[pcsx_rearmed.git] / libpcsxcore / psxcounters.c

/***************************************************************************
 *   Copyright (C) 2010 by Blade_Arma                                      *
 *                                                                         *
 *   This program is free software; you can redistribute it and/or modify  *
 *   it under the terms of the GNU General Public License as published by  *
 *   the Free Software Foundation; either version 2 of the License, or     *
 *   (at your option) any later version.                                   *
 *                                                                         *
 *   This program is distributed in the hope that it will be useful,       *
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of        *
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the         *
 *   GNU General Public License for more details.                          *
 *                                                                         *
 *   You should have received a copy of the GNU General Public License     *
 *   along with this program; if not, write to the                         *
 *   Free Software Foundation, Inc.,                                       *
 *   51 Franklin Street, Fifth Floor, Boston, MA 02111-1307 USA.           *
 ***************************************************************************/

/*
 * Internal PSX counters.
 */

#include "psxcounters.h"
#include "psxevents.h"
#include "gpu.h"
//#include "debug.h"
#define DebugVSync()

/******************************************************************************/

enum
{
    RcSyncModeEnable  = 0x0001, // 0
    Rc01BlankPause    = 0 << 1, // 1,2
    Rc01UnblankReset  = 1 << 1, // 1,2
    Rc01UnblankReset2 = 2 << 1, // 1,2
    Rc2Stop           = 0 << 1, // 1,2
    Rc2Stop2          = 3 << 1, // 1,2
    RcCountToTarget   = 0x0008, // 3
    RcIrqOnTarget     = 0x0010, // 4
    RcIrqOnOverflow   = 0x0020, // 5
    RcIrqRegenerate   = 0x0040, // 6
    RcUnknown7        = 0x0080, // 7    ?
    Rc0PixelClock     = 0x0100, // 8    fake implementation
    Rc1HSyncClock     = 0x0100, // 8
    Rc2Unknown8       = 0x0100, // 8    ?
    Rc0Unknown9       = 0x0200, // 9    ?
    Rc1Unknown9       = 0x0200, // 9    ?
    Rc2OneEighthClock = 0x0200, // 9
    RcUnknown10       = 0x0400, // 10   ?
    RcCountEqTarget   = 0x0800, // 11
    RcOverflow        = 0x1000, // 12
    RcUnknown13       = 0x2000, // 13   ? (always zero)
    RcUnknown14       = 0x4000, // 14   ? (always zero)
    RcUnknown15       = 0x8000, // 15   ? (always zero)
};

#define CounterQuantity           ( 4 )
//static const u32 CounterQuantity  = 4;

static const u32 CountToOverflow  = 0;
static const u32 CountToTarget    = 1;

static const u32 HSyncTotal[]     = { 263, 314 };
#define VBlankStart 240 // todo: depend on the actual GPU setting

#define VERBOSE_LEVEL 0

/******************************************************************************/
#ifdef DRC_DISABLE
Rcnt rcnts[ CounterQuantity ];
#endif
u32 hSyncCount = 0;
u32 frame_counter = 0;
static u32 hsync_steps = 0;

u32 psxNextCounter = 0, psxNextsCounter = 0;

/******************************************************************************/

#define FPS_FRACTIONAL_PAL  (53203425/314./3406) // ~49.75
#define FPS_FRACTIONAL_NTSC (53693175/263./3413) // ~59.81

static inline
u32 frameCycles(void)
{
    int ff = Config.FractionalFramerate >= 0
        ? Config.FractionalFramerate : Config.hacks.fractional_Framerate;
    if (ff)
    {
        if (Config.PsxType)
            return (u32)(PSXCLK / FPS_FRACTIONAL_PAL);
        else
            return (u32)(PSXCLK / FPS_FRACTIONAL_NTSC);
    }
    return Config.PsxType ? (PSXCLK / 50) : (PSXCLK / 60);
}

// used to inform the frontend about the exact framerate
double psxGetFps()
{
    int ff = Config.FractionalFramerate >= 0
        ? Config.FractionalFramerate : Config.hacks.fractional_Framerate;
    if (ff)
        return Config.PsxType ? FPS_FRACTIONAL_PAL : FPS_FRACTIONAL_NTSC;
    else
        return Config.PsxType ? 50.0 : 60.0;
}

// to inform the frontend about the exact famerate
static inline
u32 lineCycles(void)
{
    // should be more like above, but our timing is already poor anyway
    if (Config.PsxType)
        return PSXCLK / 50 / HSyncTotal[1];
    else
        return PSXCLK / 60 / HSyncTotal[0];
}

static inline
void setIrq( u32 irq )
{
    psxHu32ref(0x1070) |= SWAPu32(irq);
}

static
void verboseLog( u32 level, const char *str, ... )
{
#if VERBOSE_LEVEL > 0
    if( level <= VERBOSE_LEVEL )
    {
        va_list va;
        char buf[ 4096 ];

        va_start( va, str );
        vsprintf( buf, str, va );
        va_end( va );

        printf( "%s", buf );
        fflush( stdout );
    }
#endif
}

/******************************************************************************/

static inline
void _psxRcntWcount( u32 index, u32 value )
{
    value &= 0xffff;

    rcnts[index].cycleStart  = psxRegs.cycle;
    rcnts[index].cycleStart -= value * rcnts[index].rate;

