// Copyright 2017, 2018 David Conran #include "ir_Panasonic.h" #include "IRac.h" #include "IRrecv.h" #include "IRrecv_test.h" #include "IRsend.h" #include "IRsend_test.h" #include "IRtext.h" #include "IRutils.h" #include "gtest/gtest.h" // Tests for encodePanasonic(). TEST(TestEncodePanasonic, General) { IRsendTest irsend(4); EXPECT_EQ(0x0, irsend.encodePanasonic(0, 0, 0, 0)); EXPECT_EQ(0x101010101, irsend.encodePanasonic(1, 1, 1, 1)); EXPECT_EQ(0xFFFF, irsend.encodePanasonic(0, 0, 0, 0xFF)); EXPECT_EQ(0xFF00FF, irsend.encodePanasonic(0, 0, 0xFF, 0)); EXPECT_EQ(0xFF0000FF, irsend.encodePanasonic(0, 0xFF, 0, 0)); EXPECT_EQ(0xFFFF00000000, irsend.encodePanasonic(0xFFFF, 0, 0, 0)); EXPECT_EQ(0xFFFFFFFFFFFF, irsend.encodePanasonic(0xFFFF, 0xFF, 0xFF, 0xFF)); EXPECT_EQ(0x40040190ED7C, irsend.encodePanasonic(0x4004, 0x01, 0x90, 0xED)); } // Tests for sendPanasonic64(). // Test sending typical data only. TEST(TestSendPanasonic64, SendDataOnly) { IRsendTest irsend(4); irsend.begin(); irsend.reset(); irsend.sendPanasonic64(0x0); EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s116208", irsend.outputStr()); irsend.reset(); irsend.sendPanasonic64(0x40040190ED7C); EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384", irsend.outputStr()); irsend.reset(); irsend.sendPanasonic64(0xFFFFFFFFFFFF); EXPECT_EQ( "f36700d50" "m3456s1728" "m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296" "m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296" "m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296" "m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296" "m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296" "m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296m432s1296" "m432s74736", irsend.outputStr()); } // Test sending with different repeats. TEST(TestSendPanasonic64, SendWithRepeats) { IRsendTest irsend(4); irsend.begin(); irsend.reset(); irsend.sendPanasonic64(0x40040190ED7C, kPanasonicBits, 0); // 0 repeats. EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384", irsend.outputStr()); irsend.reset(); irsend.sendPanasonic64(0x40040190ED7C, kPanasonicBits, 1); // 1 repeat. EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384", irsend.outputStr()); irsend.sendPanasonic64(0x40040190ED7C, kPanasonicBits, 2); // 2 repeats. EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s432m432s1296" "m432s432m432s1296m432s1296m432s1296m432s1296m432s1296m432s432m432s432" "m432s102384", irsend.outputStr()); } // Test sending an atypical data size. TEST(TestSendPanasonic64, SendUnusualSize) { IRsendTest irsend(4); irsend.begin(); irsend.reset(); irsend.sendPanasonic64(0x0, 8); EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s150768", irsend.outputStr()); irsend.reset(); irsend.sendPanasonic64(0x1234567890ABCDEF, 64); EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s432m432s432m432s1296m432s432m432s432m432s1296m432s432" "m432s432m432s432m432s1296m432s1296m432s432m432s1296m432s432m432s432" "m432s432m432s1296m432s432m432s1296m432s432m432s1296m432s1296m432s432" "m432s432m432s1296m432s1296m432s1296m432s1296m432s432m432s432m432s432" "m432s1296m432s432m432s432m432s1296m432s432m432s432m432s432m432s432" "m432s1296m432s432m432s1296m432s432m432s1296m432s432m432s1296m432s1296" "m432s1296m432s1296m432s432m432s432m432s1296m432s1296m432s432m432s1296" "m432s1296m432s1296m432s1296m432s432m432s1296m432s1296m432s1296m432s1296" "m432s74736", irsend.outputStr()); } // Tests for sendPanasonic(). TEST(TestSendPanasonic, CompareToSendPanasonic64) { IRsendTest panasonic(4); IRsendTest panasonic64(0); panasonic.begin(); panasonic64.begin(); panasonic.reset(); panasonic64.reset(); panasonic.sendPanasonic(0x4004, 0x0190ED7C); panasonic64.sendPanasonic64(0x40040190ED7C); EXPECT_EQ(panasonic64.outputStr(), panasonic.outputStr()); panasonic.sendPanasonic(0x0, 0x0); panasonic64.sendPanasonic64(0x0); EXPECT_EQ(panasonic64.outputStr(), panasonic.outputStr()); panasonic.sendPanasonic(0x0, 0x0, 8); panasonic64.sendPanasonic64(0x0, 8); EXPECT_EQ(panasonic64.outputStr(), panasonic.outputStr()); panasonic.sendPanasonic(0x1234, 0x567890AB, 64); panasonic64.sendPanasonic64(0x1234567890AB, 64); EXPECT_EQ(panasonic64.outputStr(), panasonic.outputStr()); panasonic.sendPanasonic(0x1234, 0x567890AB, kPanasonicBits, 2); panasonic64.sendPanasonic64(0x1234567890AB, kPanasonicBits, 2); EXPECT_EQ(panasonic64.outputStr(), panasonic.outputStr()); } // Tests for decodePanasonic(). // Decode normal Panasonic messages. TEST(TestDecodePanasonic, NormalDecodeWithStrict) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); // Normal Panasonic 48-bit message. irsend.reset(); irsend.sendPanasonic64(0x40040190ED7C); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040190ED7C, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x0190ED7C, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); // Synthesised Normal Panasonic 48-bit message. irsend.reset(); irsend.sendPanasonic64(irsend.encodePanasonic(0x4004, 0x12, 0x34, 0x56)); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x400412345670, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x12345670, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); // Synthesised Normal Panasonic 48-bit message. irsend.reset(); irsend.sendPanasonic64(irsend.encodePanasonic(0x4004, 0x1, 0x1, 0x1)); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x400401010101, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x1010101, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); } // Decode normal repeated Panasonic messages. TEST(TestDecodePanasonic, NormalDecodeWithRepeatAndStrict) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); // Normal Panasonic 48-bit message with 2 repeats. irsend.reset(); irsend.sendPanasonic64(0x40040190ED7C, kPanasonicBits, 2); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040190ED7C, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x190ED7C, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); irsend.makeDecodeResult(2 * kPanasonicBits + 4); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040190ED7C, irsend.capture.value); irsend.makeDecodeResult(2 * (2 * kPanasonicBits + 4)); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040190ED7C, irsend.capture.value); } // Decode Panasonic messages with unsupported values. TEST(TestDecodePanasonic, DecodeWithNonStrictValues) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); irsend.reset(); irsend.sendPanasonic64(0x0); // Illegal value Panasonic 48-bit message. irsend.makeDecodeResult(); // Should fail with strict on. ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); // Should pass if strict off. ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, false)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x0, irsend.capture.value); EXPECT_EQ(0x0, irsend.capture.address); EXPECT_EQ(0x0, irsend.capture.command); irsend.reset(); // Illegal address/Manufacturer code. The rest is legal. irsend.sendPanasonic64(irsend.encodePanasonic(0, 1, 2, 3)); irsend.makeDecodeResult(); // Should fail with strict on. ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); // Should pass if strict off. ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, false)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x1020300, irsend.capture.value); EXPECT_EQ(0x0, irsend.capture.address); EXPECT_EQ(0x1020300, irsend.capture.command); } // Decode Panasonic messages with unsupported size/lengths. TEST(TestDecodePanasonic, DecodeWithNonStrictSize) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); irsend.reset(); irsend.sendPanasonic64(0x12345678, 32); // Illegal size Panasonic message. irsend.makeDecodeResult(); ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); irsend.makeDecodeResult(); // Should fail with strict when we ask for the wrong bit size. ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, 32, true)); // Should pass if strict off. ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, 32, false)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(32, irsend.capture.bits); EXPECT_EQ(0x12345678, irsend.capture.value); EXPECT_EQ(0x0, irsend.capture.address); EXPECT_EQ(0x12345678, irsend.capture.command); // Illegal over length (56-bit) message. irsend.reset(); irsend.sendPanasonic64(irsend.encodePanasonic(0x4004, 1, 2, 3), 56); irsend.makeDecodeResult(); ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); // Shouldn't pass if strict off and wrong bit size. ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, false)); // Re-decode with correct bit size. ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, 56, true)); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, 56, false)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(56, irsend.capture.bits); EXPECT_EQ(0x400401020300, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x01020300, irsend.capture.command); } // Decode (non-standard) 64-bit messages. TEST(TestDecodePanasonic, Decode64BitMessages) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); irsend.reset(); // Illegal value & size Panasonic 64-bit message. irsend.sendPanasonic64(0xFFFFFFFFFFFFFFFF, 64); irsend.makeDecodeResult(); ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, 64, true)); // Should work with a 'normal' match (not strict) ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, 64, false)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(64, irsend.capture.bits); EXPECT_EQ(0xFFFFFFFFFFFFFFFF, irsend.capture.value); EXPECT_EQ(0xFFFFFFFF, irsend.capture.address); EXPECT_EQ(0xFFFFFFFF, irsend.capture.command); } // Decode a 'real' example via GlobalCache TEST(TestDecodePanasonic, DecodeGlobalCacheExample) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); irsend.reset(); // Panasonic code from Global Cache. uint16_t gc_test[103] = { 37000, 1, 1, 126, 64, 16, 17, 16, 49, 15, 16, 16, 16, 16, 16, 16, 17, 15, 17, 15, 17, 15, 17, 15, 16, 16, 16, 16, 16, 16, 17, 15, 49, 16, 16, 16, 16, 16, 17, 15, 17, 15, 17, 15, 17, 15, 16, 16, 16, 16, 16, 16, 49, 15, 49, 16, 17, 15, 17, 15, 49, 16, 16, 16, 17, 16, 17, 15, 17, 15, 49, 16, 49, 15, 49, 16, 17, 16, 49, 15, 49, 16, 17, 15, 48, 16, 16, 16, 49, 15, 48, 16, 49, 15, 49, 16, 49, 15, 17, 15, 16, 16, 2721}; irsend.sendGC(gc_test, 103); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, true)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040190ED7C, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x0190ED7C, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040190ED7C, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x0190ED7C, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); } // Fail to decode a non-Panasonic example via GlobalCache TEST(TestDecodePanasonic, FailToDecodeNonPanasonicExample) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); irsend.reset(); // Modified a few entries to unexpected values, based on previous test case. uint16_t gc_test[39] = {38000, 1, 1, 322, 162, 20, 61, 20, 61, 20, 20, 20, 20, 20, 20, 20, 127, 20, 61, 9, 20, 20, 61, 20, 20, 20, 61, 20, 61, 20, 61, 20, 20, 20, 20, 20, 20, 20, 884}; irsend.sendGC(gc_test, 39); irsend.makeDecodeResult(); ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture)); ASSERT_FALSE(irrecv.decodePanasonic(&irsend.capture, kStartOffset, kPanasonicBits, false)); } // Failing to decode Panasonic in Issue #245 TEST(TestDecodePanasonic, DecodeIssue245) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); irsend.reset(); uint16_t rawData[100] = { 3550, 1750, 500, 450, 500, 1300, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 1300, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 1300, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 450, 500, 1300, 500, 450, 500, 1300, 500, 1300, 500, 1300, 500, 1300, 500, 450, 500, 450, 500, 1300, 500, 450, 500, 1300, 500, 1300, 500, 1300, 500, 1300, 500, 450, 500, 1300, 500, 5000}; irsend.sendRaw(rawData, 100, 37); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decodePanasonic(&irsend.capture)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040100BCBD, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x100BCBD, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); irsend.reset(); irsend.sendRaw(rawData, 99, 37); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); EXPECT_EQ(PANASONIC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicBits, irsend.capture.bits); EXPECT_EQ(0x40040100BCBD, irsend.capture.value); EXPECT_EQ(0x4004, irsend.capture.address); EXPECT_EQ(0x100BCBD, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); } // Tests for sendPanasonicAC(). // Test sending typical data only. TEST(TestSendPanasonicAC, SendDataOnly) { IRsendTest irsend(kGpioUnused); irsend.begin(); irsend.reset(); uint8_t state[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x30, 0x32, 0x80, 0xAF, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0x80, 0x00, 0x06, 