Files
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blinds / hardware_design / pcb / blinds_v60.brd
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blinds / hardware_design / pcb / blinds_v60.sch
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braids / hardware_design / pcb / braids_v50.brd
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braids / hardware_design / pcb / braids_v50.sch
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branches / hardware_design / pcb / branches_v40.brd
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branches / hardware_design / pcb / branches_v40.sch
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clouds / hardware_design / pcb / clouds_v30.brd
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clouds / hardware_design / pcb / clouds_v30.sch
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ears / hardware_design / panel / ears_panel_v30.brd
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ears / hardware_design / panel / ears_panel_v30.sch
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ears / hardware_design / pcb / ears_v40.brd
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ears / hardware_design / pcb / ears_v40.sch
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edges / hardware_design / pcb / edges_expander_v01.brd
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edges / hardware_design / pcb / edges_expander_v01.sch
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edges / hardware_design / pcb / edges_v20.brd
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edges / hardware_design / pcb / edges_v20.sch
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elements / hardware_design / pcb / elements_v02.brd
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elements / hardware_design / pcb / elements_v02.sch
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frames / hardware_design / pcb / frames_v03.brd
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frames / hardware_design / pcb / frames_v03.sch
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grids / hardware_design / pcb / grids_v02.brd
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grids / hardware_design / pcb / grids_v02.sch
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kinks / hardware_design / pcb / kinks_v41.brd
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kinks / hardware_design / pcb / kinks_v41.sch
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links / hardware_design / pcb / links_v40.brd
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links / hardware_design / pcb / links_v40.sch
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marbles / hardware_design / pcb / marbles_v70.brd
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marbles / hardware_design / pcb / marbles_v70.sch
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peaks / hardware_design / pcb / peaks_v30.brd
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peaks / hardware_design / pcb / peaks_v30.sch
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plaits / hardware_design / pcb / plaits_v50.brd
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plaits / hardware_design / pcb / plaits_v50.sch
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rings / hardware_design / pcb / rings_v30.brd
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rings / hardware_design / pcb / rings_v30.sch
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ripples / hardware_design / pcb / ripples_v40.brd
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ripples / hardware_design / pcb / ripples_v40.sch
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shades / hardware_design / pcb / shades_v30.brd
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shades / hardware_design / pcb / shades_v30.sch
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shelves / hardware_design / pcb / shelves_expander_v10.brd
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shelves / hardware_design / pcb / shelves_expander_v10.sch
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shelves / hardware_design / pcb / shelves_v05.brd
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shelves / hardware_design / pcb / shelves_v05.sch
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stages / hardware_design / pcb / stages_v70.brd
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stages / hardware_design / pcb / stages_v70.sch
