#!/usr/bin/env python #*** WARNING ************************************************ #* * #* All the tests make extensive use of gpio 25 (pin 22). * #* Ensure that either nothing or just a LED is connected to * #* gpio 25 before running any of the tests. * #* * #* Some tests are statistical in nature and so may on * #* occasion fail. Repeated failures on the same test or * #* many failures in a group of tests indicate a problem. * #************************************************************ import sys import time import struct import pigpio GPIO=25 def STRCMP(r, s): if sys.hexversion > 0x03000000: if type(r) == type(""): r = bytearray(r, 'latin-1') if type(s) == type(""): s = bytearray(s, 'latin-1') if r != s: print(r, s) return 0 else: return 1 def CHECK(t, st, got, expect, pc, desc): if got >= (((1E2-pc)*expect)/1E2) and got <= (((1E2+pc)*expect)/1E2): print("TEST {:2d}.{:<2d} PASS ({}: {:d})".format(t, st, desc, expect)) else: print("TEST {:2d}.{:<2d} FAILED got {:d} ({}: {:d})". format(t, st, got, desc, expect)) def t0(): print("Version.") print("pigpio version {}.".format(pi.get_pigpio_version())) print("Hardware revision {}.".format(pi.get_hardware_revision())) print("Python version {}.".format(sys.version.replace("\n", " "))) def t1(): print("Mode/PUD/read/write tests.") pi.set_mode(GPIO, pigpio.INPUT) v = pi.get_mode(GPIO) CHECK(1, 1, v, 0, 0, "set mode, get mode") pi.set_pull_up_down(GPIO, pigpio.PUD_UP) v = pi.read(GPIO) CHECK(1, 2, v, 1, 0, "set pull up down, read") pi.set_pull_up_down(GPIO, pigpio.PUD_DOWN) v = pi.read(GPIO) CHECK(1, 3, v, 0, 0, "set pull up down, read") pi.write(GPIO, pigpio.LOW) v = pi.get_mode(GPIO) CHECK(1, 4, v, 1, 0, "write, get mode") v = pi.read(GPIO) CHECK(1, 5, v, 0, 0, "read") pi.write(GPIO, pigpio.HIGH) v = pi.read(GPIO) CHECK(1, 6, v, 1, 0, "write, read") t2_count=0 def t2cbf(gpio, level, tick): global t2_count t2_count += 1 def t2(): global t2_count print("PWM dutycycle/range/frequency tests.") pi.set_PWM_range(GPIO, 255) pi.set_PWM_frequency(GPIO,0) f = pi.get_PWM_frequency(GPIO) CHECK(2, 1, f, 10, 0, "set PWM range, set/get PWM frequency") t2cb = pi.callback(GPIO, pigpio.EITHER_EDGE, t2cbf) pi.set_PWM_dutycycle(GPIO, 0) dc = pi.get_PWM_dutycycle(GPIO) CHECK(2, 2, dc, 0, 0, "get PWM dutycycle") time.sleep(0.5) # allow old notifications to flush oc = t2_count time.sleep(2) f = t2_count - oc CHECK(2, 3, f, 0, 0, "set PWM dutycycle, callback") pi.set_PWM_dutycycle(GPIO, 128) dc = pi.get_PWM_dutycycle(GPIO) CHECK(2, 4, dc, 128, 0, "get PWM dutycycle") time.sleep(1) oc = t2_count time.sleep(2) f = t2_count - oc CHECK(2, 5, f, 40, 10, "set PWM dutycycle, callback") pi.set_PWM_frequency(GPIO,100) f = pi.get_PWM_frequency(GPIO) CHECK(2, 6, f, 100, 0, "set/get PWM frequency") time.sleep(1) oc = t2_count time.sleep(2) f = t2_count - oc CHECK(2, 7, f, 400, 5, "callback") pi.set_PWM_frequency(GPIO,1000) f = pi.get_PWM_frequency(GPIO) CHECK(2, 8, f, 1000, 0, "set/get PWM frequency") time.sleep(1) oc = t2_count time.sleep(2) f = t2_count - oc CHECK(2, 9, f, 4000, 5, "callback") r = pi.get_PWM_range(GPIO) CHECK(2, 10, r, 255, 0, "get PWM range") rr = pi.get_PWM_real_range(GPIO) CHECK(2, 11, rr, 200, 0, "get PWM real range") pi.set_PWM_range(GPIO, 2000) r = pi.get_PWM_range(GPIO) CHECK(2, 12, r, 