Code for controlling mbed hardware (LED's, motors), as well as code for the Raspberry Pi to run a Support Vector Machine that identifies objects using the Pi camera
Dependencies: mbed Motordriver mbed-rtos PololuLedStrip
mbed/PololuLedStrip/PololuLedStrip.cpp
- Committer:
- arogliero3
- Date:
- 2019-12-05
- Revision:
- 0:e0dbd261724a
File content as of revision 0:e0dbd261724a:
#include "PololuLedStrip.h" // Our assembly code currently does not work with chip families like the STM32F4 // that use the same register and a different mask for setting and clearing // outputs. #ifdef GPIO_IP_WITHOUT_BRR #error This chip is not supported: does not have separate registers for setting and clearing GPIO outputs. #endif bool PololuLedStrip::interruptFriendly = false; // The two timed delays, in units of half-cycles. uint8_t led_strip_write_delays[2]; void PololuLedStrip::calculateDelays() { int f_mhz = SystemCoreClock / 1000000; // Clock frequency in MHz. if (f_mhz <= 48) { // The delays below result in 360/1120 ns pulses and a 1880 ns period on the mbed NXP LPC11U24. led_strip_write_delays[0] = 0; led_strip_write_delays[1] = 0; } else { // Try to generally compute what the delays should be for a wide range of clock frequencies. // The fudge factors below were experimentally chosen so that we would have // ~100 ns and ~840 ns pulses and a ~1430 ns period on the mbed NXP LPC1768 (96 MHz Cortex-M3). // There seem to be some ~100 ns inconsistencies in the timing depending on which example program is // running; the most likely explanation is some kind of flash caching that affects the timing. // If you ever change these numbers, it is important to check the the subtractions below // will not overflow in the worst case (smallest possible f_mhz). // // On an STM32F303K8 (72 MHz Cortex-M4), these delays give us ~170 ns and ~840 ns pulses // and a ~1595 ns period, and there were no timing differences between the two // example programs. led_strip_write_delays[0] = 750*f_mhz/1000 - 33; led_strip_write_delays[1] = 550*f_mhz/1000 - 20; } // Convert from units of cycles to units of half-cycles; it makes the assembly faster. led_strip_write_delays[0] <<= 1; led_strip_write_delays[1] <<= 1; } PololuLedStrip::PololuLedStrip(PinName pinName) { gpio_init_out(&gpio, pinName); } void PololuLedStrip::write(rgb_color * colors, unsigned int count) { calculateDelays(); __disable_irq(); // Disable interrupts temporarily because we don't want our pulse timing to be messed up. while(count--) { led_strip_write_color(colors, gpio.reg_set, gpio.reg_clr, gpio.mask); colors++; if (interruptFriendly) { __enable_irq(); __nop(); __nop(); __nop(); __disable_irq(); } } __enable_irq(); // Re-enable interrupts now that we are done. wait_us(80); // Send the reset signal. }