsigned int frame_counter;

        psx_w = psx_h = pl_vout_w = pl_vout_h = 256;
        psx_bpp = pl_vout_bpp = 16;

        tsdev = pl_gun_ts_init();

        pl_rearmed_cbs.gpu_hcnt = &hSyncCount;
        pl_rearmed_cbs.gpu_frame_count = &frame_counter;

        psxMapHook = pl_emu_mmap;
        psxUnmapHook = pl_emu_munmap;
}