/**

  * $Id$

  *

  * PVR2 (Video) Core module implementation and MMIO registers.

  *

  * Copyright (c) 2005 Nathan Keynes.

  *

  * 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.

  */

 #define MODULE pvr2_module

 #include <assert.h>

 #include "dream.h"

 #include "eventq.h"

 #include "display.h"

 #include "mem.h"

 #include "asic.h"

 #include "clock.h"

 #include "pvr2/pvr2.h"

 #include "pvr2/pvr2mmio.h"

 #include "pvr2/scene.h"

 #include "sh4/sh4.h"

 #define MMIO_IMPL

 #include "pvr2/pvr2mmio.h"

 unsigned char *video_base;

 #define MAX_RENDER_BUFFERS 4

 #define HPOS_PER_FRAME 0

 #define HPOS_PER_LINECOUNT 1

 static void pvr2_init( void );

 static void pvr2_reset( void );

 static uint32_t pvr2_run_slice( uint32_t );

 static void pvr2_save_state( FILE *f );

 static int pvr2_load_state( FILE *f );

 static void pvr2_update_raster_posn( uint32_t nanosecs );

 static void pvr2_schedule_scanline_event( int eventid, int line, int minimum_lines, int line_time_ns );

 static render_buffer_t pvr2_get_render_buffer( frame_buffer_t frame );

 static render_buffer_t pvr2_next_render_buffer( );

 static render_buffer_t pvr2_frame_buffer_to_render_buffer( frame_buffer_t frame );

 uint32_t pvr2_get_sync_status();

 void pvr2_display_frame( void );

 static int output_colour_formats[] = { COLFMT_BGRA1555, COLFMT_RGB565, COLFMT_BGR888, COLFMT_BGRA8888 };

 struct dreamcast_module pvr2_module = { "PVR2", pvr2_init, pvr2_reset, NULL, 

 					pvr2_run_slice, NULL,

 					pvr2_save_state, pvr2_load_state };

 display_driver_t display_driver = NULL;

 struct pvr2_state {

     uint32_t frame_count;

     uint32_t line_count;

     uint32_t line_remainder;

     uint32_t cycles_run; /* Cycles already executed prior to main time slice */

     uint32_t irq_hpos_line;

     uint32_t irq_hpos_line_count;

     uint32_t irq_hpos_mode;

     uint32_t irq_hpos_time_ns; /* Time within the line */

     uint32_t irq_vpos1;

     uint32_t irq_vpos2;

     uint32_t odd_even_field; /* 1 = odd, 0 = even */

     int32_t palette_changed; /* TRUE if palette has changed since last render */

     uint32_t padding; /* FIXME: Remove in next DST version */

     /* timing */

     uint32_t dot_clock;

     uint32_t total_lines;

     uint32_t line_size;

     uint32_t line_time_ns;

     uint32_t vsync_lines;

     uint32_t hsync_width_ns;

     uint32_t front_porch_ns;

     uint32_t back_porch_ns;

     uint32_t retrace_start_line;

     uint32_t retrace_end_line;

     int32_t interlaced;

 } pvr2_state;

 static gchar *save_next_render_filename;

 static render_buffer_t render_buffers[MAX_RENDER_BUFFERS];

 static uint32_t render_buffer_count = 0;

 static render_buffer_t displayed_render_buffer = NULL;

 static uint32_t displayed_border_colour = 0;

 /**

  * Event handler for the hpos callback

  */

 static void pvr2_hpos_callback( int eventid ) {

     asic_event( eventid );

     pvr2_update_raster_posn(sh4r.slice_cycle);

     if( pvr2_state.irq_hpos_mode == HPOS_PER_LINECOUNT ) {

 	pvr2_state.irq_hpos_line += pvr2_state.irq_hpos_line_count;

 	while( pvr2_state.irq_hpos_line > (pvr2_state.total_lines>>1) ) {

 	    pvr2_state.irq_hpos_line -= (pvr2_state.total_lines>>1);

 	}

     }

     pvr2_schedule_scanline_event( eventid, pvr2_state.irq_hpos_line, 1, 

 				  pvr2_state.irq_hpos_time_ns );

 }

 /**

  * Event handler for the scanline callbacks. Fires the corresponding

  * ASIC event, and resets the timer for the next field.

  */

 static void pvr2_scanline_callback( int eventid ) {

     asic_event( eventid );

     pvr2_update_raster_posn(sh4r.slice_cycle);

     if( eventid == EVENT_SCANLINE1 ) {

 	pvr2_schedule_scanline_event( eventid, pvr2_state.irq_vpos1, 1, 0 );

     } else {

 	pvr2_schedule_scanline_event( eventid, pvr2_state.irq_vpos2, 1, 0 );

     }

 }

 static void pvr2_init( void )

