Rev 1085 |
Rev 1436 |
Go to most recent revision |
Blame |
Compare with Previous |
Last modification |
View Log
| RSS feed
/*****************************************************************************
* Filename: test_dac.c *
* Author: Marco Ziglioli (Doctor Stein) *
* Date: 12/06/2001 *
* Description: Little test program for Analog Output section of PCI6025E *
*----------------------------------------------------------------------------*
* Notes: Connect a multimeter to DAC1 output (pin 21) and watch *
* tension value. Use '+' and '-' on numeric pad to increase *
* and decrise voltage *
* With this program it's possible to point out possible *
* offset errors. To correct them no software are written but *
* in National board package there's the program to calibrate *
* the board. Otherwise you can see how much is the offset *
* and you can compensate it through software value *
*****************************************************************************/
/* This file is part of the S.Ha.R.K. Project - http://shark.sssup.it
*
* Copyright (C) 2001 Marco Ziglioli
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#include <drivers/glib.h>
#include <drivers/keyb.h>
#include <drivers/pci6025e/dac.h>
#define TASK_VOLT_PERIOD 150E3
#define TASK_VOLT_WCET 080E3
#define TASK_DAC_PERIOD 050E3
#define TASK_DAC_WCET 020E3
#define CONV 10/2048
#define TASK_GROUP 1
WORD dac0_value
= 0,
dac1_value
= 0;
BYTE sys
= 0;
BYTE dac
= 0;
//some colors
int black
= rgb16
(0, 0, 0),
white
= rgb16
(255, 255, 255);
void drawInterface
(void);
void endfun
(KEY_EVT
*);
void inc
(KEY_EVT
*);
void dec
(KEY_EVT
*);
void change_dac
(KEY_EVT
*);
void close_event
(void *);
TASK Voltage_body
(int);
TASK DAC_Check_body
(int);
int main
(int argc
, char **argv
)
{
int modenum
;
KEY_EVT k
;
HARD_TASK_MODEL m
, d
;
PID pid_m
, pid_d
;
sys_atrunlevel
(close_event
, NULL
, RUNLEVEL_BEFORE_EXIT
);
keyb_set_map
(itaMap
);
k.
flag = CNTR_BIT
;
k.
scan = KEY_X
;
k.
ascii = 'x';
keyb_hook
(k
, endfun
);
k.
flag = CNTL_BIT
;
keyb_hook
(k
, endfun
);
k.
flag = 0;
k.
scan = 78;
k.
ascii = 43;
keyb_hook
(k
, inc
);
k.
flag = 0;
k.
scan = 74;
k.
ascii = 45;
keyb_hook
(k
, dec
);
k.
flag = 0;
k.
scan = KEY_V
;
k.
ascii = 'v';
keyb_hook
(k
, change_dac
);
hard_task_default_model
(m
);
hard_task_def_wcet
(m
, TASK_VOLT_WCET
);
hard_task_def_mit
(m
, TASK_VOLT_PERIOD
);
hard_task_def_group
(m
, TASK_GROUP
);
pid_m
= task_create
("Voltage", Voltage_body
, &m
, NULL
);
if(pid_m
== NIL
){
sys
= 30;
sys_end
();
}
hard_task_default_model
(d
);
hard_task_def_wcet
(d
, TASK_DAC_WCET
);
hard_task_def_mit
(d
, TASK_DAC_PERIOD
);
hard_task_def_group
(d
, TASK_GROUP
);
pid_d
= task_create
("DAC Check", DAC_Check_body
, &d
, NULL
);
if(pid_d
== NIL
){
sys
= 31;
sys_end
();
}
//Check if PCI bus is present
if(pci_init
()==-1){
sys
= 10;
sys_end
();
}
//Check if a NI board is on PCI bus
if(!reMap
()){
sys
= 11;
sys_end
();
}
if(grx_init
()==-1){
sys
= 20;
sys_end
();
}
modenum
= grx_getmode