    // TODO: <=.
    if( value < rcnts[index].target )
    {
        rcnts[index].cycle = rcnts[index].target * rcnts[index].rate;
        rcnts[index].counterState = CountToTarget;
    }
    else
    {
        rcnts[index].cycle = 0x10000 * rcnts[index].rate;
        rcnts[index].counterState = CountToOverflow;
    }
}

static inline
u32 _psxRcntRcount( u32 index )
{
    u32 count;

    count  = psxRegs.cycle;
    count -= rcnts[index].cycleStart;
    if (rcnts[index].rate > 1)
        count /= rcnts[index].rate;

    if( count > 0x10000 )
    {
        verboseLog( 1, "[RCNT %i] rcount > 0x10000: %x\n", index, count );
    }
    count &= 0xffff;

    return count;
}

static
void _psxRcntWmode( u32 index, u32 value )
{
    rcnts[index].mode = value;

    switch( index )
    {
        case 0:
            if( value & Rc0PixelClock )
            {
                rcnts[index].rate = 5;
            }
            else
            {
                rcnts[index].rate = 1;
            }
        break;
        case 1:
            if( value & Rc1HSyncClock )
            {
                rcnts[index].rate = lineCycles();
            }
            else
            {
                rcnts[index].rate = 1;
            }
        break;
        case 2:
            if( value & Rc2OneEighthClock )
            {
                rcnts[index].rate = 8;
            }
            else
            {
                rcnts[index].rate = 1;
            }

            // TODO: wcount must work.
            if( (value & 7) == (RcSyncModeEnable | Rc2Stop) ||
                (value & 7) == (RcSyncModeEnable | Rc2Stop2) )
            {
                rcnts[index].rate = 0xffffffff;
            }
        break;
    }
}

/******************************************************************************/

static
void psxRcntSet()
{
    s32 countToUpdate;
    u32 i;

    psxNextsCounter = psxRegs.cycle;
    psxNextCounter  = 0x7fffffff;

    for( i = 0; i < CounterQuantity; ++i )
    {
        countToUpdate = rcnts[i].cycle - (psxNextsCounter - rcnts[i].cycleStart);

        if( countToUpdate < 0 )
        {
            psxNextCounter = 0;
            break;
        }

        if( countToUpdate < (s32)psxNextCounter )
        {
            psxNextCounter = countToUpdate;
        }
    }

    set_event(PSXINT_RCNT, psxNextCounter);
}

/******************************************************************************/

static
void psxRcntReset( u32 index )
{
    u32 rcycles;

    rcnts[index].mode |= RcUnknown10;

    if( rcnts[index].counterState == CountToTarget )
    {
        rcycles = psxRegs.cycle - rcnts[index].cycleStart;
        if( rcnts[index].mode & RcCountToTarget )
        {
            rcycles -= rcnts[index].target * rcnts[index].rate;
            rcnts[index].cycleStart = psxRegs.cycle - rcycles;
        }
        else
        {
            rcnts[index].cycle = 0x10000 * rcnts[index].rate;
            rcnts[index].counterState = CountToOverflow;
        }

        if( rcnts[index].mode & RcIrqOnTarget )
        {
            if( (rcnts[index].mode & RcIrqRegenerate) || (!rcnts[index].irqState) )
            {
                verboseLog( 3, "[RCNT %i] irq\n", index );
                setIrq( rcnts[index].irq );
                rcnts[index].irqState = 1;
            }
        }

        rcnts[index].mode |= RcCountEqTarget;

        if( rcycles < 0x10000 * rcnts[index].rate )
            return;
    }

    if( rcnts[index].counterState == CountToOverflow )
    {
        rcycles = psxRegs.cycle - rcnts[index].cycleStart;
        rcycles -= 0x10000 * rcnts[index].rate;

        rcnts[index].cycleStart = psxRegs.cycle - rcycles;

        if( rcycles < rcnts[index].target * rcnts[index].rate )
        {
            rcnts[index].cycle = rcnts[index].target * rcnts[index].rate;
            rcnts[index].counterState = CountToTarget;
        }

        if( rcnts[index].mode & RcIrqOnOverflow )
        {
            if( (rcnts[index].mode & RcIrqRegenerate) || (!rcnts[index].irqState) )
            {
                verboseLog( 3, "[RCNT %i] irq\n", index );
                setIrq( rcnts[index].irq );
                rcnts[index].irqState = 1;
            }
        }

        rcnts[index].mode |= RcOverflow;
    }
}

static void scheduleRcntBase(void)
{
    // Schedule next call, in hsyncs
    if (hSyncCount < VBlankStart)
        hsync_steps = VBlankStart - hSyncCount;
    else
        hsync_steps = HSyncTotal[Config.PsxType] - hSyncCount;

    if (hSyncCount + hsync_steps == HSyncTotal[Config.PsxType])
    {
        rcnts[3].cycle = frameCycles();
    }
    else
    {
        // clk / 50 / 314 ~= 2157.25
        // clk / 60 / 263 ~= 2146.31
        u32 mult = Config.PsxType ? 8836089 : 8791293;
        rcnts[3].cycle = hsync_steps * mult >> 12;
    }
}

void psxRcntUpdate()
{
    u32 cycle, cycles_passed;

    cycle = psxRegs.cycle;