 {

     int i;

     register_io_region( &mmio_region_PVR2 );

     register_io_region( &mmio_region_PVR2PAL );

     register_io_region( &mmio_region_PVR2TA );

     register_event_callback( EVENT_HPOS, pvr2_hpos_callback );

     register_event_callback( EVENT_SCANLINE1, pvr2_scanline_callback );

     register_event_callback( EVENT_SCANLINE2, pvr2_scanline_callback );

     video_base = mem_get_region_by_name( MEM_REGION_VIDEO );

     texcache_init();

     pvr2_reset();

     pvr2_ta_reset();

     save_next_render_filename = NULL;

     for( i=0; i<MAX_RENDER_BUFFERS; i++ ) {

 	render_buffers[i] = NULL;

     }

     render_buffer_count = 0;

     displayed_render_buffer = NULL;

     displayed_border_colour = 0;

 }

 static void pvr2_reset( void )

 {

     int i;

     pvr2_state.line_count = 0;

     pvr2_state.line_remainder = 0;

     pvr2_state.cycles_run = 0;

     pvr2_state.irq_vpos1 = 0;

     pvr2_state.irq_vpos2 = 0;

     pvr2_state.dot_clock = PVR2_DOT_CLOCK;

     pvr2_state.back_porch_ns = 4000;

     pvr2_state.palette_changed = FALSE;

     mmio_region_PVR2_write( DISP_TOTAL, 0x0270035F );

     mmio_region_PVR2_write( DISP_SYNCTIME, 0x07D6A53F );

     mmio_region_PVR2_write( YUV_ADDR, 0 );

     mmio_region_PVR2_write( YUV_CFG, 0 );

     pvr2_ta_init();

     texcache_flush();

     if( display_driver ) {

 	display_driver->display_blank(0);

 	for( i=0; i<render_buffer_count; i++ ) {

 	    display_driver->destroy_render_buffer(render_buffers[i]);

 	    render_buffers[i] = NULL;

 	}

 	render_buffer_count = 0;

     }

 }

 void pvr2_save_render_buffer( FILE *f, render_buffer_t buffer )

 {

     struct frame_buffer fbuf;

     fbuf.width = buffer->width;

     fbuf.height = buffer->height;

     fbuf.rowstride = fbuf.width*3;

     fbuf.colour_format = COLFMT_BGR888;

     fbuf.inverted = buffer->inverted;

     fbuf.data = g_malloc0( buffer->width * buffer->height * 3 );

     display_driver->read_render_buffer( fbuf.data, buffer, fbuf.rowstride, COLFMT_BGR888 );

     write_png_to_stream( f, &fbuf );

     g_free( fbuf.data );

     fwrite( &buffer->rowstride, sizeof(buffer->rowstride), 1, f );

     fwrite( &buffer->colour_format, sizeof(buffer->colour_format), 1, f );

     fwrite( &buffer->address, sizeof(buffer->address), 1, f );

     fwrite( &buffer->scale, sizeof(buffer->scale), 1, f );

     int32_t flushed = (int32_t)buffer->flushed; // Force to 32-bits for save-file consistency

     fwrite( &flushed, sizeof(flushed), 1, f );

 }

 render_buffer_t pvr2_load_render_buffer( FILE *f )

 {

     frame_buffer_t frame = read_png_from_stream( f );

     if( frame == NULL ) {

 	return NULL;

     }

     render_buffer_t buffer = pvr2_frame_buffer_to_render_buffer(frame);

     if( buffer != NULL ) {

         int32_t flushed;

 	fread( &buffer->rowstride, sizeof(buffer->rowstride), 1, f );

 	fread( &buffer->colour_format, sizeof(buffer->colour_format), 1, f );

 	fread( &buffer->address, sizeof(buffer->address), 1, f );

 	fread( &buffer->scale, sizeof(buffer->scale), 1, f );

 	fread( &flushed, sizeof(flushed), 1, f );

 	buffer->flushed = (gboolean)flushed;

     } else {

 	fseek( f, sizeof(buffer->rowstride)+sizeof(buffer->colour_format)+

 	       sizeof(buffer->address)+sizeof(buffer->scale)+

 	       sizeof(int32_t), SEEK_CUR );

     }

     return buffer;

 }

 void pvr2_save_render_buffers( FILE *f )

 {

     int i;

     uint32_t has_frontbuffer;

     fwrite( &render_buffer_count, sizeof(render_buffer_count), 1, f );

     if( displayed_render_buffer != NULL ) {

 	has_frontbuffer = 1;

 	fwrite( &has_frontbuffer, sizeof(has_frontbuffer), 1, f );

 	pvr2_save_render_buffer( f, displayed_render_buffer );

     } else {

 	has_frontbuffer = 0;

 	fwrite( &has_frontbuffer, sizeof(has_frontbuffer), 1, f );

     }

     for( i=0; i<render_buffer_count; i++ ) {

 	if( render_buffers[i] != displayed_render_buffer && render_buffers[i] != NULL ) {

 	    pvr2_save_render_buffer( f, render_buffers[i] );

 	}

     }

 }

 gboolean pvr2_load_render_buffers( FILE *f )

 {

     uint32_t count, has_frontbuffer;

     int i;

     fread( &count, sizeof(count), 1, f );

     if( count > MAX_RENDER_BUFFERS ) {

 	return FALSE;