(800, 600, 16);
if(modenum
== -1){
sys
= 21;
sys_end
();
}
grx_setmode
(modenum
);
drawInterface
();
//Analog output section set up
DAC_Init
();
/*
*AI_TIMEBASE div by 2; OUT_TIMEBASE div by 2; single DAC mode
*TMRDACWR = 3 OUT_TIMEBASE period; FIFO flags polarity active low
*TMRDACWR disabled; DMA PIO control = FIFO DATA interface mode
*UPDATE signal timebase = AO_UPDATE pulse width
*UPDATE pulsewidth = 3-3.5 OUT_TIMEBASE period
*UPDATE signal polarity = HIGH Z
*/
DAC_boardInit
(0x02, 0x4000);
/*
*LDAC0 source = UPDATE
*DAC0 update immediately
*LDAC1 source = UPDATE
*DAC1 update immediately
*/
DAC_LDACSourceUpdate
(0x00);
//End of Analog output section setup
group_activate
(TASK_GROUP
);
return 0;
}
/*
* Every time operator select a new value to send to a DAc this TASK makes
* actions needed to perform the operation
*/
TASK Voltage_body
(int dac_work
)
{
WORD old0_value
, old1_value
;
char buf
[6];
float volt
;
old0_value
= dac0_value
;
old1_value
= dac1_value
;
while(1){
if(dac
){
if(dac1_value
!= old1_value
){
DAC_output
(DAC1
, dac1_value
);
old1_value
= dac1_value
;
sprintf(buf
, "%04d", dac1_value
);
grx_text
(buf
, 70, 120, rgb16
(180, 0, 0), rgb16
(255,255,140));
sprintf(buf
, "%04x", dac1_value
);
grx_text
(buf
, 300, 120, rgb16
(180, 0, 0), rgb16
(255,255,140));
if( (dac1_value
& 0x0800) == 0 )
volt
= (float)dac1_value
* (float)CONV
;
else
volt
= (float)(dac1_value
-0x0FFF) * (float)CONV
;
sprintf(buf
, "%05.2f", volt
);
grx_text
(buf
, 70, 177, rgb16
(180, 40, 180), black
);
}
} else {
if(dac0_value
!= old0_value
){
DAC_output
(DAC0
, dac0_value
);
old0_value
= dac0_value
;
sprintf(buf
, "%04d", dac0_value
);
grx_text
(buf
, 521, 120, rgb16
(180, 0, 0), rgb16
(255,255,140));
sprintf(buf
, "%04x", dac0_value
);
grx_text
(buf
, 754, 120, rgb16
(180, 0, 0), rgb16
(255,255,140));
if( (dac0_value
& 0x0800) == 0 )
volt
= (float)dac0_value
* (float)CONV
;
else
volt
= (float)(dac0_value
-0x0FFF) * (float)CONV
;
sprintf(buf
, "%05.2f", volt
);
grx_text
(buf
, 521, 177, rgb16
(180, 40, 180), black
);
}
}
task_endcycle
();
}
}
/*
* This TASK show which is the DAC active
*/
TASK DAC_Check_body
(int dummy
)
{
BYTE old
= dac
;
char buf
[8];
while(1){
if(dac
!= old
){
old
= dac
;
sprintf(buf
, "DAC %d", dac
);
grx_text
(buf
, 385, 90, rgb16
(255*dac
, 255*(1-dac
), 0), black
);
}
task_endcycle
();
}
}
void drawInterface
(void)
{
grx_rect
(1, 1, 799, 69, rgb16
(105, 0, 0));
grx_rect
(2, 2, 798, 68, rgb16
(155, 0, 0));
grx_rect
(3, 3, 797, 67, rgb16
(205, 0, 0));
grx_rect
(4, 4, 796, 66, rgb16
(255, 0, 0));
grx_text
("Test program for Analog output section of PCI6025E",
7, 10, rgb16
(50, 255, 50), black
);
grx_text
("Use '+' and '-' on numeric pad to change tension",
7, 25, rgb16
(0, 255, 255), black
);
grx_text
("Connect a tester to DAC1 output (pin21) or to DAC0 output (pin20)",
7, 33, rgb16
(0, 255, 255), black
);
grx_text
("Use 'v' to alternate change active DAC",
7, 40, rgb16
(0, 255, 255), black
);
grx_text
