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mpv/libvo/gtf.c
arpi 4ae1571dda General Timing Formula algorithm from a scratch.
vo_vesa.c so now adjust the timing to highest possible refresh rate using
the monitor capabilities from a config file.
patch by Rudolf Marek <MAREKR2@cs.felk.cvut.cz>


git-svn-id: svn://svn.mplayerhq.hu/mplayer/trunk@7070 b3059339-0415-0410-9bf9-f77b7e298cf2
2002-08-22 23:03:51 +00:00

298 lines
10 KiB
C

/*
* Copyright (C) Rudolf Marek <r.marek@sh.cvut.cz> - Aug 2002
*
* You can redistribute this file under terms and conditions
* of GNU General Public licence v2.
*
* GTF calculations formulas are taken from GTF_V1R1.xls
* created by ANDY.MORRISH@NSC.COM
*/
//Version 0.4
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include "gtf.h"
#undef GTF_DEBUG
#ifdef GTF_DEBUG
#define DEBUG_PRINTF(a,b) printf(a,b);
#else
#define DEBUG_PRINTF(a,b)
#endif
static GTF_constants GTF_given_constants = { 3.0,550.0,1,8,1.8,8,40,20,128,600 };
static double round(double v)
{
return floor(v + 0.5);
}
static void GetRoundedConstants(GTF_constants *c)
{
c->Vsync_need = round(GTF_given_constants.Vsync_need);
c->min_Vsync_BP = GTF_given_constants.min_Vsync_BP;
c->min_front_porch = round(GTF_given_constants.min_front_porch);
c->char_cell_granularity = GTF_given_constants.char_cell_granularity;
c->margin_width = GTF_given_constants.margin_width;
c->sync_width = GTF_given_constants.sync_width;
c->c = ((GTF_given_constants.c - GTF_given_constants.j)*(GTF_given_constants.k / 256)) + GTF_given_constants.j;
c->j = GTF_given_constants.j;
c->k = GTF_given_constants.k;
c->m = (GTF_given_constants.k / 256) * GTF_given_constants.m;
}
void GTF_calcTimings(double X,double Y,double freq, int type,
int want_margins, int want_interlace,struct VesaCRTCInfoBlock *result )
{
GTF_constants c;
double RR, margin_top, margin_bottom, margin_left, margin_right;
double estimated_H_period,sync_plus_BP,BP,interlace,V_total_lines_field;
double estimated_V_field_rate,actual_H_period,actual_V_field_freq;
double total_active_pixels, ideal_duty_cycle, blanking_time, H_total_pixels;
double H_freq, pixel_freq,actual_V_frame_freq;
double H_sync_start, H_sync_end, H_back_porch, H_front_porch, H_sync_width;
double V_back_porch, V_front_porch, V_sync_start, V_sync_end,V_sync_width;
double ideal_H_period;
GetRoundedConstants(&c);
pixel_freq = RR = freq;
/* DETERMINE IF 1/2 LINE INTERLACE IS PRESENT */
interlace = 0;
if (want_interlace) {
RR = RR * 2;
Y=Y/2;
interlace = 0.5;
}
result->Flags = 0;
if ((Y==300)||(Y==200)||(Y==240))
{
Y*=2;
result->Flags = VESA_CRTC_DOUBLESCAN; /* TODO: check if mode support */
}
/* DETERMINE NUMBER OF LINES IN V MARGIN */
/* DETERMINE NUMBER OF PIXELS IN H MARGIN [pixels] */
margin_left = margin_right = 0;
margin_top = margin_bottom = 0;
if (want_margins) {
margin_top = margin_bottom = (c.margin_width / 100) * Y;
margin_left = round(( X* c.margin_width/100)/c.char_cell_granularity) \
* c.char_cell_granularity;
margin_right = margin_left;
DEBUG_PRINTF("margin_left_right : %f\n",margin_right)
DEBUG_PRINTF("margin_top_bottom : %f\n",margin_top)
}
/* FIND TOTAL NUMBER OF ACTIVE PIXELS (IMAGE + MARGIN) [pixels] */
