temp-fan-control/gertboard_sw/gb_common.c

324 lines
8.1 KiB
C
Raw Normal View History

//=============================================================================
//
//
// Gertboard Common code
//
// This file is part of the gertboard test suite
//
//
// Copyright (C) Gert Jan van Loo & Myra VanInwegen 2012
// No rights reserved
// You may treat this program as if it was in the public domain
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
//
// Notes:
// 1/ In some Linux systems (e.g. Debian) the UART is used by Linux.
// So for now do not demo the UART.
// 2/ At the moment (16-March-2012) there is no Linux driver for
// the audio yet so the PWM is free.
// This is likely to change and in that case the Linux
// audio/PWM driver must be disabled.
//
// This file contains code use by all the test programs for individual
// capabilities.
#include "gb_common.h"
#define BCM2708_PERI_BASE 0x20000000
#define CLOCK_BASE (BCM2708_PERI_BASE + 0x101000) /* Clocks */
#define GPIO_BASE (BCM2708_PERI_BASE + 0x200000) /* GPIO */
#define PWM_BASE (BCM2708_PERI_BASE + 0x20C000) /* PWM */
#define SPI0_BASE (BCM2708_PERI_BASE + 0x204000) /* SPI0 controller */
#define UART0_BASE (BCM2708_PERI_BASE + 0x201000) /* Uart 0 */
#define UART1_BASE (BCM2708_PERI_BASE + 0x215000) /* Uart 1 (not used) */
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <dirent.h>
#include <fcntl.h>
#include <assert.h>
#include <sys/mman.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
#define PAGE_SIZE (4*1024)
#define BLOCK_SIZE (4*1024)
int mem_fd;
char *clk_mem_orig, *clk_mem, *clk_map;
char *gpio_mem_orig, *gpio_mem, *gpio_map;
char *pwm_mem_orig, *pwm_mem, *pwm_map;
char *spi0_mem_orig, *spi0_mem, *spi0_map;
char *uart_mem_orig, *uart_mem, *uart_map;
// I/O access
volatile unsigned *gpio;
volatile unsigned *pwm;
volatile unsigned *clk;
volatile unsigned *spi0;
volatile unsigned *uart;
//
// GPIO
//
// GPIO setup macros. Always use INP_GPIO(x) before using OUT_GPIO(x) or SET_GPIO_ALT(x,y)
#define INP_GPIO(g) *(gpio+((g)/10)) &= ~(7<<(((g)%10)*3))
#define OUT_GPIO(g) *(gpio+((g)/10)) |= (1<<(((g)%10)*3))
#define SET_GPIO_ALT(g,a) *(gpio+(((g)/10))) |= (((a)<=3?(a)+4:(a)==4?3:2)<<(((g)%10)*3))
#define GPIO_SET0 *(gpio+7) // Set GPIO high bits 0-31
#define GPIO_SET1 *(gpio+8) // Set GPIO high bits 32-53
#define GPIO_CLR0 *(gpio+10) // Set GPIO low bits 0-31
#define GPIO_CLR1 *(gpio+11) // Set GPIO low bits 32-53
#define GPIO_PULL *(gpio+37) // Pull up/pull down
#define GPIO_PULLCLK0 *(gpio+38) // Pull up/pull down clock
//
// UART 0
//
#define UART0_BAUD_HI *(uart+9)
#define UART0_BAUD_LO *(uart+10)
void setup_io();
void restore_io();
//
// This is a software loop to wait
// a short while.
//
void short_wait()
{ int w;
for (w=0; w<100; w++)
{ w++;
w--;
}
} // short_wait
//
// Simple SW wait loop
//
void long_wait(int v)
{ int w;
while (v--)
for (w=-800000; w<800000; w++)
{ w++;
w--;
}
} // long_wait
//
// Set up memory regions to access the peripherals.
// This is a bit of 'magic' which you should not touch.
// It it also the part of the code which makes that
// you have to use 'sudo' to run this program.