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streams / hardware_design / pcb / streams_v02_bargraph.brd
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streams / hardware_design / pcb / streams_v02_bargraph.sch
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streams / hardware_design / pcb / streams_v05.brd
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streams / hardware_design / pcb / streams_v05.sch
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tides / hardware_design / pcb / tides_v40.brd
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tides / hardware_design / pcb / tides_v40.sch
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veils / hardware_design / pcb / veils_v40.brd
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veils / hardware_design / pcb / veils_v40.sch
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volts / hardware_design / pcb / volts_v01.brd
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volts / hardware_design / pcb / volts_v01.sch
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warps / hardware_design / pcb / warps_v30.brd
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warps / hardware_design / pcb / warps_v30.sch
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yarns / hardware_design / pcb / yarns_v03.brd
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yarns / hardware_design / pcb / yarns_v03.sch
Last update 6 years 1 month
by
Olivier Gillet
Filesbranches | |
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bootloader | |
hardware_design | |
branches.cc | |
makefile |
branches.cc// Copyright 2012 Olivier Gillet. // // Author: Olivier Gillet (ol.gillet@gmail.com) // // 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 3 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, see <http://www.gnu.org/licenses/>. #include <avr/eeprom.h> #include <avr/pgmspace.h> #include "avrlib/adc.h" #include "avrlib/boot.h" #include "avrlib/gpio.h" #include "avrlib/watchdog_timer.h" using namespace avrlib; enum LedState { LED_STATE_OFF, LED_STATE_RED, LED_STATE_GREEN }; Gpio<PortD, 4> in_1; Gpio<PortD, 3> out_1_a; Gpio<PortD, 0> out_1_b; Gpio<PortD, 1> led_1_a; Gpio<PortD, 2> led_1_k; Gpio<PortD, 7> in_2; Gpio<PortD, 6> out_2_a; Gpio<PortD, 5> out_2_b; Gpio<PortB, 1> led_2_a; Gpio<PortB, 0> led_2_k; Gpio<PortC, 2> switch_2; Gpio<PortC, 3> switch_1; Adc adc; const uint16_t kLongPressTime = 6250; // 800 * 8000 / 1024 const uint16_t kLedGateDelay = 0x1ff; static uint8_t adc_channel; static uint16_t p[2]; bool toggle_mode[2]; bool latch_mode[2]; bool input_state[2]; bool previous_state[2]; bool switch_state[2]; bool inhibit_switch[2]; uint16_t press_time[2]; uint8_t led_state[2]; uint16_t led_gate_delay[2]; uint32_t rng_state; const prog_uint16_t linear_table[] PROGMEM = { 0, 0, 259, 518, 777, 1036, 1295, 1554, 1813, 2072, 2331, 2590, 2849, 3108, 3367, 3626, 3885, 4145, 4404, 4663, 4922, 5181, 5440, 5699, 5958, 6217, 6476, 6735, 6994, 7253, 7512, 7771, 8030, 8289, 8548, 8807, 9066, 9325, 9584, 9843, 10102, 10361, 10620, 10879, 11138, 11397, 11656, 11915, 12174, 12434, 12693, 12952, 13211, 13470, 13729, 13988, 14247, 14506, 14765, 15024, 15283, 15542, 15801, 16060, 16319, 16578, 16837, 17096, 17355, 17614, 17873, 18132, 18391, 18650, 18909, 19168, 19427, 19686, 19945, 20204, 20463, 20723, 20982, 21241, 21500, 21759, 22018, 22277, 22536, 22795, 23054, 23313, 23572, 23831, 24090, 24349, 24608, 24867, 25126, 25385, 25644, 25903, 26162, 26421, 26680, 26939, 27198, 27457, 27716, 27975, 28234, 28493, 28753, 29012, 29271, 29530, 29789, 30048, 30307, 30566, 30825, 31084, 31343, 31602, 31861, 32120, 32379, 32638, 32897, 33156, 33415, 33674, 33933, 34192, 34451, 34710, 34969, 35228, 35487, 35746, 36005, 36264, 36523, 36782, 37042, 37301, 37560, 37819, 38078, 38337, 38596, 38855, 39114, 39373, 39632, 39891, 40150, 40409, 40668, 40927, 41186, 41445, 41704, 41963, 42222, 42481, 42740, 42999, 43258, 43517, 43776, 44035, 44294, 44553, 44812, 45072, 45331, 45590, 45849, 46108, 46367, 46626, 46885, 47144, 47403, 47662, 47921, 48180, 48439, 48698, 48957, 49216, 49475, 49734, 49993, 50252, 50511, 50770, 51029, 51288, 51547, 51806, 52065, 52324, 52583, 52842, 53101, 53361, 53620, 53879, 54138, 54397, 54656, 54915, 55174, 55433, 55692, 55951, 56210, 56469, 56728, 56987, 57246, 57505, 57764, 58023, 58282, 58541, 58800, 59059, 59318, 59577, 59836, 60095, 