     }

     fread( &has_frontbuffer, sizeof(has_frontbuffer), 1, f );

     for( i=0; i<render_buffer_count; i++ ) {

 	display_driver->destroy_render_buffer(render_buffers[i]);

 	render_buffers[i] = NULL;

     }

     render_buffer_count = 0;

     if( has_frontbuffer ) {

 	displayed_render_buffer = pvr2_load_render_buffer(f);

 	display_driver->display_render_buffer( displayed_render_buffer );

 	count--;

     }

     for( i=0; i<count; i++ ) {

 	pvr2_load_render_buffer( f );

     }

     return TRUE;

 }

 static void pvr2_save_state( FILE *f )

 {

     pvr2_save_render_buffers( f );

     fwrite( &pvr2_state, sizeof(pvr2_state), 1, f );

     pvr2_ta_save_state( f );

     pvr2_yuv_save_state( f );

 }

 static int pvr2_load_state( FILE *f )

 {

     if( !pvr2_load_render_buffers(f) )

 	return 1;

     if( fread( &pvr2_state, sizeof(pvr2_state), 1, f ) != 1 )

 	return 1;

     if( pvr2_ta_load_state(f) ) {

 	return 1;

     }

     return pvr2_yuv_load_state(f);

 }

 /**

  * Update the current raster position to the given number of nanoseconds,

  * relative to the last time slice. (ie the raster will be adjusted forward

  * by nanosecs - nanosecs_already_run_this_timeslice)

  */

 static void pvr2_update_raster_posn( uint32_t nanosecs )

 {

     uint32_t old_line_count = pvr2_state.line_count;

     if( pvr2_state.line_time_ns == 0 ) {

 	return; /* do nothing */

     }

     pvr2_state.line_remainder += (nanosecs - pvr2_state.cycles_run);

     pvr2_state.cycles_run = nanosecs;

     while( pvr2_state.line_remainder >= pvr2_state.line_time_ns ) {

 	pvr2_state.line_count ++;

 	pvr2_state.line_remainder -= pvr2_state.line_time_ns;

     }

     if( pvr2_state.line_count >= pvr2_state.total_lines ) {

 	pvr2_state.line_count -= pvr2_state.total_lines;

 	if( pvr2_state.interlaced ) {

 	    pvr2_state.odd_even_field = !pvr2_state.odd_even_field;

 	}

     }

     if( pvr2_state.line_count >= pvr2_state.retrace_end_line &&

 	(old_line_count < pvr2_state.retrace_end_line ||

 	 old_line_count > pvr2_state.line_count) ) {

 	pvr2_state.frame_count++;

 	pvr2_display_frame();

     }

 }

 static uint32_t pvr2_run_slice( uint32_t nanosecs ) 

 {

     pvr2_update_raster_posn( nanosecs );

     pvr2_state.cycles_run = 0;

     return nanosecs;

 }

 int pvr2_get_frame_count() 

 {

     return pvr2_state.frame_count;

 }

 void pvr2_redraw_display()

 {

     if( display_driver != NULL ) {

         if( displayed_render_buffer == NULL ) {

             display_driver->display_blank(displayed_border_colour);

         } else {

             display_driver->display_render_buffer(displayed_render_buffer);

         }

     }

 }

 gboolean pvr2_save_next_scene( const gchar *filename )

 {

     if( save_next_render_filename != NULL ) {

 	g_free( save_next_render_filename );

     } 

     save_next_render_filename = g_strdup(filename);

     return TRUE;

 }

 /**

  * Display the next frame, copying the current contents of video ram to

  * the window. If the video configuration has changed, first recompute the

  * new frame size/depth.

  */

 void pvr2_display_frame( void )

 {

     int dispmode = MMIO_READ( PVR2, DISP_MODE );

     int vidcfg = MMIO_READ( PVR2, DISP_SYNCCFG );

     gboolean bEnabled = (dispmode & DISPMODE_ENABLE) && (vidcfg & DISPCFG_VO ) ? TRUE : FALSE;

     if( display_driver == NULL ) {

 	return; /* can't really do anything much */

     } else if( !bEnabled ) {

 	/* Output disabled == black */

 	displayed_render_buffer = NULL;

 	displayed_border_colour = 0;

 	display_driver->display_blank( 0 ); 

     } else if( MMIO_READ( PVR2, DISP_CFG2 ) & 0x08 ) { 

 	/* Enabled but blanked - border colour */

 	displayed_border_colour = MMIO_READ( PVR2, DISP_BORDER );

 	displayed_render_buffer = NULL;

 	display_driver->display_blank( displayed_border_colour );

     } else {

 	/* Real output - determine dimensions etc */

 	struct frame_buffer fbuf;

 	uint32_t dispsize = MMIO_READ( PVR2, DISP_SIZE );

 	int vid_stride = (((dispsize & DISPSIZE_MODULO) >> 20) - 1);

 	int vid_ppl = ((dispsize & DISPSIZE_PPL)) + 1;

 	fbuf.colour_format = output_colour_formats[(dispmode & DISPMODE_COLFMT) >> 2];

 	fbuf.width = vid_ppl << 2 / colour_formats[fbuf.colour_format].bpp;

 	fbuf.height = ((dispsize & DISPSIZE_LPF) >> 10) + 1;

 	fbuf.size = vid_ppl << 2 * fbuf.height;

 	fbuf.rowstride = (vid_ppl + vid_stride) << 2;

