#include "wmp.h" #include "i2c.h" #include "timer.h" #define UARTBASE 0xE000C000 #define RBR 0x00 #define THR 0x00 #define DLL 0x00 #define DLM 0x04 #define IER 0x04 #define IIR 0x08 #define FCR 0x08 #define LCR 0x0c #define LSR 0x14 #define SCR 0x1c #define ACR 0x20 #define FDR 0x28 #define TER 0x30 #define UREG(x) (((volatile unsigned char *)UARTBASE)[x]) #define U0THRE ((UREG(LSR) & (1<<5))) /* UART0 transmitter holding register is empty */ #define U0DR ((UREG(LSR) & (1<<0))) /* UART0 data ready */ #define PINSEL0 (*((volatile unsigned char *) 0xE002C000)) void init_uart(void) { UREG(FDR) = 0x10; /* DivAddVal = 0, MulVal = 1 */ UREG(LCR) = 0x80; UREG(DLM) = 0x00; UREG(DLL) = 0x08; /* 14745600 / (16*115200) */ UREG(LCR) = 0x13; UREG(FCR) = 0x07; } void init_pins(void) { PINSEL0 = 0x00000055; /* P0.0 and P0.1 assigned to UART */ /* P0.2 and P0.3 assigned to I2C */ } void putch(char c) { while (!U0THRE); UREG(THR) = c; } void putstr(char *s) { while (*s) putch(*s++); } void putint(unsigned int n) { char s[11]; int i; i = 10; s[i] = '\0'; do { s[--i] = n % 10 + '0'; } while ((n /= 10) > 0); putstr(s+i); } void puthex(unsigned int n) { char s[9]; int i; i = 8; s[i] = '\0'; do { int x = n % 16; if (x > 9) x += 'A' - '0' - 10; s[--i] = x + '0'; } while ((n /= 16) > 0); putstr(s+i); } char getch(void) { while (!U0DR); return UREG(RBR); } void reply(char *str) { putstr(str); putstr("\r\n"); } unsigned int count = 0; void minmax_sample(void) { int count; int fast_roll_min, fast_roll_max; int fast_pitch_min, fast_pitch_max; int fast_yaw_min, fast_yaw_max; int slow_roll_min, slow_roll_max; int slow_pitch_min, slow_pitch_max; int slow_yaw_min, slow_yaw_max; putstr("Sampling min/max values\r\n"); if (!wmp_sample()) { putstr("\r\nRead error\r\n"); return; } fast_roll_min = fast_roll_max = wmp_roll; fast_pitch_min = fast_pitch_max = wmp_pitch; fast_yaw_min = fast_yaw_max = wmp_yaw; slow_roll_min = slow_roll_max = wmp_roll; slow_pitch_min = slow_pitch_max = wmp_pitch; slow_yaw_min = slow_yaw_max = wmp_yaw; count = 0; while (1) { if (!wmp_sample()) { putstr("\r\nRead error\r\n"); return; } if (wmp_roll_fast) { if (wmp_roll < fast_roll_min) fast_roll_min = wmp_roll; if (wmp_roll > fast_roll_max) fast_roll_max = wmp_roll; } else { if (wmp_roll < slow_roll_min) slow_roll_min = wmp_roll; if (wmp_roll > slow_roll_max) slow_roll_max = wmp_roll; } if (wmp_pitch_fast) { if (wmp_pitch < fast_pitch_min) fast_pitch_min = wmp_pitch; if (wmp_pitch > fast_pitch_max) fast_pitch_max = wmp_pitch; } else { if (wmp_pitch < slow_pitch_min) slow_pitch_min = wmp_pitch; if (wmp_pitch > slow_pitch_max) slow_pitch_max = wmp_pitch; } if (wmp_yaw_fast) { if (wmp_yaw < fast_yaw_min) fast_yaw_min = wmp_yaw; if (wmp_yaw > fast_yaw_max) fast_yaw_max = wmp_yaw; } else { if (wmp_yaw < slow_yaw_min) slow_yaw_min = wmp_yaw; if (wmp_yaw > slow_yaw_max) slow_yaw_max = wmp_yaw; } count++; if (count > 1000) { putstr("("); puthex(slow_roll_min); putstr(", "); puthex(slow_pitch_min); putstr(", "); puthex(slow_yaw_min); putstr(") ("); puthex(slow_roll_max); putstr(", "); puthex(slow_pitch_max); putstr(", "); puthex(slow_yaw_max); putstr(") ("); puthex(fast_roll_min); putstr(", "); puthex(fast_pitch_min); putstr(", "); puthex(fast_yaw_min); putstr(") ("); puthex(fast_roll_max); putstr(", "); puthex(fast_pitch_max); putstr(", "); puthex(fast_yaw_max); putstr(") \r"); count = 0; } timer_delay_ms(2); } } void average_sample(void) { int i; int roll_total; int pitch_total; int yaw_total; putstr("Sampling average values\r\n"); roll_total = 0; pitch_total = 0; yaw_total = 0; for (i = 0; i < 0x1000; i++) { if (!wmp_sample()) { putstr("\r\nRead error\r\n"); return; } roll_total += wmp_roll; pitch_total += wmp_pitch; yaw_total += wmp_yaw; timer_delay_ms(2); } putstr("("); puthex(roll_total); putstr(", "); puthex(pitch_total); putstr(", "); puthex(yaw_total); putstr(")\r\n"); } int main(void) { int i; int data; init_uart(); init_i2c(); init_pins(); init_timer(); putstr("Your entire life has been a mathematical error... a mathematical error I'm about to correct!\r\n"); while (1) { char c; putstr("prompt> "); c = getch(); if (c == 0x0a) continue; putch(c); putstr("\r\n"); switch (c & 0xdf) { case 0x0a: case 0x0d: break; case 'A': reply("apple"); break; case 'C': count++; putstr("The current count is "); putint(count); reply("."); break; case 'H': case '?': reply("Help is not available. Try a psychiatrist."); break; case 'T': putstr("I2C status was: "); puthex(i2cstat); putstr(" I2C status is: "); puthex(i2c_statreg()); reply("."); putstr("I2C register is: "); puthex(i2c_conreg()); reply("."); break; case 'S': putstr("Sending START... "); if (i2c_send_start()) reply("OK"); else reply("FAIL"); break; case 'O': putstr("Sending STOP... "); i2c_send_stop(); reply("sent"); break; case 'I': putstr("Initialising WMP... "); if (wmp_init()) reply("done"); else reply("FAIL"); break; case 'M': putstr("Reading from WMP... "); if (wmp_sample()) { putstr("("); puthex(wmp_roll); putstr(", "); puthex(wmp_pitch); putstr(", "); puthex(wmp_yaw); reply(")."); } else reply("FAIL"); break; case 'L': minmax_sample(); break; case 'V': average_sample(); break; case 'D': putstr("Reading calibration data... "); if (wmp_read_calibration_data()) { putstr("\r\n"); for (i = 0; i < 0x10 ; i++) { puthex(wmp_calibration_data[i]); putstr(" "); } putstr("\r\n"); for (i = 0x10; i < 0x20 ; i++) { puthex(wmp_calibration_data[i]); putstr(" "); } putstr("\r\n"); } else { reply("FAIL"); } break; case 'N': putstr("The time is "); puthex(timer_read()); reply("."); break; default: reply("Unrecognised command."); break; } } return 0; }