0x83}; irsend.sendPanasonicAC(state); EXPECT_EQ( "f36700d50" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s1296m432s1296" "m432s432m432s432m432s1296m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s1296m432s1296m432s432m432s432m432s432m432s432m432s432" "m432s10000" "m3456s1728" "m432s432m432s1296m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s1296m432s1296" "m432s432m432s432m432s1296m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s1296m432s1296m432s432m432s432" "m432s432m432s1296m432s432m432s432m432s1296m432s1296m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s1296m432s1296m432s1296m432s1296m432s432m432s1296m432s432m432s1296" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s1296m432s1296m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s1296m432s1296m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s432m432s432m432s432m432s432m432s432m432s432m432s432m432s432" "m432s432m432s1296m432s1296m432s432m432s432m432s432m432s432m432s432" "m432s1296m432s1296m432s432m432s432m432s432m432s432m432s432m432s1296" "m432s100000", irsend.outputStr()); } // Tests for the IRPanasonicAc class. TEST(TestIRPanasonicAcClass, ChecksumCalculation) { IRPanasonicAc ac(kGpioUnused); const uint8_t originalstate[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x30, 0x32, 0x80, 0xAF, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0x80, 0x00, 0x06, 0x83}; uint8_t examplestate[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x30, 0x32, 0x80, 0xAF, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0x80, 0x00, 0x06, 0x83}; EXPECT_TRUE(IRPanasonicAc::validChecksum(examplestate)); EXPECT_EQ(0x83, IRPanasonicAc::calcChecksum(examplestate)); examplestate[kPanasonicAcStateLength - 1] = 0x0; // Set incorrect checksum. EXPECT_FALSE(IRPanasonicAc::validChecksum(examplestate)); EXPECT_EQ(0x83, IRPanasonicAc::calcChecksum(examplestate)); ac.setRaw(examplestate); // Extracting the state from the object should have a correct checksum. EXPECT_TRUE(IRPanasonicAc::validChecksum(ac.getRaw())); EXPECT_STATE_EQ(originalstate, ac.getRaw(), kPanasonicAcBits); examplestate[kPanasonicAcStateLength - 1] = 0x83; // Restore old checksum. // Change the state to force a different checksum. examplestate[6] = 0x01; // Should increase checksum by 1. EXPECT_FALSE(IRPanasonicAc::validChecksum(examplestate)); EXPECT_EQ(0x84, IRPanasonicAc::calcChecksum(examplestate)); } TEST(TestIRPanasonicAcClass, SetAndGetPower) { IRPanasonicAc ac(kGpioUnused); ac.on(); EXPECT_TRUE(ac.getPower()); ac.off(); EXPECT_FALSE(ac.getPower()); ac.setPower(true); EXPECT_TRUE(ac.getPower()); ac.setPower(false); EXPECT_FALSE(ac.getPower()); } TEST(TestIRPanasonicAcClass, SetAndGetModel) { IRPanasonicAc ac(kGpioUnused); EXPECT_EQ(kPanasonicJke, ac.getModel()); ac.setModel(kPanasonicDke); EXPECT_EQ(kPanasonicDke, ac.getModel()); ac.setModel(kPanasonicLke); EXPECT_EQ(kPanasonicLke, ac.getModel()); ac.setModel(kPanasonicNke); EXPECT_EQ(kPanasonicNke, ac.getModel()); ac.setModel(kPanasonicUnknown); // shouldn't change. EXPECT_EQ(kPanasonicNke, ac.getModel()); ac.setModel((panasonic_ac_remote_model_t)255); // shouldn't change. EXPECT_EQ(kPanasonicNke, ac.getModel()); ac.setModel(kPanasonicJke); EXPECT_EQ(kPanasonicJke, ac.getModel()); // This state tickled a bug in getModel(). Should read as a JKE. uint8_t jkeState[27] = {0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x32, 0x2E, 0x80, 0xA2, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0x80, 0x00, 0x06, 0x74}; ac.setModel(kPanasonicDke); // Make sure it isn't somehow set to JKE ac.setRaw(jkeState); EXPECT_EQ(kPanasonicJke, ac.getModel()); EXPECT_STATE_EQ(jkeState, ac.getRaw(), kPanasonicAcBits); // This state tickled a bug in getModel(). Should read as CKP. uint8_t ckpState[27] = {0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x67, 0x2E, 0x80, 0xAF, 0x00, 0xC0, 0x6B, 0x98, 0x10, 0x00, 0x81, 0x64, 0x05, 0x87}; ac.setModel(kPanasonicDke); // Make sure it isn't somehow set to CKP ac.setRaw(ckpState); EXPECT_EQ(kPanasonicCkp, ac.getModel()); EXPECT_STATE_EQ(ckpState, ac.getRaw(), kPanasonicAcBits); } TEST(TestIRPanasonicAcClass, SetAndGetMode) { IRPanasonicAc ac(kGpioUnused); ac.setMode(kPanasonicAcCool); ac.setTemp(21); EXPECT_EQ(kPanasonicAcCool, ac.getMode()); ac.setMode(kPanasonicAcHeat); EXPECT_EQ(kPanasonicAcHeat, ac.getMode()); ac.setMode(kPanasonicAcAuto); EXPECT_EQ(kPanasonicAcAuto, ac.getMode()); ac.setMode(kPanasonicAcDry); EXPECT_EQ(kPanasonicAcDry, ac.getMode()); EXPECT_EQ(21, ac.getTemp()); // Temp should be unchanged. ac.setMode(kPanasonicAcFan); EXPECT_EQ(kPanasonicAcFan, ac.getMode()); EXPECT_EQ(kPanasonicAcFanModeTemp, ac.getTemp()); // Temp should change. ac.setMode(kPanasonicAcCool); EXPECT_EQ(kPanasonicAcCool, ac.getMode()); // Temp should be unchanged from the last manual change. EXPECT_EQ(21, ac.getTemp()); } TEST(TestIRPanasonicAcClass, SetAndGetTemp) { IRPanasonicAc ac(kGpioUnused); ac.setTemp(25); EXPECT_EQ(25, ac.getTemp()); ac.setTemp(kPanasonicAcMinTemp); EXPECT_EQ(kPanasonicAcMinTemp, ac.getTemp()); ac.setTemp(kPanasonicAcMinTemp - 1); EXPECT_EQ(kPanasonicAcMinTemp, ac.getTemp()); ac.setTemp(kPanasonicAcMaxTemp); EXPECT_EQ(kPanasonicAcMaxTemp, ac.getTemp()); ac.setTemp(kPanasonicAcMaxTemp + 1); EXPECT_EQ(kPanasonicAcMaxTemp, ac.getTemp()); } TEST(TestIRPanasonicAcClass, SetAndGetFan) { IRPanasonicAc ac(kGpioUnused); ac.setFan(kPanasonicAcFanAuto); EXPECT_EQ(kPanasonicAcFanAuto, ac.getFan()); ac.setFan(kPanasonicAcFanMin); EXPECT_EQ(kPanasonicAcFanMin, ac.getFan()); ac.setFan(kPanasonicAcFanMin - 1); EXPECT_EQ(kPanasonicAcFanAuto, ac.getFan()); ac.setFan(kPanasonicAcFanMed); EXPECT_EQ(kPanasonicAcFanMed, ac.getFan()); ac.setFan(kPanasonicAcFanMin + 1); EXPECT_EQ(kPanasonicAcFanAuto, ac.getFan()); ac.setFan(kPanasonicAcFanMax); EXPECT_EQ(kPanasonicAcFanMax, ac.getFan()); ac.setFan(kPanasonicAcFanMax + 1); EXPECT_EQ(kPanasonicAcFanAuto, ac.getFan()); ac.setFan(kPanasonicAcFanMax - 1); EXPECT_EQ(kPanasonicAcFanAuto, ac.getFan()); } TEST(TestIRPanasonicAcClass, SetAndGetSwings) { IRPanasonicAc ac(kGpioUnused); // Vertical ac.setSwingVertical(kPanasonicAcSwingVAuto); EXPECT_EQ(kPanasonicAcSwingVAuto, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVHighest); EXPECT_EQ(kPanasonicAcSwingVHighest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVHighest - 1); EXPECT_EQ(kPanasonicAcSwingVHighest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVHighest + 1); EXPECT_EQ(kPanasonicAcSwingVHighest + 1, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVLowest); EXPECT_EQ(kPanasonicAcSwingVLowest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVLowest + 1); EXPECT_EQ(kPanasonicAcSwingVLowest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVLowest - 1); EXPECT_EQ(kPanasonicAcSwingVLowest - 1, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVAuto); EXPECT_EQ(kPanasonicAcSwingVAuto, ac.getSwingVertical()); // Horizontal