    // rcnt 0.
    cycles_passed = cycle - rcnts[0].cycleStart;
    while( cycles_passed >= rcnts[0].cycle )
    {
        if (((rcnts[0].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset) ||
             (rcnts[0].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset2))
            && cycles_passed > lineCycles())
        {
            u32 q = cycles_passed / (lineCycles() + 1u);
            rcnts[0].cycleStart += q * lineCycles();
            break;
        }
        else
            psxRcntReset( 0 );

        cycles_passed = cycle - rcnts[0].cycleStart;
    }

    // rcnt 1.
    while( cycle - rcnts[1].cycleStart >= rcnts[1].cycle )
    {
        psxRcntReset( 1 );
    }

    // rcnt 2.
    while( cycle - rcnts[2].cycleStart >= rcnts[2].cycle )
    {
        psxRcntReset( 2 );
    }

    // rcnt base.
    if( cycle - rcnts[3].cycleStart >= rcnts[3].cycle )
    {
        hSyncCount += hsync_steps;

        // VSync irq.
        if( hSyncCount == VBlankStart )
        {
            HW_GPU_STATUS &= SWAP32(~PSXGPU_LCF);
            GPU_vBlank( 1, 0 );
            setIrq( 0x01 );

            EmuUpdate();
            GPU_updateLace();

            if( SPU_async )
            {
                SPU_async( cycle, 1 );
            }
        }
        
        // Update lace.
        if( hSyncCount >= HSyncTotal[Config.PsxType] )
        {
            u32 status, field = 0;
            rcnts[3].cycleStart += frameCycles();
            hSyncCount = 0;
            frame_counter++;

            gpuSyncPluginSR();
            status = SWAP32(HW_GPU_STATUS) | PSXGPU_FIELD;
            if ((status & PSXGPU_ILACE_BITS) == PSXGPU_ILACE_BITS) {
                field = frame_counter & 1;
                status |= field << 31;
                status ^= field << 13;
            }
            HW_GPU_STATUS = SWAP32(status);
            GPU_vBlank(0, field);
            if ((s32)(psxRegs.gpuIdleAfter - psxRegs.cycle) < 0)
                psxRegs.gpuIdleAfter = psxRegs.cycle - 1; // prevent overflow

            if ((rcnts[0].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset) ||
                (rcnts[0].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset2))
            {
                rcnts[0].cycleStart = rcnts[3].cycleStart;
            }

            if ((rcnts[1].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset) ||
                (rcnts[1].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset2))
            {
                rcnts[1].cycleStart = rcnts[3].cycleStart;
            }
            else if (rcnts[1].mode & Rc1HSyncClock)
            {
                // adjust to remove the rounding error
                _psxRcntWcount(1, (psxRegs.cycle - rcnts[1].cycleStart) / rcnts[1].rate);
            }
        }

        scheduleRcntBase();
    }

    psxRcntSet();

#if 0 //ndef NDEBUG
    DebugVSync();
#endif
}

/******************************************************************************/

void psxRcntWcount( u32 index, u32 value )
{
    verboseLog( 2, "[RCNT %i] wcount: %x\n", index, value );

    _psxRcntWcount( index, value );
    psxRcntSet();
}

void psxRcntWmode( u32 index, u32 value )
{
    verboseLog( 1, "[RCNT %i] wmode: %x\n", index, value );

    _psxRcntWmode( index, value );
    _psxRcntWcount( index, 0 );

    rcnts[index].irqState = 0;
    psxRcntSet();
}

void psxRcntWtarget( u32 index, u32 value )
{
    verboseLog( 1, "[RCNT %i] wtarget: %x\n", index, value );

    rcnts[index].target = value;

    _psxRcntWcount( index, _psxRcntRcount( index ) );
    psxRcntSet();
}

/******************************************************************************/

u32 psxRcntRcount0()
{
    u32 index = 0;
    u32 count;

    if ((rcnts[0].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset) ||
        (rcnts[0].mode & 7) == (RcSyncModeEnable | Rc01UnblankReset2))
    {
        count = psxRegs.cycle - rcnts[index].cycleStart;
        //count = ((16u * count) % (16u * PSXCLK / 60 / 263)) / 16u;
        count = count % lineCycles();
        rcnts[index].cycleStart = psxRegs.cycle - count;
    }
    else
        count = _psxRcntRcount( index );

    verboseLog( 2, "[RCNT 0] rcount: %04x m: %04x\n", count, rcnts[index].mode);

    return count;
}

u32 psxRcntRcount1()
{
    u32 index = 1;
    u32 count;

    count = _psxRcntRcount( index );

    verboseLog( 2, "[RCNT 1] rcount: %04x m: %04x\n", count, rcnts[index].mode);

    return count;
}

u32 psxRcntRcount2()
{
    u32 index = 2;
    u32 count;

    count = _psxRcntRcount( index );

    verboseLog( 2, "[RCNT 2] rcount: %04x m: %04x\n", count, rcnts[index].mode);

    return count;
}

u32 psxRcntRmode( u32 index )
{
    u16 mode;

    mode = rcnts[index].mode;
    rcnts[index].mode &= 0xe7ff;

    verboseLog( 2, "[RCNT %i] rmode: %x\n", index, mode );

    return mode;
}

u32 psxRcntRtarget( u32 index )
{
    verboseLog( 2, "[RCNT %i] rtarget: %x\n", index, rcnts[index].target );

    return rcnts[index].target;
}

/******************************************************************************/

void psxRcntInit()
{
    s32 i;

