Mechazawa/pifm.c

## pifm.c
// To run:
//  wget -O - http://beta.etherpad.org/p/pihackfm/export/txt 2>/dev/null | gcc -lm -std=c99 -g -xc - && time ./a.out
// Access from ARM Running Linux

#define BCM2708_PERI_BASE        0x20000000
#define GPIO_BASE                (BCM2708_PERI_BASE + 0x200000) /* GPIO controller */


#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <dirent.h>
#include <math.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 *gpio_mem, *gpio_map;
char *spi0_mem, *spi0_map;


// I/O access
volatile unsigned *gpio;
volatile unsigned *allof7e;

// 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_SET *(gpio+7)  // sets   bits which are 1 ignores bits which are 0
#define GPIO_CLR *(gpio+10) // clears bits which are 1 ignores bits which are 0
#define GPIO_GET *(gpio+13)  // sets   bits which are 1 ignores bits which are 0

#define ACCESS(base) *(volatile int*)((int)allof7e+base-0x7e000000)
#define SETBIT(base, bit) ACCESS(base) |= 1<<bit
#define CLRBIT(base, bit) ACCESS(base) &= ~(1<<bit)

void setup_io();


#define CM_GP0CTL (0x7e101070)
#define GPFSEL0 (0x7E200000)
#define CM_GP0DIV (0x7e101074)
#define DMABASE (0x7E007000)

struct GPCTL {
    char SRC         : 4;
    char ENAB        : 1;
    char KILL        : 1;
    char             : 1;
    char BUSY        : 1;
    char FLIP        : 1;
    char MASH        : 2;
    unsigned int     : 13;
    char PASSWD      : 8;
};

void setup_fm()
{

    allof7e = (unsigned *)mmap(
                  NULL,
                  0x01000000,  //len
                  PROT_READ|PROT_WRITE,
                  MAP_SHARED,
                  mem_fd,
                  0x20000000  //base
              );

    if ((int)allof7e==-1) exit(-1);

    SETBIT(GPFSEL0 , 14);
    CLRBIT(GPFSEL0 , 13);
    CLRBIT(GPFSEL0 , 12);


    struct GPCTL setupword = {6/*SRC*/, 1, 0, 0, 0, 1,0x5a};

    ACCESS(CM_GP0CTL) = *((int*)&setupword);


}

/*
void delay(int i) {
    for(volatile unsigned int j = 1<<i; j; j--);
}
*/

void delay( int i)
{
    for(volatile unsigned int j = 1.25*(1<<i); j; j--);
}

void modulate(int m, double rawFreq)
{
    ACCESS(CM_GP0DIV) = (0x5a << 24) + round((500/rawFreq) * 16 * 16 * 16) + m;
    //ACCESS(CM_GP0DIV) = (0x5a << 24) + 0x5000 + m;
}


void playWav(char* filename, double freq)
{
    int fp = open(filename, 'r');
    int sz = lseek(fp, 0L, SEEK_END);
    lseek(fp, 0L, SEEK_SET);

    short* data = (short*)malloc(sz);
    read(fp, data, sz);
    unsigned int rnd=1;

    for (int j=22; j<sz/2; j++){ //while (read(fp, &data, 2)) {
        float dval = (float)(data[j])/65536.0*25.0;
        int intval = (int)(floor(dval));
        float frac = dval - (float)intval;
        unsigned int fracval = (unsigned int)(frac*((float)(1<<16))*((float)(1<<16)));

        for (int i=0; i<270; i++) {
          rnd = (rnd >> 1) ^ (-(rnd & 1u) & 0xD0000001u);
          modulate( intval + (fracval>rnd?1:0),freq);
        }
        //printf("%8f  %8x %8f  %08x\n", dval, intval,  frac, fracval);
        //delay(9);
    }

}

//the plan is:
//use PWM to trigger DMA transfer

struct CB {
    unsigned int TI;
    unsigned int SOURCE_AD;
    unsigned int DEST_AD;
    unsigned int TXFR_LEN;
    unsigned int STRIDE;
    unsigned int NEXTCONBK;
};

struct DMAregs {
    unsigned int CS;
    unsigned int CONBLK_AD;
    unsigned int TI;
    unsigned int SOURCE_AD;
    unsigned int DEST_AD;
    unsigned int TXFR_LEN;
    unsigned int STRIDE;
    unsigned int NEXTCONBK;
    unsigned int DEBUG;
};

/*
//TODO! Make DMA work. We decided that this needs to be a kernel mode driver
void setupDMA(){