is model dependant. ac.setModel(kPanasonicNke); // NKE is always fixed in the middle. EXPECT_EQ(kPanasonicAcSwingHMiddle, ac.getSwingHorizontal()); ac.setSwingHorizontal(kPanasonicAcSwingHAuto); EXPECT_EQ(kPanasonicAcSwingHMiddle, ac.getSwingHorizontal()); ac.setModel(kPanasonicJke); // JKE has no H swing. EXPECT_EQ(0, ac.getSwingHorizontal()); ac.setSwingHorizontal(kPanasonicAcSwingHMiddle); EXPECT_EQ(0, ac.getSwingHorizontal()); ac.setModel(kPanasonicLke); // LKE is always fixed in the middle. EXPECT_EQ(kPanasonicAcSwingHMiddle, ac.getSwingHorizontal()); ac.setSwingHorizontal(kPanasonicAcSwingHAuto); EXPECT_EQ(kPanasonicAcSwingHMiddle, ac.getSwingHorizontal()); ac.setModel(kPanasonicDke); // DKE has full control. ASSERT_EQ(kPanasonicDke, ac.getModel()); // Auto was last requested. EXPECT_EQ(kPanasonicAcSwingHAuto, ac.getSwingHorizontal()); ac.setSwingHorizontal(kPanasonicAcSwingHLeft); EXPECT_EQ(kPanasonicAcSwingHLeft, ac.getSwingHorizontal()); // Changing models from DKE to something else, then back should not change // the intended swing. ac.setModel(kPanasonicLke); EXPECT_EQ(kPanasonicAcSwingHMiddle, ac.getSwingHorizontal()); ac.setModel(kPanasonicDke); EXPECT_EQ(kPanasonicAcSwingHLeft, ac.getSwingHorizontal()); } TEST(TestIRPanasonicAcClass, QuietAndPowerful) { IRPanasonicAc ac(kGpioUnused); ac.setQuiet(false); EXPECT_FALSE(ac.getQuiet()); ac.setQuiet(true); EXPECT_TRUE(ac.getQuiet()); EXPECT_FALSE(ac.getPowerful()); ac.setPowerful(false); EXPECT_FALSE(ac.getPowerful()); EXPECT_TRUE(ac.getQuiet()); ac.setPowerful(true); EXPECT_TRUE(ac.getPowerful()); EXPECT_FALSE(ac.getQuiet()); ac.setPowerful(false); EXPECT_FALSE(ac.getPowerful()); EXPECT_FALSE(ac.getQuiet()); ac.setPowerful(true); ac.setQuiet(true); EXPECT_TRUE(ac.getQuiet()); EXPECT_FALSE(ac.getPowerful()); } TEST(TestIRPanasonicAcClass, SetAndGetIon) { IRPanasonicAc ac(0); // Ion Filter only works for DKE. ac.setModel(kPanasonicDke); ac.setIon(true); EXPECT_TRUE(ac.getIon()); ac.setIon(false); EXPECT_FALSE(ac.getIon()); ac.setIon(true); EXPECT_TRUE(ac.getIon()); // Now try a different (a guess at unsupported) model. ac.setModel(kPanasonicRkr); EXPECT_FALSE(ac.getIon()); ac.setIon(true); EXPECT_FALSE(ac.getIon()); ac.setIon(false); EXPECT_FALSE(ac.getIon()); } TEST(TestIRPanasonicAcClass, HumanReadable) { IRPanasonicAc ac(kGpioUnused); EXPECT_EQ( "Model: 4 (JKE), Power: Off, Mode: 0 (Auto), Temp: 0C, " "Fan: 253 (UNKNOWN), Swing(V): 0 (UNKNOWN), Quiet: Off, " "Powerful: Off, Clock: 00:00, On Timer: Off, Off Timer: Off", ac.toString()); ac.setPower(true); ac.setTemp(kPanasonicAcMaxTemp); ac.setMode(kPanasonicAcHeat); ac.setFan(kPanasonicAcFanMax); ac.setSwingVertical(kPanasonicAcSwingVAuto); ac.setPowerful(true); EXPECT_EQ( "Model: 4 (JKE), Power: On, Mode: 4 (Heat), Temp: 30C, " "Fan: 4 (High), Swing(V): 15 (Auto), Quiet: Off, " "Powerful: On, Clock: 00:00, On Timer: Off, Off Timer: Off", ac.toString()); ac.setQuiet(true); ac.setModel(kPanasonicLke); EXPECT_EQ( "Model: 1 (LKE), Power: Off, Mode: 4 (Heat), Temp: 30C, " "Fan: 4 (High), Swing(V): 15 (Auto), " "Swing(H): 6 (Middle), Quiet: On, Powerful: Off, " "Clock: 00:00, On Timer: 00:00, Off Timer: Off", ac.toString()); ac.setModel(kPanasonicDke); ac.setSwingHorizontal(kPanasonicAcSwingHRight); EXPECT_EQ( "Model: 3 (DKE), Power: Off, Mode: 4 (Heat), Temp: 30C, " "Fan: 4 (High), Swing(V): 15 (Auto), " "Swing(H): 11 (Right), Quiet: On, Powerful: Off, Ion: Off, " "Clock: 00:00, On Timer: Off, Off Timer: Off", ac.toString()); } // Tests for decodePanasonicAC(). // Decode normal Panasonic AC messages. TEST(TestDecodePanasonicAC, RealExample) { IRsendTest irsend(4); IRrecv irrecv(4); irsend.begin(); // Data from Issue #525 uint16_t rawData[439] = { 3582, 1686, 488, 378, 488, 1238, 488, 378, 488, 378, 488, 378, 488, 378, 488, 378, 488, 384, 488, 378, 488, 378, 488, 378, 488, 378, 488, 378, 488, 1242, 486, 378, 488, 384, 488, 378, 488, 378, 488, 380, 486, 382, 484, 382, 484, 1264, 464, 1266, 460, 1272, 462, 378, 488, 406, 460, 1266, 462, 380, 488, 382, 484, 388, 478, 406, 462, 410, 462, 404, 462, 406, 462, 396, 470, 406, 462, 404, 462, 406, 460, 404, 462, 410, 462, 404, 462, 404, 462, 406, 464, 406, 462, 404, 462, 406, 462, 404, 462, 410, 462, 404, 462, 406, 462, 404, 462, 404, 462, 404, 462, 406, 460, 406, 462, 410, 462, 404, 462, 1264, 484, 1244, 486, 382, 482, 382, 486, 382, 486, 378, 486, 382, 488, 9924, 3554, 1686, 488, 378, 490, 1240, 486, 378, 488, 378, 488, 378, 488, 378, 488, 382, 484, 386, 486, 378, 488, 382, 486, 378, 488, 382, 486, 382, 484, 1242, 486, 380, 488, 386, 484, 382, 486, 380, 486, 382, 486, 380, 486, 380, 486, 1242, 486, 1242, 484, 1248, 484, 380, 488, 382, 484, 1242, 486, 382, 484, 382, 484, 382, 484, 382, 486, 386, 484, 382, 486, 382, 484, 382, 486, 382, 486, 380, 484, 382, 486, 382, 488, 380, 486, 382, 484, 380, 462, 406, 488, 376, 484, 1246, 482, 1246, 460, 404, 480, 392, 484, 386, 482, 1244, 484, 382, 484, 382, 484, 1242, 482, 1244, 484, 382, 464, 410, 460, 404, 462, 406, 462, 404, 462, 404, 470, 396, 462, 406, 462, 404, 462, 1286, 460, 1268, 458, 1268, 460, 1266, 460, 1266, 460, 406, 460, 1266, 462, 406, 460, 1272, 462, 406, 460, 406, 460, 406, 460, 406, 462, 404, 462, 406, 460, 406, 462, 410, 462, 404, 462, 406, 460, 406, 460, 406, 462, 404, 462, 406, 460, 406, 460, 410, 462, 406, 460, 1268, 460, 1266, 460, 404, 460, 406, 462, 406, 460, 406, 460, 412, 456, 410, 460, 410, 438, 428, 460, 410, 456, 410, 456, 1272, 436, 1288, 438, 434, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 434, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 440, 428, 438, 428, 438, 432, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 430, 438, 1294, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 428, 438, 434, 438, 428, 438, 1288, 438, 1290, 438, 428, 438, 428, 438, 428, 438, 428, 438, 432, 438, 1288, 438, 1290, 438, 430, 438, 428, 438, 428, 438, 428, 438, 428, 438, 1292, 438}; uint8_t expectedState[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x30, 0x32, 0x80, 0xAF, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0x80, 0x00, 0x06, 0x83}; irsend.sendRaw(rawData, 439, kPanasonicFreq); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAcBits, irsend.capture.bits); EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits); EXPECT_FALSE(irsend.capture.repeat); } // Decode synthetic Panasonic AC message. TEST(TestDecodePanasonicAC, SyntheticExample) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // Data from Issue #525 uint8_t expectedState[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x30, 0x32, 