    // rcnt 0.
    rcnts[0].rate   = 1;
    rcnts[0].irq    = 0x10;

    // rcnt 1.
    rcnts[1].rate   = 1;
    rcnts[1].irq    = 0x20;

    // rcnt 2.
    rcnts[2].rate   = 1;
    rcnts[2].irq    = 0x40;

    // rcnt base.
    rcnts[3].rate   = 1;

    for( i = 0; i < CounterQuantity; ++i )
    {
        _psxRcntWcount( i, 0 );
    }

    hSyncCount = 0;
    hsync_steps = 1;

    scheduleRcntBase();
    psxRcntSet();
}

/******************************************************************************/

s32 psxRcntFreeze( void *f, s32 Mode )
{
    u32 spuSyncCount = 0;
    u32 count;
    s32 i;

    gzfreeze( &rcnts, sizeof(Rcnt) * CounterQuantity );
    gzfreeze( &hSyncCount, sizeof(hSyncCount) );
    gzfreeze( &spuSyncCount, sizeof(spuSyncCount) );
    gzfreeze( &psxNextCounter, sizeof(psxNextCounter) );
    gzfreeze( &psxNextsCounter, sizeof(psxNextsCounter) );

    if (Mode == 0)
    {
        rcnts[3].rate = 1;
        for( i = 0; i < CounterQuantity - 1; ++i )
        {
            _psxRcntWmode( i, rcnts[i].mode );
            count = (psxRegs.cycle - rcnts[i].cycleStart) / rcnts[i].rate;
            if (count > 0x1000)
                _psxRcntWcount( i, count & 0xffff );
        }
        scheduleRcntBase();
        psxRcntSet();
    }