2000, 0, "set/get PWM range") rr = pi.get_PWM_real_range(GPIO) CHECK(2, 13, rr, 200, 0, "get PWM real range") pi.set_PWM_dutycycle(GPIO, 0) t2cb.cancel() t3_reset=True t3_count=0 t3_tick=0 t3_on=0.0 t3_off=0.0 def t3cbf(gpio, level, tick): global t3_reset, t3_count, t3_tick, t3_on, t3_off if t3_reset: t3_count = 0 t3_on = 0.0 t3_off = 0.0 t3_reset = False else: td = pigpio.tickDiff(t3_tick, tick) if level == 0: t3_on += td else: t3_off += td t3_count += 1 t3_tick = tick def t3(): global t3_reset, t3_count, t3_on, t3_off pw=[500.0, 1500.0, 2500.0] dc=[0.2, 0.4, 0.6, 0.8] print("PWM/Servo pulse accuracy tests.") t3cb = pi.callback(GPIO, pigpio.EITHER_EDGE, t3cbf) t = 0 for x in pw: t += 1 pi.set_servo_pulsewidth(GPIO, x) v = pi.get_servo_pulsewidth(GPIO) CHECK(3, t, v, int(x), 0, "get servo pulsewidth") t += 1 time.sleep(1) t3_reset = True time.sleep(4) c = t3_count on = t3_on off = t3_off CHECK(3, t, int((1E3*(on+off))/on), int(2E7/x), 1, "set servo pulsewidth") pi.set_servo_pulsewidth(GPIO, 0) pi.set_PWM_frequency(GPIO, 1000) f = pi.get_PWM_frequency(GPIO) CHECK(3, 7, f, 1000, 0, "set/get PWM frequency") rr = pi.set_PWM_range(GPIO, 100) CHECK(3, 8, rr, 200, 0, "set PWM range") t = 8 for x in dc: t += 1 pi.set_PWM_dutycycle(GPIO, x*100) v = pi.get_PWM_dutycycle(GPIO) CHECK(3, t, v, int(x*100), 0, "get PWM dutycycle") t += 1 time.sleep(1) t3_reset = True time.sleep(2) c = t3_count on = t3_on off = t3_off CHECK(3, t, int((1E3*on)/(on+off)), int(1E3*x), 1, "set PWM dutycycle") pi.set_PWM_dutycycle(GPIO, 0) t3cb.cancel() def t4(): print("Pipe notification tests.") pi.set_PWM_frequency(GPIO, 0) pi.set_PWM_dutycycle(GPIO, 0) pi.set_PWM_range(GPIO, 100) h = pi.notify_open() e = pi.notify_begin(h, (1<=0, 1, 0, "serial open") (b, s) = pi.serial_read(h, 1000) # flush buffer b = pi.serial_data_available(h) CHECK(10, 2, b, 0, 0, "serial data available") TEXT = """ To be, or not to be, that is the question- Whether 'tis Nobler in the mind to suffer The Slings and Arrows of outrageous Fortune, Or to take Arms against a Sea of troubles, """ e = pi.serial_write(h, TEXT) CHECK(10, 3, e, 0, 0, "serial write") e = pi.serial_write_byte(h, 0xAA) e = pi.serial_write_byte(h, 0x55) e = pi.serial_write_byte(h, 0x00) e = pi.serial_write_byte(h, 0xFF) CHECK(10, 4, e, 0, 0, "serial write byte") time.sleep(0.1) # allow time for transmission b = pi.serial_data_available(h) CHECK(10, 5, b, len(TEXT)+4, 0, "serial data available") (b, text) = pi.serial_read(h, len(TEXT)) CHECK(10, 6, b, len(TEXT), 0, "serial read") CHECK(10, 7, STRCMP(text, TEXT), True, 0, "serial read") b = pi.serial_read_byte(h) CHECK(10, 8, b, 0xAA, 0, "serial read byte") b = pi.serial_read_byte(h) CHECK(10, 9, b, 0x55, 0, "serial read byte") b = pi.serial_read_byte(h) CHECK(10, 10, b, 0x00, 0, "serial read byte") b = pi.serial_read_byte(h) CHECK(10, 11, b, 0xFF, 0, "serial read byte") b = pi.serial_data_available(h) CHECK(10, 12, b, 0, 0, "serial data available") e = pi.serial_close(h) CHECK(10, 13, e, 0, 0, "serial close") def tb(): print("SMBus / I2C tests.") # this test requires an ADXL345 on I2C bus 1 addr 0x53 h = pi.i2c_open(1, 0x53) CHECK(11, 1, h>=0, 1, 0, "i2c open") e = pi.i2c_write_device(h, "\x00") # move to known register CHECK(11, 2, e, 0, 0, "i2c write device") (b, d) = pi.i2c_read_device(h, 