("CTRL-X for Exit", 7, 55, rgb16
(200, 200, 0), black
);
grx_rect
(1, 80, 355, 150, rgb16
(0, 105, 0));
grx_rect
(2, 81, 354, 149, rgb16
(0, 155, 0));
grx_rect
(3, 82, 353, 148, rgb16
(0, 205, 0));
grx_rect
(4, 83, 352, 147, rgb16
(0, 255, 0));
grx_rect
(1, 160, 355, 199, rgb16
(0, 105, 0));
grx_rect
(2, 161, 354, 198, rgb16
(0, 155, 0));
grx_rect
(3, 162, 353, 197, rgb16
(0, 205, 0));
grx_rect
(4, 163, 352, 196, rgb16
(0, 255, 0));
grx_rect
(455, 80, 799, 150, rgb16
(105, 105, 0));
grx_rect
(456, 81, 798, 149, rgb16
(155, 155, 0));
grx_rect
(457, 82, 797, 148, rgb16
(205, 205, 0));
grx_rect
(458, 83, 796, 147, rgb16
(255, 255, 0));
grx_rect
(455, 160, 799, 199, rgb16
(105, 105, 0));
grx_rect
(456, 161, 798, 198, rgb16
(155, 155, 0));
grx_rect
(457, 162, 797, 197, rgb16
(205, 205, 0));
grx_rect
(458, 163, 796, 196, rgb16
(255, 255, 0));
grx_rect
(360, 80, 450, 105, rgb16
(85, 85, 255));
grx_rect
(361, 81, 449, 104, rgb16
(125, 125, 255));
grx_rect
(362, 82, 448, 103, rgb16
(175, 175, 255));
grx_rect
(363, 83, 447, 102, rgb16
(225, 225, 255));
grx_rect
(153, 93, 195, 103, rgb16
(255, 0, 0));
grx_text
("DAC 1", 155, 95, rgb16
(255, 170, 170), black
);
grx_rect
(607, 93, 649, 103, rgb16
(255, 0, 0));
grx_text
("DAC 0", 609, 95, rgb16
(255, 255, 210), black
);
grx_text
("Decimal", 7, 120, rgb16
(120, 120, 255), black
);
grx_text
("Hexadecimal", 200, 120, rgb16
(120, 120, 255), black
);
grx_text
("Tension", 7, 177, rgb16
(120, 120, 255), black
);
grx_text
("Decimal", 461, 120, rgb16
(255, 120, 120), black
);
grx_text
("Hexadecimal", 654, 120, rgb16
(255, 120, 120), black
);
grx_text
("Tension", 461, 177, rgb16
(255, 120, 120), black
);
}
void close_event
(void *arg
)
{
grx_close
();
switch(sys
){
case 0 : cprintf
("Regular End\n"); break;
case 1 : cprintf
("End fun invoked\n"); break;
case 10: cprintf
("Pci bus not found\n"); break;
case 11: cprintf
("No National board found\n"); break;
case 20: cprintf
("Cannot initialize graphic envirorment\n"); break;
case 21: cprintf
("Cannot start envirorment in 800x600x16\n"); break;
case 30: cprintf
("Cannot create task <voltage>\n"); break;
case 31: cprintf
("Canot create task <DAC Check>\n"); break;
case 40: cprintf
("Break on clock end event\n"); break;
default: cprintf
("Unkwon exit event\n"); break;
}
}
void endfun
(KEY_EVT
*k
)
{
sys
= 1;
sys_end
();
}
/*
* Capture correct key event and increase output tension of active DAC
*/
void inc
(KEY_EVT
*k
)
{
if(dac
){
if( (dac1_value
& 0x0800) == 0 && dac1_value
> 0x07FF )
dac1_value
= 0;
else
dac1_value
++;
} else {
if( (dac0_value
& 0x0800) == 0 && dac0_value
> 0x07FF )
dac0_value
= 0;
else
dac0_value
++;
}
}
/*
* Same as above but decrease tension
*/
void dec
(KEY_EVT
*k
)
{
if(dac
){
if(dac1_value
< 1)
dac1_value
= 0x0FFF;
else
dac1_value
-= 1;
} else {
if(dac0_value
< 1)
dac0_value
= 0x0FFF;
else
dac0_value
-= 1;
}
}
/*
* Capture correct key event and change active DAC
*/
void change_dac
(KEY_EVT
*k
)
{
if(dac
) dac
= 0;
else dac
= 1;
}