0x80, 0xAF, 0x00, 0x00, 0x06, 0x60, 0x00, 0x00, 0x80, 0x00, 0x06, 0x83}; irsend.sendPanasonicAC(expectedState); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAcBits, irsend.capture.bits); EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits); EXPECT_FALSE(irsend.capture.repeat); EXPECT_EQ( "Model: 4 (JKE), Power: Off, Mode: 3 (Cool), Temp: 25C, " "Fan: 7 (Auto), Swing(V): 15 (Auto), Quiet: Off, " "Powerful: Off, Clock: 00:00, On Timer: Off, Off Timer: Off", IRAcUtils::resultAcToString(&irsend.capture)); stdAc::state_t r, p; ASSERT_TRUE(IRAcUtils::decodeToState(&irsend.capture, &r, &p)); } // Tests for general utility functions. TEST(TestGeneralPanasonic, hasACState) { EXPECT_TRUE(hasACState(PANASONIC_AC)); ASSERT_FALSE(hasACState(PANASONIC)); ASSERT_FALSE(hasACState(PANASONIC_AC32)); } TEST(TestGeneralPanasonic, typeToString) { EXPECT_EQ("PANASONIC_AC", typeToString(PANASONIC_AC)); EXPECT_EQ("PANASONIC", typeToString(PANASONIC)); } // Decode a problematic Panasonic AC message TEST(TestDecodePanasonicAC, Issue540) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // Data from Issue #540 uint16_t rawData[439] = { 3512, 1714, 466, 408, 466, 1280, 470, 408, 466, 412, 466, 408, 466, 412, 462, 412, 466, 414, 466, 408, 466, 412, 462, 412, 466, 412, 466, 408, 466, 1280, 466, 412, 462, 416, 462, 412, 466, 408, 466, 412, 462, 416, 462, 412, 462, 1282, 462, 1284, 462, 1288, 466, 412, 462, 412, 462, 1284, 462, 416, 440, 438, 462, 412, 462, 412, 462, 416, 466, 412, 462, 412, 462, 412, 440, 442, 462, 412, 462, 412, 460, 418, 462, 416, 462, 412, 462, 418, 462, 412, 462, 416, 462, 412, 436, 442, 462, 412, 460, 418, 462, 416, 462, 412, 460, 412, 462, 420, 436, 438, 462, 412, 462, 416, 432, 448, 436, 438, 436, 1310, 436, 1310, 462, 420, 432, 442, 436, 438, 462, 416, 432, 444, 432, 10008, 3480, 1744, 492, 382, 492, 1254, 492, 386, 488, 390, 492, 382, 492, 386, 488, 386, 492, 386, 492, 386, 488, 386, 488, 386, 492, 386, 492, 382, 492, 1258, 488, 386, 488, 390, 492, 386, 488, 386, 488, 386, 492, 390, 488, 386, 488, 1256, 488, 1258, 488, 1262, 488, 390, 488, 386, 488, 1258, 488, 390, 488, 392, 488, 386, 488, 386, 488, 394, 488, 386, 488, 386, 488, 390, 488, 390, 488, 386, 488, 390, 462, 412, 488, 390, 462, 1282, 488, 390, 456, 416, 458, 1292, 456, 1288, 488, 1258, 488, 392, 456, 422, 488, 390, 484, 392, 484, 1262, 458, 420, 484, 1262, 482, 1262, 488, 392, 484, 394, 484, 416, 436, 442, 458, 416, 458, 422, 430, 448, 432, 442, 458, 416, 458, 1296, 432, 1314, 458, 1288, 432, 1312, 432, 1322, 428, 446, 428, 1318, 432, 442, 432, 1318, 432, 1318, 428, 446, 428, 1318, 428, 1322, 430, 448, 426, 448, 428, 452, 426, 452, 426, 448, 428, 472, 400, 478, 402, 478, 402, 472, 402, 476, 402, 472, 402, 478, 402, 472, 402, 1348, 398, 1348, 398, 1352, 398, 508, 370, 478, 398, 476, 398, 512, 366, 508, 370, 502, 372, 508, 340, 538, 372, 504, 344, 1400, 344, 1400, 346, 1434, 314, 560, 316, 588, 290, 560, 314, 564, 396, 400, 474, 400, 480, 394, 480, 404, 474, 400, 454, 446, 454, 426, 448, 430, 424, 450, 428, 452, 448, 426, 426, 452, 424, 1322, 454, 426, 450, 424, 426, 452, 428, 452, 450, 424, 428, 446, 426, 1322, 454, 426, 422, 450, 454, 426, 448, 430, 454, 426, 448, 426, 428, 446, 454, 430, 454, 422, 452, 424, 424, 452, 452, 430, 424, 452, 452, 426, 448, 426, 426, 456, 448, 426, 448, 1296, 424, 1322, 426, 1326, 450, 1270, 478, 422, 454, 424, 424, 450, 454}; uint8_t expectedState[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x39, 0x34, 0x80, 0xAF, 0x0D, 0x00, 0x0E, 0xE0, 0x00, 0x00, 0x81, 0x00, 0x00, 0x1E}; irsend.sendRaw(rawData, 439, kPanasonicFreq); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAcBits, irsend.capture.bits); EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits); EXPECT_FALSE(irsend.capture.repeat); IRPanasonicAc ac(kGpioUnused); ac.setRaw(irsend.capture.state); // TODO(crankyoldgit): Try to figure out what model this should be. EXPECT_EQ( "Model: 0 (UNKNOWN), Power: On, Mode: 3 (Cool), Temp: 26C, " "Fan: 7 (Auto), Swing(V): 15 (Auto), " "Swing(H): 13 (Auto), Quiet: Off, Powerful: Off, " "Clock: 00:00, On Timer: Off, Off Timer: Off", ac.toString()); } TEST(TestIRPanasonicAcClass, TimeBasics) { EXPECT_EQ(0x186, IRPanasonicAc::encodeTime(6, 30)); EXPECT_EQ(0x3CA, IRPanasonicAc::encodeTime(16, 10)); EXPECT_EQ(0x448, IRPanasonicAc::encodeTime(18, 16)); EXPECT_EQ(0, IRPanasonicAc::encodeTime(0, 0)); EXPECT_EQ(kPanasonicAcTimeMax, IRPanasonicAc::encodeTime(23, 59)); EXPECT_EQ(kPanasonicAcTimeMax, IRPanasonicAc::encodeTime(23, 59)); EXPECT_EQ(kPanasonicAcTimeMax, IRPanasonicAc::encodeTime(25, 72)); EXPECT_EQ(59, IRPanasonicAc::encodeTime(0, 72)); EXPECT_EQ(23 * 60, IRPanasonicAc::encodeTime(27, 0)); } TEST(TestIRPanasonicAcClass, TimersAndClock) { IRPanasonicAc ac(kGpioUnused); // Data from Issue #544 uint8_t state[27] = {0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x4E, 0x2E, 0x80, 0xAF, 0x00, 0xCA, 0x6B, 0x98, 0x10, 0x00, 0x01, 0x48, 0x04, 0xDB}; ac.setRaw(state); EXPECT_TRUE(ac.isOnTimerEnabled()); EXPECT_EQ(0x3CA, ac.getOnTimer()); EXPECT_TRUE(ac.isOffTimerEnabled()); EXPECT_EQ(0x186, ac.getOffTimer()); EXPECT_EQ(0x448, ac.getClock()); ac.cancelOnTimer(); EXPECT_FALSE(ac.isOnTimerEnabled()); EXPECT_EQ(0, ac.getOnTimer()); EXPECT_TRUE(ac.isOffTimerEnabled()); EXPECT_EQ(0x186, ac.getOffTimer()); EXPECT_EQ(0x448, ac.getClock()); ac.cancelOffTimer(); EXPECT_FALSE(ac.isOnTimerEnabled()); EXPECT_EQ(0, ac.getOnTimer()); EXPECT_FALSE(ac.isOffTimerEnabled()); EXPECT_EQ(0, ac.getOffTimer()); EXPECT_EQ(0x448, ac.getClock()); ac.setOnTimer(7 * 60 + 50); EXPECT_TRUE(ac.isOnTimerEnabled()); EXPECT_EQ(7 * 60 + 50, ac.getOnTimer()); EXPECT_FALSE(ac.isOffTimerEnabled()); EXPECT_EQ(0, ac.getOffTimer()); EXPECT_EQ(0x448, ac.getClock()); ac.setOnTimer(7 * 60 + 57); // It should round down. EXPECT_EQ(7 * 60 + 50, ac.getOnTimer()); ac.setOnTimer(28 * 60); // It should round down. EXPECT_EQ(kPanasonicAcTimeMax - 9, ac.getOnTimer()); ac.setOnTimer(kPanasonicAcTimeSpecial); EXPECT_EQ(0, ac.getOnTimer()); ac.setOnTimer(7 * 60 + 50); ac.setOffTimer(19 * 60 + 30); EXPECT_TRUE(ac.isOnTimerEnabled()); EXPECT_EQ(7 * 60 + 50, ac.getOnTimer()); EXPECT_TRUE(ac.isOffTimerEnabled()); EXPECT_EQ(19 * 60 + 30, ac.getOffTimer()); EXPECT_EQ(0x448, ac.getClock()); ac.setOffTimer(19 * 60 + 57); // It should round down. EXPECT_EQ(19 * 60 + 50, ac.getOffTimer()); ac.setOffTimer(28 * 60); // It should round down. EXPECT_EQ(kPanasonicAcTimeMax - 9, ac.getOffTimer()); ac.setOffTimer(kPanasonicAcTimeSpecial); EXPECT_EQ(0, ac.getOffTimer()); ac.setClock(0); EXPECT_EQ(0, ac.getClock()); ac.setClock(kPanasonicAcTimeMax); EXPECT_EQ(kPanasonicAcTimeMax, ac.getClock()); ac.setClock(kPanasonicAcTimeMax - 1); EXPECT_EQ(kPanasonicAcTimeMax - 1, ac.getClock()); ac.setClock(kPanasonicAcTimeMax + 1); EXPECT_EQ(kPanasonicAcTimeMax, ac.getClock()); ac.setClock(kPanasonicAcTimeSpecial); EXPECT_EQ(0, ac.getClock()); } // Decode a real short Panasonic AC message TEST(TestDecodePanasonicAC, RealExampleOfShortMessage) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // Data from Issue #544 (Odour Wash) uint16_t rawData[263] = { 3496, 1734, 506, 366, 448, 1294, 504, 368, 498, 374, 452, 418, 448, 424, 444, 428, 450, 422, 446, 426, 450, 420, 448, 424, 452, 418, 448, 422, 444, 1300, 498, 374, 504, 368, 448, 424, 452, 418, 448, 424, 444, 428, 450, 422, 446, 1296, 500, 1242, 502, 1242, 504, 368, 498, 374, 452, 1292, 504, 366, 450, 422, 444, 426, 450, 420, 446, 424, 452, 418, 448, 424, 444, 428, 450, 422, 444, 426, 450, 420, 446, 424, 452, 418, 448, 422, 444, 428, 450, 422, 446, 426, 452, 420, 446, 426, 452, 418, 448, 424, 442, 428, 448, 422, 444, 426, 450, 420, 446, 426, 452, 418, 448, 424, 444, 428, 450, 422, 444, 1298, 500, 1244, 500, 372, 444, 428, 450, 422, 446, 426, 452, 418, 448, 10020, 3500, 1732, 498, 372, 452, 1290, 506, 366, 450, 422, 446, 426, 452, 420, 448, 424, 452, 418, 448, 422, 444, 426, 450, 420, 446, 426, 452, 420, 446, 1296, 500, 370, 444, 428, 450, 422, 446, 426, 452, 420, 446, 424, 442, 428, 448, 1294, 502, 1240, 504, 1238, 506, 366, 448, 422, 444, 1298, 498, 374, 452, 418, 448, 424, 444, 428, 450, 422, 446, 426, 450, 420, 446, 424, 452, 418, 448, 422, 444, 428, 450, 420, 446, 1298, 498, 1244, 500, 1242, 502, 368, 446, 1298, 500, 1244, 500, 372, 444, 428, 450, 1292, 504, 368, 446, 1296, 502, 370, 444, 426, 452, 1290, 504, 1238, 506, 366, 450, 422, 446, 1298, 498, 1246, 500, 372, 444, 428, 450, 1294, 452, 420, 446, 1296, 448, 422, 444}; // UNKNOWN // 1FB51F79 uint8_t expectedState[kPanasonicAcStateShortLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x80, 0x9B, 0x32, 0x53}; irsend.sendRaw(rawData, 263, kPanasonicFreq); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAcShortBits, irsend.capture.bits); EXPECT_STATE_EQ(expectedState, irsend.capture.state, irsend.capture.bits); } // Create and decode a short Panasonic AC message TEST(TestDecodePanasonicAC, SyntheticShortMessage) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); uint8_t odourWash[kPanasonicAcStateShortLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x80, 0x9B, 0x32, 0x53}; irsend.sendPanasonicAC(odourWash, kPanasonicAcStateShortLength); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAcShortBits, irsend.capture.bits); EXPECT_STATE_EQ(odourWash, irsend.capture.state, irsend.capture.bits); } // // Test for CKP model / see issue #544 TEST(TestDecodePanasonicAC, CkpModelSpecifics) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // Data from Issue #544 uint8_t ckpPowerfulOn[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x4E, 0x2E, 0x80, 0xAF, 0x00, 0x00, 0x0E, 0xE0, 0x11, 0x00, 0x01, 0x00, 0x06, 0xB7}; uint8_t ckpQuietOn[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x4E, 0x2E, 0x80, 0xAF, 0x00, 0x00, 0x0E, 0xE0, 0x30, 0x00, 0x01, 0x00, 0x06, 0xD6}; irsend.sendPanasonicAC(ckpPowerfulOn); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAcBits, irsend.capture.bits); EXPECT_STATE_EQ(ckpPowerfulOn, irsend.capture.state, irsend.capture.bits); EXPECT_FALSE(irsend.capture.repeat); IRPanasonicAc ac(kGpioUnused); ac.setRaw(irsend.capture.state); EXPECT_EQ( "Model: 5 (CKP), Power: Off, Mode: 4 (Heat), Temp: 23C, " "Fan: 7 (Auto), Swing(V): 15 (Auto), Quiet: Off, " "Powerful: On, Clock: 00:00, On Timer: 00:00, Off Timer: 00:00", ac.toString()); ac.setQuiet(true); EXPECT_FALSE(ac.getPowerful()); EXPECT_TRUE(ac.getQuiet()); EXPECT_EQ(kPanasonicCkp, ac.getModel()); EXPECT_STATE_EQ(ckpQuietOn, ac.getRaw(), kPanasonicAcBits); ac.setPowerful(true); EXPECT_TRUE(ac.getPowerful()); EXPECT_FALSE(ac.getQuiet()); EXPECT_EQ(kPanasonicCkp, ac.getModel()); EXPECT_STATE_EQ(ckpPowerfulOn, ac.getRaw(), kPanasonicAcBits); } TEST(TestIRPanasonicAcClass, toCommon) { IRPanasonicAc ac(0); ac.setModel(panasonic_ac_remote_model_t::kPanasonicDke); ac.setPower(true); ac.setMode(kPanasonicAcCool); ac.setTemp(20); ac.setFan(kPanasonicAcFanMax); ac.setSwingVertical(kPanasonicAcSwingVAuto); ac.setSwingHorizontal(kPanasonicAcSwingHMiddle); ac.setPowerful(true); ac.setQuiet(false); // Now test it. ASSERT_EQ(decode_type_t::PANASONIC_AC, ac.toCommon().protocol); ASSERT_EQ(panasonic_ac_remote_model_t::kPanasonicDke, ac.toCommon().model); ASSERT_TRUE(ac.toCommon().power); ASSERT_TRUE(ac.toCommon().celsius); ASSERT_EQ(20, ac.toCommon().degrees); ASSERT_EQ(stdAc::opmode_t::kCool, ac.toCommon().mode); ASSERT_EQ(stdAc::fanspeed_t::kMax, ac.toCommon().fanspeed); ASSERT_EQ(stdAc::swingv_t::kAuto, ac.toCommon().swingv); ASSERT_EQ(stdAc::swingh_t::kMiddle, ac.toCommon().swingh); ASSERT_TRUE(ac.toCommon().turbo); ASSERT_FALSE(ac.toCommon().quiet); // Unsupported. ASSERT_FALSE(ac.toCommon().econo); ASSERT_FALSE(ac.toCommon().clean); ASSERT_FALSE(ac.toCommon().light); ASSERT_FALSE(ac.toCommon().filter); ASSERT_FALSE(ac.toCommon().beep); ASSERT_EQ(-1, ac.toCommon().sleep); ASSERT_EQ(-1, ac.toCommon().clock); // Ref: https://github.com/crankyoldgit/IRremoteESP8266/issues/921#issuecomment-532267240 ac.setSwingVertical(kPanasonicAcSwingVLow); ASSERT_EQ(stdAc::swingv_t::kLow, ac.toCommon().swingv); // Real data. uint8_t swingVMiddle[27] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x39, 0x32, 0x80, 0x73, 0x00, 0x00, 0x0E, 0xE0, 0x00, 0x00, 0x89, 0x00, 0x00, 0xDB}; ac.setRaw(swingVMiddle); ASSERT_EQ(stdAc::swingv_t::kMiddle, ac.toCommon().swingv); ASSERT_EQ(kPanasonicAcSwingVMiddle, IRPanasonicAc::convertSwingV(stdAc::swingv_t::kMiddle)); } // // Test for DKE/DKW model / see issue #1024 TEST(TestDecodePanasonicAC, DkeIonRealMessages) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // Data from Issue #1024 // 0x0220E004000000060220E004004F3280AF0D000660000001000630 uint8_t dkeIonOff[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x4F, 0x32, 0x80, 0xAF, 0x0D, 0x00, 0x06, 0x60, 0x00, 0x00, 0x01, 0x00, 0x06, 0x30}; // 0x0220E004000000060220E004004F3280AF0D000660000101000631 uint8_t dkeIonOn[kPanasonicAcStateLength] = { 0x02, 0x20, 0xE0, 0x04, 0x00, 0x00, 0x00, 0x06, 0x02, 0x20, 0xE0, 0x04, 0x00, 0x4F, 0x32, 0x80, 0xAF, 0x0D, 0x00, 0x06, 0x60, 0x00, 0x01, 0x01, 0x00, 0x06, 0x31}; IRPanasonicAc ac(0); ac.setRaw(dkeIonOff); EXPECT_EQ( "Model: 3 (DKE), Power: On, Mode: 4 (Heat), Temp: 25C, Fan: 7 (Auto), " "Swing(V): 15 (Auto), Swing(H): 13 (Auto), Quiet: Off, Powerful: Off, " "Ion: Off, Clock: 00:00, On Timer: 00:00, Off Timer: 00:00", ac.toString()); ac.setRaw(dkeIonOn); EXPECT_EQ( "Model: 3 (DKE), Power: On, Mode: 4 (Heat), Temp: 25C, Fan: 7 (Auto), " "Swing(V): 15 (Auto), Swing(H): 13 (Auto), Quiet: Off, Powerful: Off, " "Ion: On, Clock: 00:00, On Timer: 00:00, Off Timer: 00:00", ac.toString()); } // General housekeeping TEST(TestPanasonic, Housekeeping) { // Simple Panasonic protocol. e.g. TVs etc. ASSERT_EQ(D_STR_PANASONIC, typeToString(decode_type_t::PANASONIC)); ASSERT_FALSE(hasACState(decode_type_t::PANASONIC)); ASSERT_EQ(decode_type_t::PANASONIC, strToDecodeType(D_STR_PANASONIC)); ASSERT_FALSE(IRac::isProtocolSupported(decode_type_t::PANASONIC)); ASSERT_EQ(kPanasonicBits, IRsend::defaultBits(decode_type_t::PANASONIC)); ASSERT_EQ(kNoRepeat, IRsend::minRepeats(decode_type_t::PANASONIC)); // Panasonic A/Cs ASSERT_EQ(D_STR_PANASONIC_AC, typeToString(decode_type_t::PANASONIC_AC)); ASSERT_TRUE(hasACState(decode_type_t::PANASONIC_AC)); ASSERT_EQ(decode_type_t::PANASONIC_AC, strToDecodeType(D_STR_PANASONIC_AC)); ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::PANASONIC_AC)); ASSERT_EQ(kPanasonicAcBits, IRsend::defaultBits(decode_type_t::PANASONIC_AC)); ASSERT_EQ(kNoRepeat, IRsend::minRepeats(decode_type_t::PANASONIC_AC)); // Panasonic A/Cs (32bit) ASSERT_EQ(D_STR_PANASONIC_AC32, typeToString(decode_type_t::PANASONIC_AC32)); ASSERT_EQ(decode_type_t::PANASONIC_AC32, strToDecodeType(D_STR_PANASONIC_AC32)); ASSERT_FALSE(hasACState(decode_type_t::PANASONIC_AC32)); ASSERT_TRUE(IRac::isProtocolSupported(decode_type_t::PANASONIC_AC32)); ASSERT_EQ(kPanasonicAc32Bits, IRsend::defaultBits(decode_type_t::PANASONIC_AC32)); ASSERT_EQ(kNoRepeat, IRsend::minRepeats(decode_type_t::PANASONIC_AC32)); } // Decode a real Panasonic AC 32 bit message TEST(TestDecodePanasonicAC32, RealMessage) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // https://github.com/crankyoldgit/IRremoteESP8266/issues/1307#issuecomment-717436003 // https://github.com/crankyoldgit/IRremoteESP8266/files/5446781/temp-take3_36khz.txt // # Remote: 17 C, auto mode, auto top swing, auto left/right swing, auto fan const uint16_t rawData[271] = { 3544, 3448, 922, 830, 918, 2576, 922, 830, 918, 830, 918, 2576, 922, 2574, 922, 2576, 922, 2576, 922, 826, 922, 2574, 922, 828, 920, 826, 922, 2574, 922, 2574, 922, 2576, 920, 2576, 918, 2578, 918, 830, 918, 2574, 922, 2574, 922, 830, 918, 830, 918, 830, 918, 826, 922, 2574, 922, 826, 922, 2576, 922, 2574, 922, 826, 922, 826, 922, 826, 922, 826, 3544, 3452, 918, 830, 918, 2574, 922, 830, 918, 830, 918, 2576, 922, 2576, 922, 2576, 918, 2580, 918, 830, 918, 2580, 918, 830, 918, 832, 916, 2576, 922, 2576, 922, 2576, 918, 2580, 918, 2580, 916, 832, 918, 2576, 922, 2574, 922, 826, 922, 826, 922, 826, 922, 826, 922, 2576, 916, 830, 918, 2580, 918, 2578, 918, 832, 920, 826, 922, 826, 922, 826, 3544, 3450, 922, 13946, 3542, 3450, 922, 826, 922, 826, 922, 2574, 922, 2574, 922, 2574, 922, 2574, 922, 2574, 922, 2574, 920, 830, 918, 830, 916, 2578, 918, 2580, 916, 2580, 916, 2580, 918, 2578, 922, 2574, 922, 826, 922, 2576, 922, 2574, 922, 826, 922, 2574, 922, 2574, 922, 826, 922, 826, 922, 830, 918, 2574, 922, 2574, 922, 830, 916, 2574, 922, 2574, 922, 830, 918, 830, 3542, 3450, 918, 830, 916, 830, 918, 2578, 922, 2574, 922, 2574, 922, 2574, 922, 2574, 922, 2574, 922, 830, 918, 830, 916, 2574, 922, 2574, 922, 2576, 920, 2574, 922, 2574, 922, 2576, 922, 830, 916, 2580, 916, 2580, 916, 830, 918, 2578, 916, 2580, 918, 830, 922, 826, 922, 826, 922, 2574, 922, 2574, 924, 824, 922, 2574, 922, 2574, 922, 826, 922, 826, 3542, 3452, 922}; // UNKNOWN AA94330B irsend.sendRaw(rawData, 271, kPanasonicFreq); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC32, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAc32Bits, irsend.capture.bits); EXPECT_EQ(0x0DF236FC, irsend.capture.value); EXPECT_EQ(0, irsend.capture.address); EXPECT_EQ(0, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); EXPECT_EQ( "Power Toggle: Off, Mode: 5 (UNKNOWN), Temp: 17C, Fan: 15 (Auto), " "Swing(H): On, Swing(V): 7 (Auto)", IRAcUtils::resultAcToString(&irsend.capture)); stdAc::state_t r, p; ASSERT_TRUE(IRAcUtils::decodeToState(&irsend.capture, &r, &p)); } // Decode a synthetic Panasonic AC 32 bit message TEST(TestDecodePanasonicAC32, SyntheticMessage) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); irsend.sendPanasonicAC32(0x0DF236FC); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC32, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAc32Bits, irsend.capture.bits); EXPECT_EQ(0x0DF236FC, irsend.capture.value); EXPECT_EQ(0, irsend.capture.address); EXPECT_EQ(0, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); EXPECT_EQ( "f36700d50" "m3543s3450" "m920s828m920s2575m920s828m920s828m920s2575m920s2575m920s2575m920s2575" "m920s828m920s2575m920s828m920s828m920s2575m920s2575m920s2575m920s2575" "m920s2575m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828" "m920s2575m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828" "m3543s3450" "m920s828m920s2575m920s828m920s828m920s2575m920s2575m920s2575m920s2575" "m920s828m920s2575m920s828m920s828m920s2575m920s2575m920s2575m920s2575" "m920s2575m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828" "m920s2575m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828" "m3543s3450" "m920s13946" "m3543s3450" "m920s828m920s828m920s2575m920s2575m920s2575m920s2575m920s2575m920s2575" "m920s828m920s828m920s2575m920s2575m920s2575m920s2575m920s2575m920s2575" "m920s828m920s2575m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m920s828m920s2575m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m3543s3450" "m920s828m920s828m920s2575m920s2575m920s2575m920s2575m920s2575m920s2575" "m920s828m920s828m920s2575m920s2575m920s2575m920s2575m920s2575m920s2575" "m920s828m920s2575m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m920s828m920s2575m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m3543s3450" "m920s13946", irsend.outputStr()); } // Decode a real *short* (16 bit) Panasonic AC 32 bit message TEST(TestDecodePanasonicAC32, RealShortMessage) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); // https://github.com/crankyoldgit/IRremoteESP8266/issues/1307#issuecomment-719038870 // https://github.com/crankyoldgit/IRremoteESP8266/files/5461382/quiet-powerful.txt const uint16_t rawData[201] = { 3548, 3448, 922, 826, 922, 2576, 922, 2574, 918, 832, 916, 830, 918, 830, 918, 830, 918, 2574, 924, 824, 922, 2576, 922, 2574, 922, 826, 922, 826, 