DMAregs* DMA0 = &(ACCESS(DMABASE ));


//activate
DMA0->CS = (1<<20) | (1<<20) | 1
}
*/


int main(int argc, char **argv)
{
    int g,rep;

    // Set up gpi pointer for direct register access
    setup_io();

    // Switch GPIO 7..11 to output mode

    /************************************************************************\
     * You are about to change the GPIO settings of your computer.          *
     * Mess this up and it will stop working!                               *
     * It might be a good idea to 'sync' before running this program        *
     * so at least you still have your code changes written to the SD-card! *
    \************************************************************************/

    // Set GPIO pins 7-11 to output
    for (g=7; g<=11; g++) {
        INP_GPIO(g); // must use INP_GPIO before we can use OUT_GPIO
        //OUT_GPIO(g);
    }
    //Messy code...
    double freq = 100;
    if (argc==2)
        freq = atof(argv[2]);
    if (freq < 87.5 || freq > 108.0)
      freq = 100;

    setup_fm();
    modulate(0,freq);

    if (argc==2) //We must have 3 args due to the mod :P
      playWav(argv[1], freq);
    else
      fprintf(stderr, "Usage:   program wavfile.wav frequency\n\nWhere wavfile is 16 bit 44.1kHz Mono\nAnd the frequency between 87.5 and 108.0\n");

    return 0;

    //setup_DMA()

    /*
    int lastregs[9*15];
    int inuse[9*15];
    memset(&inuse, 0, 9*15*4);
    for(int i = 0; i < 1000000; i++)
        for (int ch = 0; ch <= 14; ch++)
            for (int reg = 0; reg <= 0x20/4; reg++) {
                int curr = ACCESS((DMABASE + 0x100*ch + reg*4));
                if (lastregs[ch*9+reg] != curr) {
                    inuse[ch*9+reg]++;
                    lastregs[ch*9+reg] = curr;
                }

                    //printf("addr %#010x:  %#010x\n",0x100*ch + reg, ACCESS(DMABASE + 0x100*ch + reg));
            }


    for (int ch = 0; ch <= 14; ch++)
        for (int reg = 0; reg <= 0x20/4; reg++)
            printf("addr %#010x inuse:  %#010x\n",0x100*ch + reg, inuse[ch*9+reg]);
    */

    printf("addr %#010x:  %#010x\n",0x200, ACCESS(DMABASE + 0x200));
    while(!(ACCESS(DMABASE + 0x200) & 0xF << 16));
    printf("addr %#010x:  %#010x\n",0x200, ACCESS(DMABASE + 0x200));


    /* printf("start\n");
     // frequency counter on gpio 7
     int oldval=0;
     for (int i=0; i<1000000;) {
        int newval = GPIO_GET & 1<<10;
        if (oldval^newval) {
            oldval=newval;
            i++;
            }

     };
     printf("done\n");
     return 0;
     */


    //Sawtooth wave!
    while(1) {
        for(int i = -40; i <= 40; i++) {
            modulate(i,freq);
            printf("Modulating: %d\n", i);
            delay(25);
        }
    }

    for (rep=0; rep<10; rep++) {
        for (g=7; g<=11; g++) {
            GPIO_SET = 1<<g;
        }
        sleep(1);
        for (g=7; g<=11; g++) {
            GPIO_CLR = 1<<g;
        }
        sleep(1);
    }

    return 0;

} // main


//
// Set up a memory regions to access GPIO
//
void setup_io()
{
    /* open /dev/mem */
    if ((mem_fd = open("/dev/mem", O_RDWR|O_SYNC) ) < 0) {
        printf("can't open /dev/mem \n");
        exit (-1);
    }

    /* mmap GPIO */

    // Allocate MAP block
    if ((gpio_mem = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
        printf("allocation error \n");
        exit (-1);
    }

    // Make sure pointer is on 4K boundary
    if ((unsigned long)gpio_mem % PAGE_SIZE)
        gpio_mem += PAGE_SIZE - ((unsigned long)gpio_mem % PAGE_SIZE);

    // Now map it
    gpio_map = (unsigned char *)mmap(
                   gpio_mem,
                   BLOCK_SIZE,
                   PROT_READ|PROT_WRITE,
                   MAP_SHARED|MAP_FIXED,
                   mem_fd,
                   GPIO_BASE
               );

    if ((long)gpio_map < 0) {
        printf("mmap error %d\n", (int)gpio_map);
        exit (-1);
    }

    // Always use volatile pointer!
    gpio = (volatile unsigned *)gpio_map;