1) CHECK(11, 3, b, 1, 0, "i2c read device") CHECK(11, 4, ord(d), 0xE5, 0, "i2c read device") b = pi.i2c_read_byte(h) CHECK(11, 5, b, 0xE5, 0, "i2c read byte") b = pi.i2c_read_byte_data(h, 0) CHECK(11, 6, b, 0xE5, 0, "i2c read byte data") b = pi.i2c_read_byte_data(h, 48) CHECK(11, 7, b, 2, 0, "i2c read byte data") exp = b"[aB\x08cD\xAAgHj\xFD]" e = pi.i2c_write_device(h, b'\x1D'+ exp) CHECK(11, 8, e, 0, 0, "i2c write device") e = pi.i2c_write_device(h, '\x1D') (b, d) = pi.i2c_read_device(h, 12) CHECK(11, 9, b, 12, 0, "i2c read device") CHECK(11, 10, STRCMP(d, exp), True, 0, "i2c read device") e = pi.i2c_write_byte_data(h, 0x1d, 0xAA) CHECK(11, 11, e, 0, 0, "i2c write byte data") b = pi.i2c_read_byte_data(h, 0x1d) CHECK(11, 12, b, 0xAA, 0, "i2c read byte data") e = pi.i2c_write_byte_data(h, 0x1d, 0x55) CHECK(11, 13, e, 0, 0, "i2c write byte data") b = pi.i2c_read_byte_data(h, 0x1d) CHECK(11, 14, b, 0x55, 0, "i2c read byte data") exp = "[1234567890#]" e = pi.i2c_write_block_data(h, 0x1C, exp) CHECK(11, 15, e, 0, 0, "i2c write block data") e = pi.i2c_write_device(h, '\x1D') (b, d) = pi.i2c_read_device(h, 13) CHECK(11, 16, b, 13, 0, "i2c read device") CHECK(11, 17, STRCMP(d, exp), True, 0, "i2c read device") (b, d) = pi.i2c_read_i2c_block_data(h, 0x1D, 13) CHECK(11, 18, b, 13, 0, "i2c read i2c block data") CHECK(11, 19, STRCMP(d, exp), True, 0, "i2c read i2c block data") expl = [0x01, 0x05, 0x06, 0x07, 0x09, 0x1B, 0x99, 0xAA, 0xBB, 0xCC] exp = "\x01\x05\x06\x07\x09\x1B\x99\xAA\xBB\xCC" e = pi.i2c_write_i2c_block_data(h, 0x1D, expl) CHECK(11, 20, e, 0, 0, "i2c write i2c block data") (b, d) = pi.i2c_read_i2c_block_data(h, 0x1D, 10) CHECK(11, 21, b, 10, 0, "i2c read i2c block data") CHECK(11, 22, STRCMP(d, exp), True, 0, "i2c read i2c block data") e = pi.i2c_close(h) CHECK(11, 23, e, 0, 0, "i2c close") def tca(b, d): if b == 3: c1 = d[1] & 0x0F c2 = d[2] time.sleep(1.0) print((c1*256)+c2) def tc(): print("SPI tests.") # this test requires a MCP3202 on SPI channel 1 h = pi.spi_open(1, 50000) CHECK(12, 1, h>=0, 1, 0, "spi open") (b, d) = pi.spi_xfer(h, [1,128,0]) CHECK(12, 2, b, 3, 0, "spi xfer") tca(b, d) (b, d) = pi.spi_xfer(h, "\x01\x80\x00") CHECK(12, 2, b, 3, 0, "spi xfer") tca(b, d) (b, d) = pi.spi_xfer(h, b"\x01\x80\x00") CHECK(12, 2, b, 3, 0, "spi xfer") tca(b, d) (b, d) = pi.spi_xfer(h, '\x01\x80\x00') CHECK(12, 2, b, 3, 0, "spi xfer") tca(b, d) (b, d) = pi.spi_xfer(h, b'\x01\x80\x00') CHECK(12, 2, b, 3, 0, "spi xfer") tca(b, d) e = pi.spi_close(h) CHECK(12, 99, e, 0, 0, "spi close") def td(): print("Wavechains & filter tests.") tdcb = pi.callback(GPIO) pi.set_mode(GPIO, pigpio.OUTPUT) pi.write(GPIO, pigpio.LOW) e = pi.wave_clear() CHECK(13, 1, e, 0, 0, "callback, set mode, wave clear") wf = [] wf.append(pigpio.pulse(1< 1: tests = "" for C in sys.argv[1]: c = C.lower() if c not in tests: tests += c else: tests = "0123456789d" pi = pigpio.pi() if pi.connected: print("Connected to pigpio daemon.") if '0' in tests: t0() if '1' in tests: t1() if '2' in tests: t2() if '3' in tests: t3() if '4' in tests: t4() if '5' in tests: t5() if '6' in tests: t6() if '7' in tests: t7() if '8' in tests: t8() if '9' in tests: t9() if 'a' in tests: ta() if 'b' in tests: tb() if 'c' in tests: tc() if 'd' in tests: td() pi.stop()