922, 826, 922, 826, 922, 2574, 922, 2574, 918, 830, 918, 2574, 922, 832, 916, 2574, 922, 2574, 922, 830, 918, 830, 918, 2574, 922, 826, 922, 2576, 922, 826, 922, 2574, 922, 2574, 922, 826, 922, 826, 3542, 3452, 918, 830, 918, 2574, 922, 2574, 922, 830, 916, 830, 918, 830, 918, 830, 918, 2574, 922, 832, 916, 2574, 922, 2574, 922, 830, 918, 830, 916, 830, 918, 830, 918, 2576, 922, 2574, 922, 826, 922, 2574, 922, 826, 922, 2574, 922, 2574, 918, 830, 916, 830, 918, 2580, 918, 830, 918, 2578, 918, 830, 918, 2580, 918, 2574, 922, 830, 918, 830, 3544, 3446, 922, 832, 916, 2574, 922, 2574, 922, 826, 922, 826, 922, 826, 922, 826, 922, 2574, 918, 830, 918, 2580, 916, 2580, 918, 830, 918, 830, 918, 830, 916, 830, 918, 2580, 918, 2574, 922, 830, 918, 2574, 922, 830, 916, 2576, 922, 2574, 922, 830, 918, 830, 918, 2574, 922, 830, 916, 2576, 922, 830, 918, 2574, 922, 2576, 922, 830, 918, 830, 3538, 3450, 922}; // UNKNOWN A9E430DB irsend.sendRaw(rawData, 201, kPanasonicFreq); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC32, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAc32Bits / 2, irsend.capture.bits); EXPECT_EQ(0x3586, irsend.capture.value); EXPECT_EQ(0, irsend.capture.address); EXPECT_EQ(0, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); EXPECT_EQ( "", IRAcUtils::resultAcToString(&irsend.capture)); stdAc::state_t r, p; ASSERT_FALSE(IRAcUtils::decodeToState(&irsend.capture, &r, &p)); } // Decode a synthetic *short Panasonic AC 64 bit message TEST(TestDecodePanasonicAC32, SyntheticShortMessage) { IRsendTest irsend(kGpioUnused); IRrecv irrecv(kGpioUnused); irsend.begin(); irsend.sendPanasonicAC32(0x3586, kPanasonicAc32Bits / 2); irsend.makeDecodeResult(); ASSERT_TRUE(irrecv.decode(&irsend.capture)); ASSERT_EQ(PANASONIC_AC32, irsend.capture.decode_type); EXPECT_EQ(kPanasonicAc32Bits / 2, irsend.capture.bits); EXPECT_EQ(0x3586, irsend.capture.value); EXPECT_EQ(0, irsend.capture.address); EXPECT_EQ(0, irsend.capture.command); EXPECT_FALSE(irsend.capture.repeat); EXPECT_EQ( "f36700d50" "m3543s3450" "m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828m920s2575" "m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828m920s2575" "m920s2575m920s828m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m920s2575m920s828m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m3543s3450" "m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828m920s2575" "m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828m920s2575" "m920s2575m920s828m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m920s2575m920s828m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m3543s3450" "m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828m920s2575" "m920s828m920s2575m920s2575m920s828m920s828m920s828m920s828m920s2575" "m920s2575m920s828m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m920s2575m920s828m920s2575m920s828m920s2575m920s2575m920s828m920s828" "m3543s3450" "m920s13946", irsend.outputStr()); } TEST(TestIRPanasonicAc32Class, SetAndGetPower) { IRPanasonicAc32 ac(kGpioUnused); ac.setPowerToggle(false); EXPECT_FALSE(ac.getPowerToggle()); ac.setPowerToggle(true); EXPECT_TRUE(ac.getPowerToggle()); ac.setPowerToggle(false); EXPECT_FALSE(ac.getPowerToggle()); // Ref: https://github.com/crankyoldgit/IRremoteESP8266/issues/1364#issuecomment-750427966 ac.setRaw(0x04FF36A0); EXPECT_TRUE(ac.getPowerToggle()); } TEST(TestIRPanasonicAc32Class, SetAndGetFan) { IRPanasonicAc32 ac(kGpioUnused); ac.setFan(kPanasonicAc32FanAuto); EXPECT_EQ(kPanasonicAc32FanAuto, ac.getFan()); ac.setFan(kPanasonicAc32FanMin); EXPECT_EQ(kPanasonicAc32FanMin, ac.getFan()); ac.setFan(kPanasonicAc32FanMin - 1); EXPECT_EQ(kPanasonicAc32FanAuto, ac.getFan()); ac.setFan(kPanasonicAc32FanMed); EXPECT_EQ(kPanasonicAc32FanMed, ac.getFan()); ac.setFan(kPanasonicAc32FanMax); EXPECT_EQ(kPanasonicAc32FanMax, ac.getFan()); ac.setFan(kPanasonicAc32FanMax + 1); EXPECT_EQ(kPanasonicAc32FanAuto, ac.getFan()); } TEST(TestIRPanasonicAc32Class, SetAndGetMode) { IRPanasonicAc32 ac(kGpioUnused); ac.setMode(kPanasonicAc32Cool); EXPECT_EQ(kPanasonicAc32Cool, ac.getMode()); ac.setMode(kPanasonicAc32Heat); EXPECT_EQ(kPanasonicAc32Heat, ac.getMode()); ac.setMode(kPanasonicAc32Auto); EXPECT_EQ(kPanasonicAc32Auto, ac.getMode()); ac.setMode(kPanasonicAc32Dry); EXPECT_EQ(kPanasonicAc32Dry, ac.getMode()); ac.setMode(kPanasonicAcFan); EXPECT_EQ(kPanasonicAcFan, ac.getMode()); ac.setMode(255); EXPECT_EQ(kPanasonicAc32Auto, ac.getMode()); } TEST(TestIRPanasonicAc32Class, SetAndGetTemp) { IRPanasonicAc ac(kGpioUnused); ac.setTemp(25); EXPECT_EQ(25, ac.getTemp()); ac.setTemp(kPanasonicAcMinTemp); EXPECT_EQ(kPanasonicAcMinTemp, ac.getTemp()); ac.setTemp(kPanasonicAcMinTemp - 1); EXPECT_EQ(kPanasonicAcMinTemp, ac.getTemp()); ac.setTemp(kPanasonicAcMaxTemp); EXPECT_EQ(kPanasonicAcMaxTemp, ac.getTemp()); ac.setTemp(kPanasonicAcMaxTemp + 1); EXPECT_EQ(kPanasonicAcMaxTemp, ac.getTemp()); } TEST(TestIRPanasonicAc32Class, SetAndGetSwings) { IRPanasonicAc32 ac(kGpioUnused); // Horizontal ac.setSwingHorizontal(true); EXPECT_TRUE(ac.getSwingHorizontal()); ac.setSwingHorizontal(false); EXPECT_FALSE(ac.getSwingHorizontal()); ac.setSwingHorizontal(true); EXPECT_TRUE(ac.getSwingHorizontal()); // Vertical ac.setSwingVertical(kPanasonicAc32SwingVAuto); EXPECT_EQ(kPanasonicAc32SwingVAuto, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVHighest); EXPECT_EQ(kPanasonicAcSwingVHighest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVHighest - 1); EXPECT_EQ(kPanasonicAcSwingVHighest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVHighest + 1); EXPECT_EQ(kPanasonicAcSwingVHighest + 1, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVLowest); EXPECT_EQ(kPanasonicAcSwingVLowest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVLowest + 1); EXPECT_EQ(kPanasonicAcSwingVLowest, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAcSwingVLowest - 1); EXPECT_EQ(kPanasonicAcSwingVLowest - 1, ac.getSwingVertical()); ac.setSwingVertical(kPanasonicAc32SwingVAuto); EXPECT_EQ(kPanasonicAc32SwingVAuto, ac.getSwingVertical()); } TEST(TestIRPanasonicAc32Class, HumanReadable) { IRPanasonicAc32 ac(kGpioUnused); EXPECT_EQ( "Power Toggle: Off, Mode: 2 (Cool), Temp: 16C, Fan: 15 (Auto), " "Swing(H): On, Swing(V): 7 (Auto)", ac.toString()); ac.setMode(kPanasonicAc32Heat); ac.setTemp(24); ac.setFan(kPanasonicAc32FanMed); ac.setSwingHorizontal(false); ac.setSwingVertical(kPanasonicAcSwingVLowest); ac.setPowerToggle(true); EXPECT_EQ( "Power Toggle: On, Mode: 4 (Heat), Temp: 24C, Fan: 4 (Medium), " "Swing(H): Off, Swing(V): 5 (Lowest)", ac.toString()); }