//
void setup_io()
{ unsigned long extra;
/* open /dev/mem */
if ((mem_fd = open("/dev/mem", O_RDWR|O_SYNC) ) < 0) {
printf("Can't open /dev/mem\n");
printf("Did you forgot to use 'sudo .. ?'\n");
exit (-1);
}
/*
* mmap clock
*/
if ((clk_mem_orig = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
printf("allocation error \n");
exit (-1);
}
extra = (unsigned long)clk_mem_orig % PAGE_SIZE;
if (extra)
clk_mem = clk_mem_orig + PAGE_SIZE - extra;
else
clk_mem = clk_mem_orig;
clk_map = (unsigned char *)mmap(
(caddr_t)clk_mem,
BLOCK_SIZE,
PROT_READ|PROT_WRITE,
MAP_SHARED|MAP_FIXED,
mem_fd,
CLOCK_BASE
);
if ((long)clk_map < 0) {
printf("clk mmap error %d\n", (int)clk_map);
exit (-1);
}
clk = (volatile unsigned *)clk_map;
/*
* mmap GPIO
*/
if ((gpio_mem_orig = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
printf("allocation error \n");
exit (-1);
}
extra = (unsigned long)gpio_mem_orig % PAGE_SIZE;
if (extra)
gpio_mem = gpio_mem_orig + PAGE_SIZE - extra;
else
gpio_mem = gpio_mem_orig;
gpio_map = (unsigned char *)mmap(
(caddr_t)gpio_mem,
BLOCK_SIZE,
PROT_READ|PROT_WRITE,
MAP_SHARED|MAP_FIXED,
mem_fd,
GPIO_BASE
);
if ((long)gpio_map < 0) {
printf("gpio mmap error %d\n", (int)gpio_map);
exit (-1);
}
gpio = (volatile unsigned *)gpio_map;
/*
* mmap PWM
*/
if ((pwm_mem_orig = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
printf("allocation error \n");
exit (-1);
}
extra = (unsigned long)pwm_mem_orig % PAGE_SIZE;
if (extra)
pwm_mem = pwm_mem_orig + PAGE_SIZE - extra;
else
pwm_mem = pwm_mem_orig;
pwm_map = (unsigned char *)mmap(
(caddr_t)pwm_mem,
BLOCK_SIZE,
PROT_READ|PROT_WRITE,
MAP_SHARED|MAP_FIXED,
mem_fd,
PWM_BASE
);
if ((long)pwm_map < 0) {
printf("pwm mmap error %d\n", (int)pwm_map);
exit (-1);
}
pwm = (volatile unsigned *)pwm_map;
/*
* mmap SPI0
*/
if ((spi0_mem_orig = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
printf("allocation error \n");
exit (-1);
}
extra = (unsigned long)spi0_mem_orig % PAGE_SIZE;
if (extra)
spi0_mem = spi0_mem_orig + PAGE_SIZE - extra;
else
spi0_mem = spi0_mem_orig;
spi0_map = (unsigned char *)mmap(
(caddr_t)spi0_mem,
BLOCK_SIZE,
PROT_READ|PROT_WRITE,
MAP_SHARED|MAP_FIXED,
mem_fd,
SPI0_BASE
);
if ((long)spi0_map < 0) {
printf("spi0 mmap error %d\n", (int)spi0_map);
exit (-1);
}
spi0 = (volatile unsigned *)spi0_map;
/*
* mmap UART
*/
if ((uart_mem_orig = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
printf("allocation error \n");
exit (-1);
}
extra = (unsigned long)uart_mem_orig % PAGE_SIZE;
if (extra)
uart_mem = uart_mem_orig + PAGE_SIZE - extra;
else
uart_mem = uart_mem_orig;
uart_map = (unsigned char *)mmap(
(caddr_t)uart_mem,
BLOCK_SIZE,
PROT_READ|PROT_WRITE,
MAP_SHARED|MAP_FIXED,
mem_fd,
UART0_BASE
);
if ((long)uart_map < 0) {
printf("uart mmap error %d\n", (int)uart_map);
exit (-1);
}
uart = (volatile unsigned *)uart_map;
} // setup_io
//
// Undo what we did above
//
void restore_io()
{
munmap(uart_map,BLOCK_SIZE);
munmap(spi0_map,BLOCK_SIZE);
munmap(pwm_map,BLOCK_SIZE);
munmap(gpio_map,BLOCK_SIZE);
munmap(clk_map,BLOCK_SIZE);
// free memory
free(uart_mem_orig);
free(spi0_mem_orig);
free(pwm_mem_orig);
free(gpio_mem_orig);
free(clk_mem_orig);
} // restore_io
// simple routine to convert the last several bits of an integer to a string
// showing its binary value
// nbits is the number of bits in i to look at
// i is integer we want to show as a binary number
// we only look at the nbits least significant bits of i and we assume that
// s is at least nbits+1 characters long
void make_binary_string(int nbits, int i, char *s)
{ char *p;
int bit;
p = s;
for (bit = 1 << (nbits-1); bit > 0; bit = bit >> 1, p++)
*p = (i & bit) ? '1' : '0';
*p = '\0';
}