// Copyright 2017 David Conran #ifndef TEST_IRSEND_TEST_H_ #define TEST_IRSEND_TEST_H_ #define __STDC_LIMIT_MACROS #include #include #include #include #include "IRrecv.h" #include "IRsend.h" #include "IRtimer.h" #define OUTPUT_BUF 10000U #define RAW_BUF 10000U #ifdef UNIT_TEST // Used to help simulate elapsed time in unit tests. uint32_t _IRtimer_unittest_now = 0; #endif // UNIT_TEST class IRsendTest : public IRsend { public: uint32_t output[OUTPUT_BUF]; uint16_t last; uint16_t rawbuf[RAW_BUF]; decode_results capture; explicit IRsendTest(uint16_t x, bool i = false, bool j = true) : IRsend(x, i, j) { reset(); } void reset() { last = 0; for (uint16_t i = 0; i < OUTPUT_BUF; i++) output[i] = 0; for (uint16_t i = 0; i < RAW_BUF; i++) rawbuf[i] = 0; } std::string outputStr() { std::stringstream result; if (last == 0 && output[0] == 0) return ""; for (uint16_t i = 0; i <= last; i++) { if ((i & 1) != outputOff) // Odd XOR outputOff result << "s"; else result << "m"; result << output[i]; } reset(); return result.str(); } void makeDecodeResult(uint16_t offset = 0) { capture.decode_type = UNKNOWN; capture.bits = 0; capture.rawlen = last + 2 - offset; capture.overflow = (last - offset >= (int16_t)RAW_BUF); capture.repeat = false; capture.address = 0; capture.command = 0; capture.value = 0; capture.rawbuf = rawbuf; for (uint16_t i = 0; (i < RAW_BUF - 1) && (offset < OUTPUT_BUF); i++, offset++) if (output[offset] / kRawTick > UINT16_MAX) rawbuf[i + 1] = UINT16_MAX; else rawbuf[i + 1] = output[offset] / kRawTick; } void dumpRawResult() { std::cout << std::dec; if (capture.rawlen == 0) return; std::cout << "uint16_t rawbuf[" << capture.rawlen - 1 << "] = {"; for (uint16_t i = 1; i < capture.rawlen; i++) { if (i % 8 == 1) std::cout << std::endl << " "; std::cout << (capture.rawbuf[i] * kRawTick); // std::cout << "(" << capture.rawbuf[i] << ")"; if (i < capture.rawlen - 1) std::cout << ", "; } std::cout << "};" << std::endl; } void addGap(uint32_t usecs) { space(usecs); } uint16_t mark(uint16_t usec) { IRtimer::add(usec); if (last >= OUTPUT_BUF) return 0; if (last & 1) // Is odd? (i.e. last call was a space()) output[++last] = usec; else output[last] += usec; return 0; } void space(uint32_t time) { IRtimer::add(time); if (last >= OUTPUT_BUF) return; if (last & 1) { // Is odd? (i.e. last call was a space()) output[last] += time; } else { output[++last] = time; } } }; #ifdef UNIT_TEST class IRsendLowLevelTest : public IRsend { public: std::string low_level_sequence; explicit IRsendLowLevelTest(uint16_t x, bool i = false, bool j = true) : IRsend(x, i, j) { reset(); } void reset() { low_level_sequence = ""; } protected: void _delayMicroseconds(uint32_t usec) { _IRtimer_unittest_now += usec; std::ostringstream Convert; Convert << usec; low_level_sequence += Convert.str() + "usecs"; } void ledOff() { low_level_sequence += "[Off]"; } void ledOn() { low_level_sequence += "[On]"; } }; #endif // UNIT_TEST #endif // TEST_IRSEND_TEST_H_