Tasmota/lib/IRremoteESP8266-2.6.0/test/IRac_test.cpp

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// Copyright 2019 David Conran
#include "ir_Argo.h"
#include "ir_Daikin.h"
#include "ir_Fujitsu.h"
#include "ir_Gree.h"
#include "ir_Haier.h"
#include "ir_Hitachi.h"
#include "ir_Kelvinator.h"
#include "ir_Midea.h"
#include "ir_Mitsubishi.h"
#include "ir_MitsubishiHeavy.h"
#include "ir_Panasonic.h"
#include "ir_Samsung.h"
#include "ir_Tcl.h"
#include "ir_Teco.h"
#include "ir_Toshiba.h"
#include "ir_Trotec.h"
#include "ir_Vestel.h"
#include "ir_Whirlpool.h"
#include "IRac.h"
#include "IRrecv.h"
#include "IRrecv_test.h"
#include "IRremoteESP8266.h"
#include "IRsend.h"
#include "IRsend_test.h"
#include "gtest/gtest.h"
// Tests for IRac class.
TEST(TestIRac, Argo) {
IRArgoAC ac(0);
IRac irac(0);
ac.begin();
irac.argo(&ac,
true, // Power
stdAc::opmode_t::kHeat, // Mode
21, // Celsius
stdAc::fanspeed_t::kHigh, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
false, // Turbo
-1); // Sleep
EXPECT_TRUE(ac.getPower());
EXPECT_EQ(1, ac.getMode());
EXPECT_EQ(21, ac.getTemp());
EXPECT_EQ(kArgoFlapAuto, ac.getFlap());
EXPECT_FALSE(ac.getMax()); // Turbo
EXPECT_FALSE(ac.getNight()); // Sleep
}
TEST(TestIRac, Coolix) {
IRCoolixAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 3 (HEAT), Fan: 1 (MAX), Temp: 21C, Zone Follow: Off, "
"Sensor Temp: Ignored";
ac.begin();
irac.coolix(&ac,
true, // Power
stdAc::opmode_t::kHeat, // Mode
21, // Celsius
stdAc::fanspeed_t::kHigh, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false, // Turbo
false, // Light
false, // Clean
-1); // Sleep
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(COOLIX, ac._irsend.capture.decode_type);
ASSERT_EQ(kCoolixBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.value);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Daikin) {
IRDaikinESP ac(0);
IRac irac(0);
char expected[] =
"Power: On, Mode: 3 (COOL), Temp: 19C, Fan: 2, Powerful: Off, "
"Quiet: Off, Sensor: Off, Eye: Off, Mold: On, Comfort: Off, "
"Swing (Horizontal): Off, Swing (Vertical): Off, "
"Current Time: 0:00, On Time: Off, Off Time: Off";
ac.begin();
irac.daikin(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
19, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false, // Quiet
false, // Turbo
true, // Filter
true); // Clean
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Daikin2) {
IRDaikin2 ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 3 (COOL), Temp: 19C, Fan: 2, Swing (V): 14 (Auto), "
"Swing (H): 0, Clock: 0:00, On Time: Off, Off Time: Off, "
"Sleep Time: Off, Beep: 1 (Quiet), Light: 1 (Bright), Mold: On, "
"Clean: Off, Fresh Air: Off, Eye: Off, Eye Auto: Off, Quiet: Off, "
"Powerful: Off, Purify: On, Econo: Off";
ac.begin();
irac.daikin2(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
19, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false, // Quiet
false, // Turbo
true, // Light
false, // Econo
true, // Filter
true, // Clean (aka Mold)
-1, // Sleep time
-1); // Current time
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(DAIKIN2, ac._irsend.capture.decode_type);
ASSERT_EQ(kDaikin2Bits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Daikin216) {
IRDaikin216 ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 4 (HEAT), Temp: 31C, Fan: 11 (QUIET), "
"Swing (Horizontal): On, Swing (Vertical): On, Quiet: On";
ac.begin();
irac.daikin216(&ac,
true, // Power
stdAc::opmode_t::kHeat, // Mode
31, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
stdAc::swingh_t::kLeft, // Horizontal swing
true); // Quiet
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(DAIKIN216, ac._irsend.capture.decode_type);
ASSERT_EQ(kDaikin216Bits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Fujitsu) {
IRFujitsuAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 1 (COOL), Temp: 19C, Fan: 2 (MED), "
"Swing: Off, Command: N/A";
ac.begin();
irac.fujitsu(&ac,
ARDB1, // Model
true, // Power
stdAc::opmode_t::kCool, // Mode
19, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false); // Quiet
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(FUJITSU_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kFujitsuAcBits - 8, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state, ac._irsend.capture.bits / 8);
ASSERT_EQ(expected, ac.toString());
ac._irsend.reset();
irac.fujitsu(&ac,
ARRAH2E, // Model
true, // Power
stdAc::opmode_t::kCool, // Mode
19, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false); // Quiet
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(FUJITSU_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kFujitsuAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state, ac._irsend.capture.bits / 8);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Gree) {
IRGreeAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 1 (COOL), Temp: 22C, Fan: 2, Turbo: Off, XFan: On, "