} // setup_io
	// To run:
	// wget -O - http://beta.etherpad.org/p/pihackfm/export/txt 2>/dev/null \| gcc -lm -std=c99 -g -xc - && time ./a.out
	// Access from ARM Running Linux

	#define BCM2708_PERI_BASE 0x20000000
	#define GPIO_BASE (BCM2708_PERI_BASE + 0x200000) /* GPIO controller */


	#include <stdio.h>
	#include <string.h>
	#include <stdlib.h>
	#include <dirent.h>
	#include <math.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 gpio_mem, gpio_map;
	char spi0_mem, spi0_map;


	// I/O access
	volatile unsigned *gpio;
	volatile unsigned *allof7e;

	// 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_SET *(gpio+7) // sets bits which are 1 ignores bits which are 0
	#define GPIO_CLR *(gpio+10) // clears bits which are 1 ignores bits which are 0
	#define GPIO_GET *(gpio+13) // sets bits which are 1 ignores bits which are 0

	#define ACCESS(base) (volatile int)((int)allof7e+base-0x7e000000)
	#define SETBIT(base, bit) ACCESS(base) \|= 1<<bit
	#define CLRBIT(base, bit) ACCESS(base) &= ~(1<<bit)

	void setup_io();


	#define CM_GP0CTL (0x7e101070)
	#define GPFSEL0 (0x7E200000)
	#define CM_GP0DIV (0x7e101074)
	#define DMABASE (0x7E007000)

	struct GPCTL {
	char SRC : 4;
	char ENAB : 1;
	char KILL : 1;
	char : 1;
	char BUSY : 1;
	char FLIP : 1;
	char MASH : 2;
	unsigned int : 13;
	char PASSWD : 8;
	};

	void setup_fm()
	{

	allof7e = (unsigned *)mmap(
	NULL,
	0x01000000, //len
	PROT_READ\|PROT_WRITE,
	MAP_SHARED,
	mem_fd,
	0x20000000 //base
	);

	if ((int)allof7e==-1) exit(-1);

	SETBIT(GPFSEL0 , 14);
	CLRBIT(GPFSEL0 , 13);
	CLRBIT(GPFSEL0 , 12);


	struct GPCTL setupword = {6/SRC/, 1, 0, 0, 0, 1,0x5a};

	ACCESS(CM_GP0CTL) = ((int)&setupword);


	}

	/*
	void delay(int i) {
	for(volatile unsigned int j = 1<<i; j; j--);
	}
	*/

	void delay( int i)
	{
	for(volatile unsigned int j = 1.25*(1<<i); j; j--);
	}

	void modulate(int m, double rawFreq)
	{
	ACCESS(CM_GP0DIV) = (0x5a << 24) + round((500/rawFreq) * 16 * 16 * 16) + m;
	//ACCESS(CM_GP0DIV) = (0x5a << 24) + 0x5000 + m;
	}


	void playWav(char* filename, double freq)
	{
	int fp = open(filename, 'r');
	int sz = lseek(fp, 0L, SEEK_END);
	lseek(fp, 0L, SEEK_SET);

	short* data = (short*)malloc(sz);
	read(fp, data, sz);
	unsigned int rnd=1;

	for (int j=22; j<sz/2; j++){ //while (read(fp, &data, 2)) {
	float dval = (float)(data[j])/65536.0*25.0;
	int intval = (int)(floor(dval));
	float frac = dval - (float)intval;
	unsigned int fracval = (unsigned int)(frac((float)(1<<16))((float)(1<<16)));

	for (int i=0; i<270; i++) {
	rnd = (rnd >> 1) ^ (-(rnd & 1u) & 0xD0000001u);
	modulate( intval + (fracval>rnd?1:0),freq);
	}
	//printf("%8f %8x %8f %08x\n", dval, intval, frac, fracval);
	//delay(9);
	}

	}

	//the plan is:
	//use PWM to trigger DMA transfer

	struct CB {
	unsigned int TI;
	unsigned int SOURCE_AD;
	unsigned int DEST_AD;
	unsigned int TXFR_LEN;
	unsigned int STRIDE;
	unsigned int NEXTCONBK;
	};

	struct DMAregs {
	unsigned int CS;
	unsigned int CONBLK_AD;
	unsigned int TI;
	unsigned int SOURCE_AD;
	unsigned int DEST_AD;
	unsigned int TXFR_LEN;
	unsigned int STRIDE;
	unsigned int NEXTCONBK;
	unsigned int DEBUG;
	};

	/*
	//TODO! Make DMA work. We decided that this needs to be a kernel mode driver
	void setupDMA(){