    return 0;
}

/******************************************************************************/
// vim:ts=4:shiftwidth=4:expandtab
Commit	Line	Data
ef79bbde P	1	/***************************************************************************
	2	* Copyright (C) 2010 by Blade_Arma *
	3	* *
	4	* This program is free software; you can redistribute it and/or modify *
	5	* it under the terms of the GNU General Public License as published by *
	6	* the Free Software Foundation; either version 2 of the License, or *
	7	* (at your option) any later version. *
	8	* *
	9	* This program is distributed in the hope that it will be useful, *
	10	* but WITHOUT ANY WARRANTY; without even the implied warranty of *
	11	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
	12	* GNU General Public License for more details. *
	13	* *
	14	* You should have received a copy of the GNU General Public License *
	15	* along with this program; if not, write to the *
	16	* Free Software Foundation, Inc., *
	17	* 51 Franklin Street, Fifth Floor, Boston, MA 02111-1307 USA. *
	18	***************************************************************************/
	19
	20	/*
	21	* Internal PSX counters.
	22	*/
	23
	24	#include "psxcounters.h"
9a0a61d2	25	#include "psxevents.h"
ddbaf678	26	#include "gpu.h"
7d7672a5	27	//#include "debug.h"
7d7672a5	28	#define DebugVSync()
ef79bbde P	29
	30	/******************************************************************************/
	31
ef79bbde P	32	enum
ef79bbde P	33	{
11d23573	34	RcSyncModeEnable = 0x0001, // 0
	35	Rc01BlankPause = 0 << 1, // 1,2
	36	Rc01UnblankReset = 1 << 1, // 1,2
	37	Rc01UnblankReset2 = 2 << 1, // 1,2
	38	Rc2Stop = 0 << 1, // 1,2
	39	Rc2Stop2 = 3 << 1, // 1,2
ef79bbde P	40	RcCountToTarget = 0x0008, // 3
	41	RcIrqOnTarget = 0x0010, // 4
	42	RcIrqOnOverflow = 0x0020, // 5
	43	RcIrqRegenerate = 0x0040, // 6
	44	RcUnknown7 = 0x0080, // 7 ?
	45	Rc0PixelClock = 0x0100, // 8 fake implementation
	46	Rc1HSyncClock = 0x0100, // 8
	47	Rc2Unknown8 = 0x0100, // 8 ?
	48	Rc0Unknown9 = 0x0200, // 9 ?
	49	Rc1Unknown9 = 0x0200, // 9 ?
	50	Rc2OneEighthClock = 0x0200, // 9
	51	RcUnknown10 = 0x0400, // 10 ?
	52	RcCountEqTarget = 0x0800, // 11
	53	RcOverflow = 0x1000, // 12
	54	RcUnknown13 = 0x2000, // 13 ? (always zero)
	55	RcUnknown14 = 0x4000, // 14 ? (always zero)
	56	RcUnknown15 = 0x8000, // 15 ? (always zero)
	57	};
	58
	59	#define CounterQuantity ( 4 )
	60	//static const u32 CounterQuantity = 4;
	61
	62	static const u32 CountToOverflow = 0;
	63	static const u32 CountToTarget = 1;
	64
1351a8fb	65	static const u32 HSyncTotal[] = { 263, 314 };
1351a8fb	66	#define VBlankStart 240 // todo: depend on the actual GPU setting
ef79bbde	67
9f7ee52e	68	#define VERBOSE_LEVEL 0
ef79bbde P	69
ef79bbde P	70	/******************************************************************************/
41e82ad4	71	#ifdef DRC_DISABLE
b1be1eee	72	Rcnt rcnts[ CounterQuantity ];
41e82ad4	73	#endif
24de2dd4	74	u32 hSyncCount = 0;
24de2dd4	75	u32 frame_counter = 0;
61ef5cf4	76	static u32 hsync_steps = 0;
ef79bbde P	77
	78	u32 psxNextCounter = 0, psxNextsCounter = 0;
	79
	80	/******************************************************************************/
	81
4c8f1c25	82	#define FPS_FRACTIONAL_PAL (53203425/314./3406) // ~49.75
	83	#define FPS_FRACTIONAL_NTSC (53693175/263./3413) // ~59.81
	84
	85	static inline
	86	u32 frameCycles(void)
	87	{
	88	int ff = Config.FractionalFramerate >= 0
	89	? Config.FractionalFramerate : Config.hacks.fractional_Framerate;
	90	if (ff)
	91	{
	92	if (Config.PsxType)
	93	return (u32)(PSXCLK / FPS_FRACTIONAL_PAL);
	94	else
	95	return (u32)(PSXCLK / FPS_FRACTIONAL_NTSC);
	96	}
	97	return Config.PsxType ? (PSXCLK / 50) : (PSXCLK / 60);
	98	}
	99
	100	// used to inform the frontend about the exact framerate
	101	double psxGetFps()
	102	{
	103	int ff = Config.FractionalFramerate >= 0
	104	? Config.FractionalFramerate : Config.hacks.fractional_Framerate;
	105	if (ff)
	106	return Config.PsxType ? FPS_FRACTIONAL_PAL : FPS_FRACTIONAL_NTSC;
	107	else
	108	return Config.PsxType ? 50.0 : 60.0;
	109	}
	110
	111	// to inform the frontend about the exact famerate
1351a8fb	112	static inline
	113	u32 lineCycles(void)
	114	{
4c8f1c25	115	// should be more like above, but our timing is already poor anyway
1351a8fb	116	if (Config.PsxType)
	117	return PSXCLK / 50 / HSyncTotal[1];
	118	else
	119	return PSXCLK / 60 / HSyncTotal[0];
	120	}
	121
ef79bbde P	122	static inline