"Light: On, Sleep: On, Swing Vertical Mode: Manual, "
"Swing Vertical Pos: 3";
ac.begin();
irac.gree(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
22, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
false, // Turbo
true, // Light
true, // Clean (aka Mold/XFan)
8 * 60 + 0); // Sleep time
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(GREE, ac._irsend.capture.decode_type);
ASSERT_EQ(kGreeBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Haier) {
IRHaierAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Command: 1 (On), Mode: 3 (HEAT), Temp: 24C, Fan: 2, Swing: 1 (Up), "
"Sleep: On, Health: On, Current Time: 13:45, On Timer: Off, "
"Off Timer: Off";
ac.begin();
irac.haier(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
24, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
true, // Filter
8 * 60 + 0, // Sleep time
13 * 60 + 45); // Clock
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(HAIER_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kHaierACBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, HaierYrwo2) {
IRHaierACYRW02 ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Button: 5 (Power), Mode: 2 (Cool), Temp: 23C, Fan: 4 (Med), "
"Turbo: 1 (High), Swing: 1 (Top), Sleep: On, Health: On";
ac.begin();
irac.haierYrwo2(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
23, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
true, // Turbo
true, // Filter
8 * 60 + 0); // Sleep time
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(HAIER_AC_YRW02, ac._irsend.capture.decode_type);
ASSERT_EQ(kHaierACYRW02Bits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Hitachi) {
IRHitachiAc ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 2 (AUTO), Temp: 22C, Fan: 3 (UNKNOWN), "
"Swing (Vertical): Off, Swing (Horizontal): On";
ac.begin();
irac.hitachi(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
22, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kAuto); // Horizontal swing
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(HITACHI_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kHitachiAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Kelvinator) {
IRKelvinatorAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 1 (COOL), Temp: 19C, Fan: 3, Turbo: Off, Quiet: Off, "
"XFan: On, IonFilter: On, Light: On, Swing (Horizontal): Off, "
"Swing (Vertical): Off";
ac.begin();
irac.kelvinator(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
19, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false, // Quiet
false, // Turbo
true, // Light
true, // Filter
true); // Clean
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(KELVINATOR, ac._irsend.capture.decode_type);
ASSERT_EQ(kKelvinatorBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Midea) {
IRMideaAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 1 (DRY), Temp: 27C/81F, Fan: 2 (MED), Sleep: On";
ac.begin();
irac.midea(&ac,
true, // Power
stdAc::opmode_t::kDry, // Mode
27, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
8 * 60 + 0); // Sleep time
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(MIDEA, ac._irsend.capture.decode_type);
ASSERT_EQ(kMideaBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.value);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Mitsubishi) {
IRMitsubishiAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On (COOL), Temp: 20C, FAN: 2, VANE: AUTO, Time: 14:30, "
"On timer: 00:00, Off timer: 00:00, Timer: -";
ac.begin();
irac.mitsubishi(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
20, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
false, // Silent
14 * 60 + 35); // Clock
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(MITSUBISHI_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kMitsubishiACBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, MitsubishiHeavy88) {
IRMitsubishiHeavy88Ac ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 1 (Cool), Temp: 21C, Fan: 3 (Med), "
"Swing (V): 16 (Auto), Swing (H): 0 (Off), Turbo: Off, Econo: Off, "
"3D: Off, Clean: On";
ac.begin();
irac.mitsubishiHeavy88(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
21, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
stdAc::swingh_t::kOff, // Horizontal swing
false, // Turbo
false, // Econo
true); // Clean
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(MITSUBISHI_HEAVY_88, ac._irsend.capture.decode_type);
ASSERT_EQ(kMitsubishiHeavy88Bits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, MitsubishiHeavy152) {
IRMitsubishiHeavy152Ac ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 1 (Cool), Temp: 20C, Fan: 6 (Econo), "
"Swing (V): 6 (Off), Swing (H): 0 (Auto), Silent: On, Turbo: Off, "
"Econo: On, Night: On, Filter: On, 3D: Off, Clean: Off";
ac.begin();
irac.mitsubishiHeavy152(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