 	/* Determine the field to display, and deinterlace if possible */

 	if( pvr2_state.interlaced ) {

 	    if( vid_ppl == vid_stride ) { /* Magic deinterlace */

 		fbuf.height = fbuf.height << 1;

 		fbuf.rowstride = vid_ppl << 2;

 		fbuf.address = MMIO_READ( PVR2, DISP_ADDR1 );

 	    } else { 

 		/* Just display the field as is, folks. This is slightly tricky -

 		 * we pick the field based on which frame is about to come through,

 		 * which may not be the same as the odd_even_field.

 		 */

 		gboolean oddfield = pvr2_state.odd_even_field;

 		if( pvr2_state.line_count >= pvr2_state.retrace_start_line ) {

 		    oddfield = !oddfield;

 		}

 		if( oddfield ) {

 		    fbuf.address = MMIO_READ( PVR2, DISP_ADDR1 );

 		} else {

 		    fbuf.address = MMIO_READ( PVR2, DISP_ADDR2 );

 		}

 	    }

 	} else {

 	    fbuf.address = MMIO_READ( PVR2, DISP_ADDR1 );

 	}

 	fbuf.address = (fbuf.address & 0x00FFFFFF) + PVR2_RAM_BASE;

 	fbuf.inverted = FALSE;

 	fbuf.data = video_base + (fbuf.address&0x00FFFFFF);

 	render_buffer_t rbuf = pvr2_get_render_buffer( &fbuf );

 	if( rbuf == NULL ) {

 	    rbuf = pvr2_frame_buffer_to_render_buffer( &fbuf );

 	}

 	displayed_render_buffer = rbuf;

 	if( rbuf != NULL ) {

 	    display_driver->display_render_buffer( rbuf );

 	}

     }

 }

 /**

  * This has to handle every single register individually as they all get masked 

  * off differently (and its easier to do it at write time)

  */

 void mmio_region_PVR2_write( uint32_t reg, uint32_t val )

 {

     if( reg >= 0x200 && reg < 0x600 ) { /* Fog table */

         MMIO_WRITE( PVR2, reg, val );

         return;

     }

     switch(reg) {

     case PVRID:

     case PVRVER:

     case GUNPOS: /* Read only registers */

 	break;

     case PVRRESET:

 	val &= 0x00000007; /* Do stuff? */

 	MMIO_WRITE( PVR2, reg, val );

 	break;

     case RENDER_START: /* Don't really care what value */

 	if( save_next_render_filename != NULL ) {

 	    if( pvr2_render_save_scene(save_next_render_filename) == 0 ) {

 		INFO( "Saved scene to %s", save_next_render_filename);

 	    }

 	    g_free( save_next_render_filename );

 	    save_next_render_filename = NULL;

 	}

 	pvr2_scene_read();

 	render_buffer_t buffer = pvr2_next_render_buffer();

 	if( buffer != NULL ) {

 	    pvr2_scene_render( buffer );

 	}

 	asic_event( EVENT_PVR_RENDER_DONE );

 	break;

     case RENDER_POLYBASE:

     	MMIO_WRITE( PVR2, reg, val&0x00F00000 );

     	break;

     case RENDER_TSPCFG:

     	MMIO_WRITE( PVR2, reg, val&0x00010101 );

     	break;

     case DISP_BORDER:

     	MMIO_WRITE( PVR2, reg, val&0x01FFFFFF );

     	break;

     case DISP_MODE:

     	MMIO_WRITE( PVR2, reg, val&0x00FFFF7F );

     	break;

     case RENDER_MODE:

     	MMIO_WRITE( PVR2, reg, val&0x00FFFF0F );

     	break;

     case RENDER_SIZE:

     	MMIO_WRITE( PVR2, reg, val&0x000001FF );

     	break;

     case DISP_ADDR1:

 	val &= 0x00FFFFFC;

 	MMIO_WRITE( PVR2, reg, val );

 	pvr2_update_raster_posn(sh4r.slice_cycle);

 	break;

     case DISP_ADDR2:

     	MMIO_WRITE( PVR2, reg, val&0x00FFFFFC );

 	pvr2_update_raster_posn(sh4r.slice_cycle);

     	break;

     case DISP_SIZE:

     	MMIO_WRITE( PVR2, reg, val&0x3FFFFFFF );

     	break;

     case RENDER_ADDR1:

     case RENDER_ADDR2:

     	MMIO_WRITE( PVR2, reg, val&0x01FFFFFC );

     	break;

     case RENDER_HCLIP:

 	MMIO_WRITE( PVR2, reg, val&0x07FF07FF );

 	break;

     case RENDER_VCLIP:

 	MMIO_WRITE( PVR2, reg, val&0x03FF03FF );

 	break;

     case DISP_HPOSIRQ:

 	MMIO_WRITE( PVR2, reg, val&0x03FF33FF );

 	pvr2_state.irq_hpos_line = val & 0x03FF;

 	pvr2_state.irq_hpos_time_ns = 2000000*((val>>16)&0x03FF)/pvr2_state.dot_clock;

 	pvr2_state.irq_hpos_mode = (val >> 12) & 0x03;

 	switch( pvr2_state.irq_hpos_mode ) {

 	case 3: /* Reserved - treat as 0 */

 	case 0: /* Once per frame at specified line */

 	    pvr2_state.irq_hpos_mode = HPOS_PER_FRAME;

 	    break;

 	case 2: /* Once per line - as per-line-count */

 	    pvr2_state.irq_hpos_line = 1;

 	    pvr2_state.irq_hpos_mode = 1;

 	case 1: /* Once per N lines */

 	    pvr2_state.irq_hpos_line_count = pvr2_state.irq_hpos_line;

 	    pvr2_state.irq_hpos_line = (pvr2_state.line_count >> 1) + 

 		pvr2_state.irq_hpos_line_count;

 	    while( pvr2_state.irq_hpos_line > (pvr2_state.total_lines>>1) ) {

 		pvr2_state.irq_hpos_line -= (pvr2_state.total_lines>>1);

 	    }

 	    pvr2_state.irq_hpos_mode = HPOS_PER_LINECOUNT;

 	}

 	pvr2_schedule_scanline_event( EVENT_HPOS, pvr2_state.irq_hpos_line, 0,

 					  pvr2_state.irq_hpos_time_ns );

 	break;

     case DISP_VPOSIRQ:

 	val = val & 0x03FF03FF;

 	pvr2_state.irq_vpos1 = (val >> 16);

 	pvr2_state.irq_vpos2 = val & 0x03FF;

 	pvr2_update_raster_posn(sh4r.slice_cycle);

 	pvr2_schedule_scanline_event( EVENT_SCANLINE1, pvr2_state.irq_vpos1, 0, 0 );

 	pvr2_schedule_scanline_event( EVENT_SCANLINE2, pvr2_state.irq_vpos2, 0, 0 );

 	MMIO_WRITE( PVR2, reg, val );

 	break;

     case RENDER_NEARCLIP:

 	MMIO_WRITE( PVR2, reg, val & 0x7FFFFFFF );

 	break;

     case RENDER_SHADOW:

 	MMIO_WRITE( PVR2, reg, val&0x000001FF );

 	break;

     case RENDER_OBJCFG:

     	MMIO_WRITE( PVR2, reg, val&0x003FFFFF );

     	break;

     case RENDER_TSPCLIP:

     	MMIO_WRITE( PVR2, reg, val&0x7FFFFFFF );

     	break;

     case RENDER_FARCLIP:

 	MMIO_WRITE( PVR2, reg, val&0xFFFFFFF0 );

 	break;

     case RENDER_BGPLANE:

     	MMIO_WRITE( PVR2, reg, val&0x1FFFFFFF );

     	break;

     case RENDER_ISPCFG:

     	MMIO_WRITE( PVR2, reg, val&0x00FFFFF9 );

     	break;

     case VRAM_CFG1:

 	MMIO_WRITE( PVR2, reg, val&0x000000FF );

 	break;

     case VRAM_CFG2:

 	MMIO_WRITE( PVR2, reg, val&0x003FFFFF );

 	break;

     case VRAM_CFG3:

 	MMIO_WRITE( PVR2, reg, val&0x1FFFFFFF );

 	break;

     case RENDER_FOGTBLCOL:

     case RENDER_FOGVRTCOL:

 	MMIO_WRITE( PVR2, reg, val&0x00FFFFFF );

 	break;

     case RENDER_FOGCOEFF:

 	MMIO_WRITE( PVR2, reg, val&0x0000FFFF );

 	break;

     case RENDER_CLAMPHI:

     case RENDER_CLAMPLO:

 	MMIO_WRITE( PVR2, reg, val );

 	break;

     case RENDER_TEXSIZE:

 	MMIO_WRITE( PVR2, reg, val&0x00031F1F );

 	break;

     case RENDER_PALETTE:

 	MMIO_WRITE( PVR2, reg, val&0x00000003 );

 	break;

     case RENDER_ALPHA_REF:

 	MMIO_WRITE( PVR2, reg, val&0x000000FF );

 	break;

 	/********** CRTC registers *************/

     case DISP_HBORDER:

     case DISP_VBORDER:

 	MMIO_WRITE( PVR2, reg, val&0x03FF03FF );

 	break;

     case DISP_TOTAL:

 	val = val & 0x03FF03FF;