	123	void setIrq( u32 irq )
	124	{
	125	psxHu32ref(0x1070) \|= SWAPu32(irq);
	126	}
	127
	128	static
9f7ee52e	129	void verboseLog( u32 level, const char *str, ... )
ef79bbde	130	{
9f7ee52e	131	#if VERBOSE_LEVEL > 0
3cf51e08	132	if( level <= VERBOSE_LEVEL )
ef79bbde P	133	{
	134	va_list va;
	135	char buf[ 4096 ];
	136
	137	va_start( va, str );
	138	vsprintf( buf, str, va );
	139	va_end( va );
	140
ab948f7e	141	printf( "%s", buf );
ef79bbde P	142	fflush( stdout );
ef79bbde P	143	}
9f7ee52e	144	#endif
ef79bbde P	145	}
	146
	147	/******************************************************************************/
	148
	149	static inline
	150	void _psxRcntWcount( u32 index, u32 value )
	151	{
20bfbac0	152	value &= 0xffff;
ef79bbde P	153
	154	rcnts[index].cycleStart = psxRegs.cycle;
	155	rcnts[index].cycleStart -= value * rcnts[index].rate;
	156
	157	// TODO: <=.
	158	if( value < rcnts[index].target )
	159	{
	160	rcnts[index].cycle = rcnts[index].target * rcnts[index].rate;
	161	rcnts[index].counterState = CountToTarget;
	162	}
	163	else
	164	{
8ca6b0a6	165	rcnts[index].cycle = 0x10000 * rcnts[index].rate;
ef79bbde P	166	rcnts[index].counterState = CountToOverflow;
	167	}
	168	}
	169
	170	static inline
	171	u32 _psxRcntRcount( u32 index )
	172	{
	173	u32 count;
	174
	175	count = psxRegs.cycle;
	176	count -= rcnts[index].cycleStart;
61ef5cf4	177	if (rcnts[index].rate > 1)
61ef5cf4	178	count /= rcnts[index].rate;
ef79bbde	179
8ca6b0a6	180	if( count > 0x10000 )
ef79bbde	181	{
8ca6b0a6	182	verboseLog( 1, "[RCNT %i] rcount > 0x10000: %x\n", index, count );
ef79bbde	183	}
8ca6b0a6	184	count &= 0xffff;
ef79bbde P	185
	186	return count;
	187	}
	188
a29f182f	189	static
	190	void _psxRcntWmode( u32 index, u32 value )
	191	{
	192	rcnts[index].mode = value;
	193
	194	switch( index )
	195	{
	196	case 0:
	197	if( value & Rc0PixelClock )
	198	{
	199	rcnts[index].rate = 5;
	200	}
	201	else
	202	{
	203	rcnts[index].rate = 1;
	204	}
	205	break;
	206	case 1:
	207	if( value & Rc1HSyncClock )
	208	{
1351a8fb	209	rcnts[index].rate = lineCycles();
a29f182f	210	}
	211	else
	212	{
	213	rcnts[index].rate = 1;
	214	}
	215	break;
	216	case 2:
	217	if( value & Rc2OneEighthClock )
	218	{
	219	rcnts[index].rate = 8;
	220	}
	221	else
	222	{
	223	rcnts[index].rate = 1;
	224	}
	225
	226	// TODO: wcount must work.
11d23573	227	if( (value & 7) == (RcSyncModeEnable \| Rc2Stop) \|\|
11d23573	228	(value & 7) == (RcSyncModeEnable \| Rc2Stop2) )
a29f182f	229	{
	230	rcnts[index].rate = 0xffffffff;
	231	}
	232	break;
	233	}
	234	}
	235
ef79bbde P	236	/******************************************************************************/
	237
	238	static
	239	void psxRcntSet()
	240	{
	241	s32 countToUpdate;
	242	u32 i;
	243
	244	psxNextsCounter = psxRegs.cycle;
	245	psxNextCounter = 0x7fffffff;
	246
	247	for( i = 0; i < CounterQuantity; ++i )
	248	{
	249	countToUpdate = rcnts[i].cycle - (psxNextsCounter - rcnts[i].cycleStart);
	250
	251	if( countToUpdate < 0 )
	252	{
	253	psxNextCounter = 0;
	254	break;
	255	}
	256
	257	if( countToUpdate < (s32)psxNextCounter )
	258	{
	259	psxNextCounter = countToUpdate;
	260	}
	261	}
5b8c000f	262
9a0a61d2	263	set_event(PSXINT_RCNT, psxNextCounter);
ef79bbde P	264	}
	265
	266	/******************************************************************************/
	267
	268	static
	269	void psxRcntReset( u32 index )
	270	{
8ca6b0a6	271	u32 rcycles;
ef79bbde	272
53c361f0	273	rcnts[index].mode \|= RcUnknown10;
53c361f0	274
ef79bbde P	275	if( rcnts[index].counterState == CountToTarget )
ef79bbde P	276	{
8ca6b0a6	277	rcycles = psxRegs.cycle - rcnts[index].cycleStart;
ef79bbde	278	if( rcnts[index].mode & RcCountToTarget )
8ca6b0a6	279	{
	280	rcycles -= rcnts[index].target * rcnts[index].rate;
	281	rcnts[index].cycleStart = psxRegs.cycle - rcycles;
	282	}
	283	else
	284	{
	285	rcnts[index].cycle = 0x10000 * rcnts[index].rate;
	286	rcnts[index].counterState = CountToOverflow;
	287	}
ef79bbde P	288
	289	if( rcnts[index].mode & RcIrqOnTarget )
	290	{
	291	if( (rcnts[index].mode & RcIrqRegenerate) \|\| (!rcnts[index].irqState) )
	292	{
8ca6b0a6	293	verboseLog( 3, "[RCNT %i] irq\n", index );
ef79bbde P	294	setIrq( rcnts[index].irq );
	295	rcnts[index].irqState = 1;
	296	}
	297	}
	298
	299	rcnts[index].mode \|= RcCountEqTarget;
53c361f0	300
8ca6b0a6	301	if( rcycles < 0x10000 * rcnts[index].rate )
53c361f0	302	return;
ef79bbde	303	}
53c361f0	304
53c361f0	305	if( rcnts[index].counterState == CountToOverflow )