60354, 60613, 60872, 61131, 61390, 61650, 61909, 62168, 62427, 62686, 62945, 63204, 63463, 63722, 63981, 64240, 64499, 64758, 65017, 65276, 65535, 65535, }; void Init() { Gpio<PortB, 4>::set_mode(DIGITAL_OUTPUT); Gpio<PortB, 4>::Low(); in_1.set_mode(DIGITAL_INPUT); in_2.set_mode(DIGITAL_INPUT); in_1.High(); in_2.High(); switch_1.set_mode(DIGITAL_INPUT); switch_2.set_mode(DIGITAL_INPUT); switch_1.High(); switch_2.High(); out_1_a.set_mode(DIGITAL_OUTPUT); out_1_b.set_mode(DIGITAL_OUTPUT); led_1_a.set_mode(DIGITAL_OUTPUT); led_1_k.set_mode(DIGITAL_OUTPUT); out_2_a.set_mode(DIGITAL_OUTPUT); out_2_b.set_mode(DIGITAL_OUTPUT); led_2_a.set_mode(DIGITAL_OUTPUT); led_2_k.set_mode(DIGITAL_OUTPUT); led_1_a.Low(); led_2_a.Low(); led_1_k.Low(); led_2_k.Low(); adc.Init(); adc.set_reference(ADC_DEFAULT); adc.set_alignment(ADC_LEFT_ALIGNED); adc.StartConversion(0); uint8_t configuration_byte = ~eeprom_read_byte((uint8_t*) 0); toggle_mode[0] = configuration_byte & 1; latch_mode[0] = configuration_byte & 2; toggle_mode[1] = configuration_byte & 4; latch_mode[1] = configuration_byte & 8; led_state[0] = led_state[1] = 0; switch_state[0] = switch_state[1] = false; TCCR1A = 0; TCCR1B = 5; } bool Read(uint8_t channel) { return channel == 0 ? !in_1.value() : !in_2.value(); } bool ReadSwitch(uint8_t channel) { return channel == 0 ? !switch_1.value() : !switch_2.value(); } void GateOn(uint8_t channel, bool outcome) { if (channel == 0) { if (outcome) { out_1_a.Low(); out_1_b.High(); } else { out_1_a.High(); out_1_b.Low(); } } else { if (outcome) { out_2_a.Low(); out_2_b.High(); } else { out_2_a.High(); out_2_b.Low(); } } } void GateOff(uint8_t channel) { if (channel == 0) { out_1_a.Low(); out_1_b.Low(); } else { out_2_a.Low(); out_2_b.Low(); } } void LedOff(uint8_t channel) { if (channel == 0) { led_1_a.Low(); led_1_k.Low(); } else { led_2_a.Low(); led_2_k.Low(); } } void DisplayConfigurationAndSave(uint8_t channel) { uint8_t configuration_byte = 0; if (toggle_mode[0]) configuration_byte |= 1; if (latch_mode[0]) configuration_byte |= 2; if (toggle_mode[1]) configuration_byte |= 4; if (latch_mode[1]) configuration_byte |= 8; eeprom_write_byte((uint8_t*) 0, ~configuration_byte); } int main(void) { ResetWatchdog(); Init(); input_state[0] = input_state[1] = false; rng_state = 1; while (1) { // Whenever an ADC cycle is finished, update the probability variables. if (adc.ready()) { uint8_t channel_index = 1 - adc_channel; // ADC pins are swapped! p[channel_index] = pgm_read_word(linear_table + adc.ReadOut8()); adc_channel = (adc_channel + 1) & 1; adc.StartConversion(adc_channel); } // Scan switches for (uint8_t i = 0; i < 2; ++i) { bool new_input_state = ReadSwitch(i); if (!switch_state[i] && new_input_state) { press_time[i] = TCNT1; inhibit_switch[i] = false; } if (switch_state[i] && !inhibit_switch[i]) { uint16_t this_press_time = TCNT1 - press_time[i]; if (this_press_time >= kLongPressTime) { inhibit_switch[i] = true; latch_mode[i] = !latch_mode[i]; DisplayConfigurationAndSave(i); } else if (this_press_time >= 64 && !new_input_state) { toggle_mode[i] = !toggle_mode[i]; DisplayConfigurationAndSave(i); } } switch_state[i] = new_input_state; } // Scan inputs uint32_t random_words = rng_state; for (uint8_t i = 0; i < 2; ++i) { bool new_input_state = Read(i); if (new_input_state || latch_mode[i]) { // Hold the LED while the trigger is high or when in latch mode led_gate_delay[i] = kLedGateDelay; } if (new_input_state && !input_state[i] /* Rising edge */) { uint16_t random = random_words & 0xffff; uint16_t threshold = p[i]; bool outcome = random >= threshold && threshold != 65535; if (toggle_mode[i]) { outcome = outcome ^ previous_state[i]; } previous_state[i] = outcome; GateOn(i, outcome); led_state[i] = outcome ? 1 : 2; } else if (!new_input_state && input_state[i] && !latch_mode[i]) { GateOff(i); } input_state[i] = new_input_state; random_words >>= 16; if (led_gate_delay[i]) { --led_gate_delay[i]; if (!led_gate_delay[i]) { led_state[i] = 0; } } } // Refresh LEDs if (led_state[0] == 0) { led_1_a.Low(); led_1_k.Low(); } else if (led_state[0] == 1) { led_1_a.Low(); led_1_k.High(); } else { led_1_a.High(); led_1_k.Low(); } if (led_state[1] == 0) { led_2_a.Low(); led_2_k.Low(); } else if (led_state[1] == 1) { led_2_a.Low(); led_2_k.High(); } else { led_2_a.High(); led_2_k.Low(); } // rng_state = rng_state * 1664525 + 1013904223; rng_state = (rng_state >> 1) ^ (-(rng_state & 1u) & 0xD0000001u); } }