	DMAregs* DMA0 = &(ACCESS(DMABASE ));


	//activate
	DMA0->CS = (1<<20) \| (1<<20) \| 1
	}
	*/


	int main(int argc, char **argv)
	{
	int g,rep;

	// Set up gpi pointer for direct register access
	setup_io();

	// Switch GPIO 7..11 to output mode

	/************************************************************************\
	* You are about to change the GPIO settings of your computer. *
	* Mess this up and it will stop working! *
	* It might be a good idea to 'sync' before running this program *
	* so at least you still have your code changes written to the SD-card! *
	\************************************************************************/

	// Set GPIO pins 7-11 to output
	for (g=7; g<=11; g++) {
	INP_GPIO(g); // must use INP_GPIO before we can use OUT_GPIO
	//OUT_GPIO(g);
	}
	//Messy code...
	double freq = 100;
	if (argc==2)
	freq = atof(argv[2]);
	if (freq < 87.5 \|\| freq > 108.0)
	freq = 100;

	setup_fm();
	modulate(0,freq);

	if (argc==2) //We must have 3 args due to the mod :P
	playWav(argv[1], freq);
	else
	fprintf(stderr, "Usage: program wavfile.wav frequency\n\nWhere wavfile is 16 bit 44.1kHz Mono\nAnd the frequency between 87.5 and 108.0\n");

	return 0;

	//setup_DMA()

	/*
	int lastregs[9*15];
	int inuse[9*15];
	memset(&inuse, 0, 9154);
	for(int i = 0; i < 1000000; i++)
	for (int ch = 0; ch <= 14; ch++)
	for (int reg = 0; reg <= 0x20/4; reg++) {
	int curr = ACCESS((DMABASE + 0x100ch + reg4));
	if (lastregs[ch*9+reg] != curr) {
	inuse[ch*9+reg]++;
	lastregs[ch*9+reg] = curr;
	}

	//printf("addr %#010x: %#010x\n",0x100ch + reg, ACCESS(DMABASE + 0x100ch + reg));
	}


	for (int ch = 0; ch <= 14; ch++)
	for (int reg = 0; reg <= 0x20/4; reg++)
	printf("addr %#010x inuse: %#010x\n",0x100ch + reg, inuse[ch9+reg]);
	*/

	printf("addr %#010x: %#010x\n",0x200, ACCESS(DMABASE + 0x200));
	while(!(ACCESS(DMABASE + 0x200) & 0xF << 16));
	printf("addr %#010x: %#010x\n",0x200, ACCESS(DMABASE + 0x200));


	/* printf("start\n");
	// frequency counter on gpio 7
	int oldval=0;
	for (int i=0; i<1000000;) {
	int newval = GPIO_GET & 1<<10;
	if (oldval^newval) {
	oldval=newval;
	i++;
	}

	};
	printf("done\n");
	return 0;
	*/


	//Sawtooth wave!
	while(1) {
	for(int i = -40; i <= 40; i++) {
	modulate(i,freq);
	printf("Modulating: %d\n", i);
	delay(25);
	}
	}

	for (rep=0; rep<10; rep++) {
	for (g=7; g<=11; g++) {
	GPIO_SET = 1<<g;
	}
	sleep(1);
	for (g=7; g<=11; g++) {
	GPIO_CLR = 1<<g;
	}
	sleep(1);
	}

	return 0;

	} // main


	//
	// Set up a memory regions to access GPIO
	//
	void setup_io()
	{
	/* open /dev/mem */
	if ((mem_fd = open("/dev/mem", O_RDWR\|O_SYNC) ) < 0) {
	printf("can't open /dev/mem \n");
	exit (-1);
	}

	/* mmap GPIO */

	// Allocate MAP block
	if ((gpio_mem = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) {
	printf("allocation error \n");
	exit (-1);
	}

	// Make sure pointer is on 4K boundary
	if ((unsigned long)gpio_mem % PAGE_SIZE)
	gpio_mem += PAGE_SIZE - ((unsigned long)gpio_mem % PAGE_SIZE);

	// Now map it
	gpio_map = (unsigned char *)mmap(
	gpio_mem,
	BLOCK_SIZE,
	PROT_READ\|PROT_WRITE,
	MAP_SHARED\|MAP_FIXED,
	mem_fd,
	GPIO_BASE
	);

	if ((long)gpio_map < 0) {
	printf("mmap error %d\n", (int)gpio_map);
	exit (-1);
	}

	// Always use volatile pointer!
	gpio = (volatile unsigned *)gpio_map;


	} // setup_io