 	MMIO_WRITE( PVR2, reg, val );

 	pvr2_update_raster_posn(sh4r.slice_cycle);

 	pvr2_state.total_lines = (val >> 16) + 1;

 	pvr2_state.line_size = (val & 0x03FF) + 1;

 	pvr2_state.line_time_ns = 1000000 * pvr2_state.line_size / pvr2_state.dot_clock;

 	pvr2_state.retrace_end_line = 0x2A;

 	pvr2_state.retrace_start_line = pvr2_state.total_lines - 6;

 	pvr2_schedule_scanline_event( EVENT_SCANLINE1, pvr2_state.irq_vpos1, 0, 0 );

 	pvr2_schedule_scanline_event( EVENT_SCANLINE2, pvr2_state.irq_vpos2, 0, 0 );

 	pvr2_schedule_scanline_event( EVENT_HPOS, pvr2_state.irq_hpos_line, 0, 

 					  pvr2_state.irq_hpos_time_ns );

 	break;

     case DISP_SYNCCFG:

 	MMIO_WRITE( PVR2, reg, val&0x000003FF );

 	pvr2_state.interlaced = (val & 0x0010) ? TRUE : FALSE;

 	break;

     case DISP_SYNCTIME:

 	pvr2_state.vsync_lines = (val >> 8) & 0x0F;

 	pvr2_state.hsync_width_ns = ((val & 0x7F) + 1) * 2000000 / pvr2_state.dot_clock;

 	MMIO_WRITE( PVR2, reg, val&0xFFFFFF7F );

 	break;

     case DISP_CFG2:

 	MMIO_WRITE( PVR2, reg, val&0x003F01FF );

 	break;

     case DISP_HPOS:

 	val = val & 0x03FF;

 	pvr2_state.front_porch_ns = (val + 1) * 1000000 / pvr2_state.dot_clock;

 	MMIO_WRITE( PVR2, reg, val );

 	break;

     case DISP_VPOS:

 	MMIO_WRITE( PVR2, reg, val&0x03FF03FF );

 	break;

 	/*********** Tile accelerator registers ***********/

     case TA_POLYPOS:

     case TA_LISTPOS:

 	/* Readonly registers */

 	break;

     case TA_TILEBASE:

     case TA_LISTEND:

     case TA_LISTBASE:

 	MMIO_WRITE( PVR2, reg, val&0x00FFFFE0 );

 	break;

     case RENDER_TILEBASE:

     case TA_POLYBASE:

     case TA_POLYEND:

 	MMIO_WRITE( PVR2, reg, val&0x00FFFFFC );

 	break;

     case TA_TILESIZE:

 	MMIO_WRITE( PVR2, reg, val&0x000F003F );

 	break;

     case TA_TILECFG:

 	MMIO_WRITE( PVR2, reg, val&0x00133333 );

 	break;

     case TA_INIT:

 	if( val & 0x80000000 )

 	    pvr2_ta_init();

 	break;

     case TA_REINIT:

 	break;

 	/**************** Scaler registers? ****************/

     case RENDER_SCALER:

 	MMIO_WRITE( PVR2, reg, val&0x0007FFFF );

 	break;

     case YUV_ADDR:

 	val = val & 0x00FFFFF8;

 	MMIO_WRITE( PVR2, reg, val );

 	pvr2_yuv_init( val );

 	break;

     case YUV_CFG:

 	MMIO_WRITE( PVR2, reg, val&0x01013F3F );

 	pvr2_yuv_set_config(val);

 	break;

 	/**************** Unknowns ***************/

     case PVRUNK1:

     	MMIO_WRITE( PVR2, reg, val&0x000007FF );

     	break;

     case PVRUNK2:

 	MMIO_WRITE( PVR2, reg, val&0x00000007 );

 	break;

     case PVRUNK3:

 	MMIO_WRITE( PVR2, reg, val&0x000FFF3F );

 	break;

     case PVRUNK5:

 	MMIO_WRITE( PVR2, reg, val&0x0000FFFF );

 	break;

     case PVRUNK7:

 	MMIO_WRITE( PVR2, reg, val&0x00000001 );

 	break;

     }

 }

 /**

  * Calculate the current read value of the syncstat register, using

  * the current SH4 clock time as an offset from the last timeslice.

  * The register reads (LSB to MSB) as:

  *     0..9  Current scan line

  *     10    Odd/even field (1 = odd, 0 = even)

  *     11    Display active (including border and overscan)

  *     12    Horizontal sync off

  *     13    Vertical sync off

  * Note this method is probably incorrect for anything other than straight

  * interlaced PAL/NTSC, and needs further testing. 

  */

 uint32_t pvr2_get_sync_status()

 {

     pvr2_update_raster_posn(sh4r.slice_cycle);

     uint32_t result = pvr2_state.line_count;

     if( pvr2_state.odd_even_field ) {

 	result |= 0x0400;

     }

     if( (pvr2_state.line_count & 0x01) == pvr2_state.odd_even_field ) {

 	if( pvr2_state.line_remainder > pvr2_state.hsync_width_ns ) {

 	    result |= 0x1000; /* !HSYNC */

 	}

 	if( pvr2_state.line_count >= pvr2_state.vsync_lines ) {

 	    if( pvr2_state.line_remainder > pvr2_state.front_porch_ns ) {

 		result |= 0x2800; /* Display active */

 	    } else {

 		result |= 0x2000; /* Front porch */

 	    }

 	}

     } else {

 	if( pvr2_state.line_count >= pvr2_state.vsync_lines ) {

 	    if( pvr2_state.line_remainder < (pvr2_state.line_time_ns - pvr2_state.back_porch_ns)) {

 		result |= 0x3800; /* Display active */

 	    } else {

 		result |= 0x3000;

 	    }

 	} else {

 	    result |= 0x1000; /* Back porch */

 	}

     }

     return result;

 }

 /**

  * Schedule a "scanline" event. This actually goes off at

  * 2 * line in even fields and 2 * line + 1 in odd fields.