ef79bbde	306	{
8ca6b0a6	307	rcycles = psxRegs.cycle - rcnts[index].cycleStart;
	308	rcycles -= 0x10000 * rcnts[index].rate;
	309
	310	rcnts[index].cycleStart = psxRegs.cycle - rcycles;
ef79bbde	311
8ca6b0a6	312	if( rcycles < rcnts[index].target * rcnts[index].rate )
	313	{
	314	rcnts[index].cycle = rcnts[index].target * rcnts[index].rate;
	315	rcnts[index].counterState = CountToTarget;
	316	}
ef79bbde P	317
	318	if( rcnts[index].mode & RcIrqOnOverflow )
	319	{
	320	if( (rcnts[index].mode & RcIrqRegenerate) \|\| (!rcnts[index].irqState) )
	321	{
8ca6b0a6	322	verboseLog( 3, "[RCNT %i] irq\n", index );
ef79bbde P	323	setIrq( rcnts[index].irq );
	324	rcnts[index].irqState = 1;
	325	}
	326	}
	327
	328	rcnts[index].mode \|= RcOverflow;
	329	}
ef79bbde P	330	}
ef79bbde P	331
ff2c2822	332	static void scheduleRcntBase(void)
	333	{
	334	// Schedule next call, in hsyncs
	335	if (hSyncCount < VBlankStart)
	336	hsync_steps = VBlankStart - hSyncCount;
	337	else
	338	hsync_steps = HSyncTotal[Config.PsxType] - hSyncCount;
	339
	340	if (hSyncCount + hsync_steps == HSyncTotal[Config.PsxType])
	341	{
4c8f1c25	342	rcnts[3].cycle = frameCycles();
ff2c2822	343	}
	344	else
	345	{
	346	// clk / 50 / 314 ~= 2157.25
	347	// clk / 60 / 263 ~= 2146.31
	348	u32 mult = Config.PsxType ? 8836089 : 8791293;
	349	rcnts[3].cycle = hsync_steps * mult >> 12;
	350	}
	351	}
	352
ef79bbde P	353	void psxRcntUpdate()
ef79bbde P	354	{
11d23573	355	u32 cycle, cycles_passed;
ef79bbde P	356
	357	cycle = psxRegs.cycle;
	358
	359	// rcnt 0.
11d23573	360	cycles_passed = cycle - rcnts[0].cycleStart;
11d23573	361	while( cycles_passed >= rcnts[0].cycle )
ef79bbde	362	{
11d23573	363	if (((rcnts[0].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset) \|\|
11d23573	364	(rcnts[0].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset2))
1351a8fb	365	&& cycles_passed > lineCycles())
11d23573	366	{
1351a8fb	367	u32 q = cycles_passed / (lineCycles() + 1u);
1351a8fb	368	rcnts[0].cycleStart += q * lineCycles();
11d23573	369	break;
	370	}
	371	else
	372	psxRcntReset( 0 );
	373
	374	cycles_passed = cycle - rcnts[0].cycleStart;
ef79bbde P	375	}
	376
	377	// rcnt 1.
e7851504	378	while( cycle - rcnts[1].cycleStart >= rcnts[1].cycle )
ef79bbde P	379	{
	380	psxRcntReset( 1 );
	381	}
	382
	383	// rcnt 2.
e7851504	384	while( cycle - rcnts[2].cycleStart >= rcnts[2].cycle )
ef79bbde P	385	{
	386	psxRcntReset( 2 );
	387	}
	388
	389	// rcnt base.
	390	if( cycle - rcnts[3].cycleStart >= rcnts[3].cycle )
	391	{
61ef5cf4	392	hSyncCount += hsync_steps;
ef79bbde	393
ef79bbde	394	// VSync irq.
0486fdc9	395	if( hSyncCount == VBlankStart )
ef79bbde	396	{
086adfff	397	HW_GPU_STATUS &= SWAP32(~PSXGPU_LCF);
72e5023f	398	GPU_vBlank( 1, 0 );
8bbbd091	399	setIrq( 0x01 );
	400
	401	EmuUpdate();
	402	GPU_updateLace();
d618a240	403
	404	if( SPU_async )
	405	{
	406	SPU_async( cycle, 1 );
	407	}
ef79bbde P	408	}
ef79bbde P	409
d014a471	410	// Update lace.
d014a471	411	if( hSyncCount >= HSyncTotal[Config.PsxType] )
ef79bbde	412	{
1351a8fb	413	u32 status, field = 0;
4c8f1c25	414	rcnts[3].cycleStart += frameCycles();
ef79bbde	415	hSyncCount = 0;
ddbaf678	416	frame_counter++;
ef79bbde	417
0486fdc9	418	gpuSyncPluginSR();
db57cbb8	419	status = SWAP32(HW_GPU_STATUS) \| PSXGPU_FIELD;
	420	if ((status & PSXGPU_ILACE_BITS) == PSXGPU_ILACE_BITS) {
	421	field = frame_counter & 1;
	422	status \|= field << 31;
	423	status ^= field << 13;
	424	}
	425	HW_GPU_STATUS = SWAP32(status);
	426	GPU_vBlank(0, field);
f8896d18	427	if ((s32)(psxRegs.gpuIdleAfter - psxRegs.cycle) < 0)
f8896d18	428	psxRegs.gpuIdleAfter = psxRegs.cycle - 1; // prevent overflow
11d23573	429
1351a8fb	430	if ((rcnts[0].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset) \|\|
	431	(rcnts[0].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset2))
	432	{
	433	rcnts[0].cycleStart = rcnts[3].cycleStart;
	434	}
	435
	436	if ((rcnts[1].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset) \|\|
	437	(rcnts[1].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset2))
	438	{
	439	rcnts[1].cycleStart = rcnts[3].cycleStart;
	440	}
	441	else if (rcnts[1].mode & Rc1HSyncClock)
11d23573	442	{
1351a8fb	443	// adjust to remove the rounding error
1351a8fb	444	_psxRcntWcount(1, (psxRegs.cycle - rcnts[1].cycleStart) / rcnts[1].rate);
11d23573	445	}
ef79bbde	446	}
61ef5cf4	447
ff2c2822	448	scheduleRcntBase();
ef79bbde P	449	}
ef79bbde P	450
95df1a04	451	psxRcntSet();
95df1a04	452