total_active_pixels = margin_left + margin_right + X;
DEBUG_PRINTF("total_active_pixels: %f\n",total_active_pixels)
if (type == GTF_PF)
{
ideal_H_period = ((c.c-100)+(sqrt(((100-c.c)*(100-c.c) )+(0.4*c.m*(total_active_pixels + margin_left + margin_right) / freq))))/2/c.m*1000;
DEBUG_PRINTF("ideal_H_period: %f\n",ideal_H_period)
/* FIND IDEAL BLANKING DUTY CYCLE FROM FORMULA [%] */
ideal_duty_cycle = c.c - (c.m * ideal_H_period /1000);
DEBUG_PRINTF("ideal_duty_cycle: %f\n",ideal_duty_cycle)
/* FIND BLANKING TIME (TO NEAREST CHAR CELL) [pixels] */
blanking_time = round(total_active_pixels * ideal_duty_cycle \
/ (100-ideal_duty_cycle) / (2*c.char_cell_granularity)) \
* (2*c.char_cell_granularity);
DEBUG_PRINTF("blanking_time : %f\n",blanking_time )
/* FIND TOTAL NUMBER OF PIXELS IN A LINE [pixels] */
H_total_pixels = total_active_pixels + blanking_time ;
DEBUG_PRINTF("H_total_pixels: %f\n",H_total_pixels)
H_freq = freq / H_total_pixels * 1000;
DEBUG_PRINTF("H_freq: %f\n",H_freq)
actual_H_period = 1000 / H_freq;
DEBUG_PRINTF("actual_H_period: %f\n",actual_H_period)
sync_plus_BP = round(H_freq * c.min_Vsync_BP/1000);
// sync_plus_BP = round( freq / H_total_pixels * c.min_Vsync_BP);
DEBUG_PRINTF("sync_plus_BP: %f\n",sync_plus_BP)
} else if (type == GTF_VF)
{
/* ESTIMATE HORIZ. PERIOD [us] */
estimated_H_period = (( 1/RR ) - c.min_Vsync_BP/1000000 ) / (Y + (2 * margin_top) + c.min_front_porch + interlace) * 1000000;
DEBUG_PRINTF("estimated_H_period: %f\n",estimated_H_period)
/* FIND NUMBER OF LINES IN (SYNC + BACK PORCH) [lines] */
sync_plus_BP = round( c.min_Vsync_BP / estimated_H_period );
DEBUG_PRINTF("sync_plus_BP: %f\n",sync_plus_BP)
} else if (type == GTF_HF)
{
sync_plus_BP = round(freq * c.min_Vsync_BP/1000);
DEBUG_PRINTF("sync_plus_BP: %f\n",sync_plus_BP)
}
/* FIND TOTAL NUMBER OF LINES IN VERTICAL FIELD */
V_total_lines_field = sync_plus_BP+interlace+margin_bottom+margin_top+Y+c.min_front_porch;
DEBUG_PRINTF("V_total_lines_field : %f\n",V_total_lines_field )
if (type == GTF_VF)
{
/* ESTIMATE VERTICAL FIELD RATE [hz] */
estimated_V_field_rate = 1 / estimated_H_period / V_total_lines_field * 1000000;
DEBUG_PRINTF(" estimated_V_field_rate: %f\n", estimated_V_field_rate)
/* FIND ACTUAL HORIZONTAL PERIOD [us] */
actual_H_period = estimated_H_period / (RR / estimated_V_field_rate);
DEBUG_PRINTF("actual_H_period: %f\n",actual_H_period)
/* FIND ACTUAL VERTICAL FIELD FREQUENCY [Hz] */
actual_V_field_freq = 1 / actual_H_period / V_total_lines_field * 1000000;
DEBUG_PRINTF("actual_V_field_freq: %f\n",actual_V_field_freq)
/* FIND IDEAL BLANKING DUTY CYCLE FROM FORMULA [%] */
ideal_duty_cycle = c.c - (c.m * actual_H_period /1000);
DEBUG_PRINTF("ideal_duty_cycle: %f\n",ideal_duty_cycle)
//if (type == GTF_VF)
//{
//moved
//}
} else if (type == GTF_HF)
{
/* FIND IDEAL BLANKING DUTY CYCLE FROM FORMULA [%] */
ideal_duty_cycle = c.c - (c.m / freq);
DEBUG_PRINTF("ideal_duty_cycle: %f\n",ideal_duty_cycle)
}
/* FIND BLANKING TIME (TO NEAREST CHAR CELL) [pixels] */
if (!(type == GTF_PF))
{
blanking_time = round(total_active_pixels * ideal_duty_cycle \
/ (100-ideal_duty_cycle) / (2*c.char_cell_granularity)) \
* (2*c.char_cell_granularity);
DEBUG_PRINTF("blanking_time : %f\n",blanking_time )