  * Otherwise this behaves as per pvr2_schedule_line_event().

  * The raster position should be updated before calling this

  * method.

  * @param eventid Event to fire at the specified time

  * @param line Line on which to fire the event (this is 2n/2n+1 for interlaced

  *  displays). 

  * @param hpos_ns Nanoseconds into the line at which to fire.

  */

 static void pvr2_schedule_scanline_event( int eventid, int line, int minimum_lines, int hpos_ns )

 {

     uint32_t field = pvr2_state.odd_even_field;

     if( line <= pvr2_state.line_count && pvr2_state.interlaced ) {

 	field = !field;

     }

     if( hpos_ns > pvr2_state.line_time_ns ) {

 	hpos_ns = pvr2_state.line_time_ns;

     }

     line <<= 1;

     if( field ) {

 	line += 1;

     }

     if( line < pvr2_state.total_lines ) {

 	uint32_t lines;

 	uint32_t time;

 	if( line <= pvr2_state.line_count ) {

 	    lines = (pvr2_state.total_lines - pvr2_state.line_count + line);

 	} else {

 	    lines = (line - pvr2_state.line_count);

 	}

 	if( lines <= minimum_lines ) {

 	    lines += pvr2_state.total_lines;

 	}

 	time = (lines * pvr2_state.line_time_ns) - pvr2_state.line_remainder + hpos_ns;

 	event_schedule( eventid, time );

     } else {

 	event_cancel( eventid );

     }

 }

 MMIO_REGION_READ_FN( PVR2, reg )

 {

     switch( reg ) {

         case DISP_SYNCSTAT:

             return pvr2_get_sync_status();

         default:

             return MMIO_READ( PVR2, reg );

     }

 }

 MMIO_REGION_WRITE_FN( PVR2PAL, reg, val )

 {

     MMIO_WRITE( PVR2PAL, reg, val );

     pvr2_state.palette_changed = TRUE;

 }

 void pvr2_check_palette_changed()

 {

     if( pvr2_state.palette_changed ) {

 	texcache_invalidate_palette();

 	pvr2_state.palette_changed = FALSE;

     }

 }

 MMIO_REGION_READ_DEFFN( PVR2PAL );

 void pvr2_set_base_address( uint32_t base ) 

 {

     mmio_region_PVR2_write( DISP_ADDR1, base );

 }

 int32_t mmio_region_PVR2TA_read( uint32_t reg )

 {

     return 0xFFFFFFFF;

 }

 void mmio_region_PVR2TA_write( uint32_t reg, uint32_t val )

 {

     pvr2_ta_write( (unsigned char *)&val, sizeof(uint32_t) );

 }

 /**

  * Find the render buffer corresponding to the requested output frame

  * (does not consider texture renders). 

  * @return the render_buffer if found, or null if no such buffer.

  *

  * Note: Currently does not consider "partial matches", ie partial

  * frame overlap - it probably needs to do this.

  */

 render_buffer_t pvr2_get_render_buffer( frame_buffer_t frame )

 {

     int i;

     for( i=0; i<render_buffer_count; i++ ) {

 	if( render_buffers[i] != NULL && render_buffers[i]->address == frame->address ) {

 	    return render_buffers[i];

 	}

     }

     return NULL;

 }

 /**

  * Allocate a render buffer with the requested parameters.

  * The order of preference is:

  *   1. An existing buffer with the same address. (not flushed unless the new

  * size is smaller than the old one).

  *   2. An existing buffer with the same size chosen by LRU order. Old buffer

  *       is flushed to vram.

  *   3. A new buffer if one can be created.

  *   4. The current display buff

  * Note: The current display field(s) will never be overwritten except as a last

  * resort.

  */

 render_buffer_t pvr2_alloc_render_buffer( sh4addr_t render_addr, int width, int height )

 {

     int i;

     render_buffer_t result = NULL;

     /* Check existing buffers for an available buffer */

     for( i=0; i<render_buffer_count; i++ ) {

 	if( render_buffers[i]->width == width && render_buffers[i]->height == height ) {

 	    /* needs to be the right dimensions */

 	    if( render_buffers[i]->address == render_addr ) {

 		if( displayed_render_buffer == render_buffers[i] ) {

 		    /* Same address, but we can't use it because the

 		     * display has it. Mark it as unaddressed for later.