7a8d521f	453	#if 0 //ndef NDEBUG
ef79bbde	454	DebugVSync();
61ef5cf4	455	#endif
ef79bbde P	456	}
	457
	458	/******************************************************************************/
	459
	460	void psxRcntWcount( u32 index, u32 value )
	461	{
	462	verboseLog( 2, "[RCNT %i] wcount: %x\n", index, value );
	463
ef79bbde P	464	_psxRcntWcount( index, value );
	465	psxRcntSet();
	466	}
	467
	468	void psxRcntWmode( u32 index, u32 value )
	469	{
	470	verboseLog( 1, "[RCNT %i] wmode: %x\n", index, value );
	471
a29f182f	472	_psxRcntWmode( index, value );
ef79bbde	473	_psxRcntWcount( index, 0 );
a29f182f	474
a29f182f	475	rcnts[index].irqState = 0;
ef79bbde P	476	psxRcntSet();
	477	}
	478
	479	void psxRcntWtarget( u32 index, u32 value )
	480	{
	481	verboseLog( 1, "[RCNT %i] wtarget: %x\n", index, value );
	482
ef79bbde P	483	rcnts[index].target = value;
	484
	485	_psxRcntWcount( index, _psxRcntRcount( index ) );
	486	psxRcntSet();
	487	}
	488
	489	/******************************************************************************/
	490
11d23573	491	u32 psxRcntRcount0()
	492	{
	493	u32 index = 0;
	494	u32 count;
	495
	496	if ((rcnts[0].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset) \|\|
	497	(rcnts[0].mode & 7) == (RcSyncModeEnable \| Rc01UnblankReset2))
	498	{
	499	count = psxRegs.cycle - rcnts[index].cycleStart;
1351a8fb	500	//count = ((16u * count) % (16u * PSXCLK / 60 / 263)) / 16u;
1351a8fb	501	count = count % lineCycles();
11d23573	502	rcnts[index].cycleStart = psxRegs.cycle - count;
	503	}
	504	else
	505	count = _psxRcntRcount( index );
	506
	507	verboseLog( 2, "[RCNT 0] rcount: %04x m: %04x\n", count, rcnts[index].mode);
	508
	509	return count;
	510	}
	511
	512	u32 psxRcntRcount1()
	513	{
	514	u32 index = 1;
	515	u32 count;
	516
	517	count = _psxRcntRcount( index );
	518
	519	verboseLog( 2, "[RCNT 1] rcount: %04x m: %04x\n", count, rcnts[index].mode);
	520
	521	return count;
	522	}
	523
	524	u32 psxRcntRcount2()
ef79bbde	525	{
11d23573	526	u32 index = 2;
ef79bbde P	527	u32 count;
ef79bbde P	528
ef79bbde P	529	count = _psxRcntRcount( index );
ef79bbde P	530
11d23573	531	verboseLog( 2, "[RCNT 2] rcount: %04x m: %04x\n", count, rcnts[index].mode);
ef79bbde P	532
	533	return count;
	534	}
	535
	536	u32 psxRcntRmode( u32 index )
	537	{
	538	u16 mode;
	539
ef79bbde P	540	mode = rcnts[index].mode;
	541	rcnts[index].mode &= 0xe7ff;
	542
	543	verboseLog( 2, "[RCNT %i] rmode: %x\n", index, mode );
	544
	545	return mode;
	546	}
	547
	548	u32 psxRcntRtarget( u32 index )
	549	{
	550	verboseLog( 2, "[RCNT %i] rtarget: %x\n", index, rcnts[index].target );
	551
	552	return rcnts[index].target;
	553	}
	554
	555	/******************************************************************************/
	556
	557	void psxRcntInit()
	558	{
	559	s32 i;
	560
	561	// rcnt 0.
	562	rcnts[0].rate = 1;
	563	rcnts[0].irq = 0x10;
	564
	565	// rcnt 1.
	566	rcnts[1].rate = 1;
	567	rcnts[1].irq = 0x20;
	568
	569	// rcnt 2.
	570	rcnts[2].rate = 1;
	571	rcnts[2].irq = 0x40;
	572
	573	// rcnt base.
	574	rcnts[3].rate = 1;
ef79bbde P	575
	576	for( i = 0; i < CounterQuantity; ++i )
	577	{
	578	_psxRcntWcount( i, 0 );
	579	}
	580
c62b43c9	581	hSyncCount = 0;
61ef5cf4	582	hsync_steps = 1;
c62b43c9	583
1351a8fb	584	scheduleRcntBase();
ef79bbde P	585	psxRcntSet();
	586	}
	587
	588	/******************************************************************************/
	589
496d88d4	590	s32 psxRcntFreeze( void *f, s32 Mode )
ef79bbde	591	{
d618a240	592	u32 spuSyncCount = 0;
d0af6d75	593	u32 count;
a29f182f	594	s32 i;
a29f182f	595
41e82ad4	596	gzfreeze( &rcnts, sizeof(Rcnt) * CounterQuantity );
ef79bbde P	597	gzfreeze( &hSyncCount, sizeof(hSyncCount) );
	598	gzfreeze( &spuSyncCount, sizeof(spuSyncCount) );
	599	gzfreeze( &psxNextCounter, sizeof(psxNextCounter) );
	600	gzfreeze( &psxNextsCounter, sizeof(psxNextsCounter) );
	601
61ef5cf4	602	if (Mode == 0)
a29f182f	603	{
e43c9382	604	rcnts[3].rate = 1;
b34d6a80	605	for( i = 0; i < CounterQuantity - 1; ++i )
d0af6d75	606	{
a29f182f	607	_psxRcntWmode( i, rcnts[i].mode );
d0af6d75	608	count = (psxRegs.cycle - rcnts[i].cycleStart) / rcnts[i].rate;
	609	if (count > 0x1000)
	610	_psxRcntWcount( i, count & 0xffff );
	611	}
ff2c2822	612	scheduleRcntBase();
a29f182f	613	psxRcntSet();
a29f182f	614	}
4f55097d	615
ef79bbde P	616	return 0;
	617	}
	618
	619	/******************************************************************************/
ff2c2822	620	// vim:ts=4:shiftwidth=4:expandtab