}
else
// if (type == GTF_PF)
{
actual_V_field_freq = H_freq / V_total_lines_field * 1000;
}
if (type == GTF_HF)
{
/* Hz */
actual_V_field_freq = freq / V_total_lines_field * 1000;
DEBUG_PRINTF("actual_V_field_freq: %f\n",actual_V_field_freq)
}
actual_V_frame_freq = actual_V_field_freq;
/* FIND ACTUAL VERTICAL FRAME FREQUENCY [Hz]*/
if (want_interlace) actual_V_frame_freq = actual_V_field_freq / 2;
DEBUG_PRINTF("actual_V_frame_freq: %f\n",actual_V_frame_freq)
// V_freq = actual_V_frame_freq;
// DEBUG_PRINTF("V_freq %f\n",V_freq)
if (!(type == GTF_PF))
{
/* FIND TOTAL NUMBER OF PIXELS IN A LINE [pixels] */
H_total_pixels = total_active_pixels + blanking_time ;
DEBUG_PRINTF("H_total_pixels: %f\n",H_total_pixels)
if (type == GTF_VF)
{
/* FIND PIXEL FREQUENCY [Mhz] */
pixel_freq = H_total_pixels / actual_H_period ;
DEBUG_PRINTF("pixel_freq: %f\n",pixel_freq)
} else if (type == GTF_HF)
{
/* FIND PIXEL FREQUENCY [Mhz] */
pixel_freq = H_total_pixels * freq / 1000 ;
DEBUG_PRINTF("pixel_freq: %f\n",pixel_freq)
actual_H_period = 1000/freq;
}
/* FIND ACTUAL HORIZONTAL FREQUENCY [KHz] */
H_freq = 1000 / actual_H_period;
DEBUG_PRINTF("H_freq %f\n",H_freq)
}
/* FIND NUMBER OF LINES IN BACK PORCH [lines] */
BP = sync_plus_BP - c.Vsync_need;
DEBUG_PRINTF("BP: %f\n",BP)
/*------------------------------------------------------------------------------------------------*/
/* FIND H SYNC WIDTH (TO NEAREST CHAR CELL) */
H_sync_width = round(c.sync_width/100*H_total_pixels/c.char_cell_granularity)*c.char_cell_granularity;
DEBUG_PRINTF("H_sync_width %f\n",H_sync_width)
/* FIND FRONT H PORCH(TO NEAREST CHAR CELL) */
H_front_porch = (blanking_time/2) - H_sync_width;
DEBUG_PRINTF("H_front_porch %f\n",H_front_porch)
/* FIND BACK H PORCH(TO NEAREST CHAR CELL) */
H_back_porch = H_sync_width + H_front_porch;
DEBUG_PRINTF("H_back_porch%f\n",H_back_porch)
H_sync_start = H_total_pixels - (H_sync_width + H_back_porch);
DEBUG_PRINTF("H_sync_start %f\n",H_sync_start)
H_sync_end = H_total_pixels - H_back_porch;
DEBUG_PRINTF("H_sync_end %f\n",H_sync_end)
V_back_porch = interlace + BP;
DEBUG_PRINTF("V_back_porch%f\n",V_back_porch)
V_front_porch = interlace + c.min_front_porch;
DEBUG_PRINTF("V_front_porch%f\n",V_front_porch)
V_sync_width = c.Vsync_need;
V_sync_start = V_total_lines_field - (V_sync_width + V_back_porch);
DEBUG_PRINTF("V_sync_start %f\n",V_sync_start)
V_sync_end = V_total_lines_field - V_back_porch;
DEBUG_PRINTF("V_sync_end %f\n",V_sync_end)
result->hTotal = H_total_pixels;
result-> hSyncStart = H_sync_start; /* Horizontal sync start in pixels */
result-> hSyncEnd = H_sync_end; /* Horizontal sync end in pixels */
result-> vTotal= V_total_lines_field; /* Vertical total in lines */
result-> vSyncStart = V_sync_start; /* Vertical sync start in lines */
result-> vSyncEnd = V_sync_end; /* Vertical sync end in lines */
result-> Flags = (result->Flags)|VESA_CRTC_HSYNC_NEG; /* Flags (Interlaced, Double Scan etc) */
if (want_interlace)
{
result->Flags = (result->Flags) | VESA_CRTC_INTERLACED;
}
result-> PixelClock = pixel_freq*1000000; /* Pixel clock in units of Hz */
result-> RefreshRate = actual_V_frame_freq*100;/* Refresh rate in units of 0.01 Hz*/
}