 		     */

 		    render_buffers[i]->address = -1;

 		} else {

 		    /* perfect */

 		    result = render_buffers[i];

 		    break;

 		}

 	    } else if( render_buffers[i]->address == -1 && result == NULL && 

 		       displayed_render_buffer != render_buffers[i] ) {

 		result = render_buffers[i];

 	    }

 	} else if( render_buffers[i]->address == render_addr ) {

 	    /* right address, wrong size - if it's larger, flush it, otherwise 

 	     * nuke it quietly */

 	    if( render_buffers[i]->width * render_buffers[i]->height >

 		width*height ) {

 		pvr2_render_buffer_copy_to_sh4( render_buffers[i] );

 	    }

 	    render_buffers[i]->address = -1;

 	}

     }

     /* Nothing available - make one */

     if( result == NULL ) {

 	if( render_buffer_count == MAX_RENDER_BUFFERS ) {

 	    /* maximum buffers reached - need to throw one away */

 	    uint32_t field1_addr = MMIO_READ( PVR2, DISP_ADDR1 );

 	    uint32_t field2_addr = MMIO_READ( PVR2, DISP_ADDR2 );

 	    for( i=0; i<render_buffer_count; i++ ) {

 		if( render_buffers[i]->address != field1_addr &&

 		    render_buffers[i]->address != field2_addr &&

 		    render_buffers[i] != displayed_render_buffer ) {

 		    /* Never throw away the current "front buffer(s)" */

 		    result = render_buffers[i];

 		    if( !result->flushed ) {

 			pvr2_render_buffer_copy_to_sh4( result );

 		    }

 		    if( result->width != width || result->height != height ) {

 			display_driver->destroy_render_buffer(render_buffers[i]);

 			result = display_driver->create_render_buffer(width,height);

 			render_buffers[i] = result;

 		    }

 		    break;

 		}

 	    }

 	} else {

 	    result = display_driver->create_render_buffer(width,height);

 	    if( result != NULL ) { 

 		render_buffers[render_buffer_count++] = result;

 	    }

 	}

     }

     if( result != NULL ) {

 	result->address = render_addr;

     }

     return result;

 }

 /**

  * Allocate a render buffer based on the current rendering settings

  */

 render_buffer_t pvr2_next_render_buffer()

 {

     render_buffer_t result = NULL;

     uint32_t render_addr = MMIO_READ( PVR2, RENDER_ADDR1 );

     uint32_t render_mode = MMIO_READ( PVR2, RENDER_MODE );

     uint32_t render_scale = MMIO_READ( PVR2, RENDER_SCALER );

     uint32_t render_stride = MMIO_READ( PVR2, RENDER_SIZE ) << 3;

     if( render_addr & 0x01000000 ) { /* vram64 */

 	render_addr = (render_addr & 0x00FFFFFF) + PVR2_RAM_BASE_INT;

     } else { /* vram32 */

 	render_addr = (render_addr & 0x00FFFFFF) + PVR2_RAM_BASE;

     }

     int width = pvr2_scene_buffer_width();

     int height = pvr2_scene_buffer_height();

     int colour_format = pvr2_render_colour_format[render_mode&0x07];

     result = pvr2_alloc_render_buffer( render_addr, width, height );

     /* Setup the buffer */

     if( result != NULL ) {

 	result->rowstride = render_stride;

 	result->colour_format = colour_format;

 	result->scale = render_scale;

 	result->size = width * height * colour_formats[colour_format].bpp;

 	result->flushed = FALSE;

 	result->inverted = TRUE; // render buffers are inverted normally

     }

     return result;

 }

 static render_buffer_t pvr2_frame_buffer_to_render_buffer( frame_buffer_t frame )

 {

     render_buffer_t result = pvr2_alloc_render_buffer( frame->address, frame->width, frame->height );

     if( result != NULL ) {

 	int bpp = colour_formats[frame->colour_format].bpp;

 	result->rowstride = frame->rowstride;

 	result->colour_format = frame->colour_format;

 	result->scale = 0x400;

 	result->size = frame->width * frame->height * bpp;

 	result->flushed = TRUE;

 	result->inverted = frame->inverted;

 	display_driver->load_frame_buffer( frame, result );

     }

     return result;

 }

 /**

  * Invalidate any caching on the supplied address. Specifically, if it falls

  * within any of the render buffers, flush the buffer back to PVR2 ram.

  */

 gboolean pvr2_render_buffer_invalidate( sh4addr_t address, gboolean isWrite )

 {

     int i;

     address = address & 0x1FFFFFFF;

     for( i=0; i<render_buffer_count; i++ ) {

 	uint32_t bufaddr = render_buffers[i]->address;

 	if( bufaddr != -1 && bufaddr <= address && 

 	    (bufaddr + render_buffers[i]->size) > address ) {

 	    if( !render_buffers[i]->flushed ) {

 		pvr2_render_buffer_copy_to_sh4( render_buffers[i] );

 		render_buffers[i]->flushed = TRUE;

 	    }

 	    if( isWrite ) {

 		render_buffers[i]->address = -1; /* Invalid */

 	    }

 	    return TRUE; /* should never have overlapping buffers */

 	}

     }

     return FALSE;

 }