20, // Celsius
stdAc::fanspeed_t::kLow, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kAuto, // Horizontal swing
true, // Silent
false, // Turbo
true, // Econo
true, // Filter
false, // Clean
8 * 60); // Sleep
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(MITSUBISHI_HEAVY_152, ac._irsend.capture.decode_type);
ASSERT_EQ(kMitsubishiHeavy152Bits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Panasonic) {
IRPanasonicAc ac(0);
IRac irac(0);
IRrecv capture(0);
char expected_nke[] =
"Model: 2 (NKE), Power: On, Mode: 4 (HEAT), Temp: 28C, Fan: 2 (UNKNOWN), "
"Swing (Vertical): 15 (AUTO), Swing (Horizontal): 6 (Middle), Quiet: On, "
"Powerful: Off, Clock: 19:17, On Timer: Off, Off Timer: Off";
ac.begin();
irac.panasonic(&ac,
kPanasonicNke, // Model
true, // Power
stdAc::opmode_t::kHeat, // Mode
28, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
stdAc::swingh_t::kLeft, // Horizontal swing
true, // Quiet
false, // Turbo
19 * 60 + 17); // Clock
ASSERT_EQ(expected_nke, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(PANASONIC_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kPanasonicAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected_nke, ac.toString());
char expected_dke[] =
"Model: 3 (DKE), Power: On, Mode: 3 (COOL), Temp: 18C, Fan: 4 (MAX), "
"Swing (Vertical): 1 (Full Up), Swing (Horizontal): 6 (Middle), "
"Quiet: Off, Powerful: On, Clock: 19:17, On Timer: Off, Off Timer: Off";
ac._irsend.reset();
irac.panasonic(&ac,
kPanasonicDke, // Model
true, // Power
stdAc::opmode_t::kCool, // Mode
18, // Celsius
stdAc::fanspeed_t::kMax, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
stdAc::swingh_t::kMiddle, // Horizontal swing
false, // Quiet
true, // Turbo
19 * 60 + 17); // Clock
ASSERT_EQ(expected_dke, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(PANASONIC_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kPanasonicAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected_dke, ac.toString());
}
TEST(TestIRac, Samsung) {
IRSamsungAc ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 0 (AUTO), Temp: 28C, Fan: 6 (AUTO), Swing: On, "
"Beep: On, Clean: On, Quiet: On";
ac.begin();
irac.samsung(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
28, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
true, // Quiet
false, // Turbo
true, // Clean
true, // Beep
false); // with the Hack Off
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(SAMSUNG_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kSamsungAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
ac._irsend.reset();
irac.samsung(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
28, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
true, // Quiet
false, // Turbo
true, // Clean
true, // Beep
true); // with the Hack On
ASSERT_EQ(expected, ac.toString()); // Class should be in the desired mode.
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(SAMSUNG_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kSamsungAcExtendedBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
// However, we expect a plain "on" state as it should be sent before the
// desired state.
char expected_on[] =
"Power: On, Mode: 0 (AUTO), Temp: 16C, Fan: 0 (AUTO), Swing: Off, "
"Beep: Off, Clean: Off, Quiet: Off";
ASSERT_EQ(expected_on, ac.toString());
}
TEST(TestIRac, Tcl112) {
IRTcl112Ac ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 3 (COOL), Temp: 20C, Fan: 3 (Med), Econo: On, "
"Health: On, Light: On, Turbo: Off, Swing (H): On, Swing (V): Off";
ac.begin();
irac.tcl112(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
20, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kOff, // Veritcal swing
stdAc::swingh_t::kAuto, // Horizontal swing
false, // Turbo
true, // Light
true, // Econo
true); // Filter (aka. Health)
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(TCL112AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kTcl112AcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Teco) {
IRTecoAc ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 0 (AUTO), Temp: 21C, Fan: 2 (Med), Sleep: On, "
"Swing: On";
ac.begin();
irac.teco(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
21, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
8 * 60 + 30); // Sleep
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(TECO, ac._irsend.capture.decode_type);
ASSERT_EQ(kTecoBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.value);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Toshiba) {
IRToshibaAC ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] = "Power: On, Mode: 2 (DRY), Temp: 29C, Fan: 2";
ac.begin();
irac.toshiba(&ac,
true, // Power
stdAc::opmode_t::kDry, // Mode
29, // Celsius
stdAc::fanspeed_t::kLow); // Fan speed
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(TOSHIBA_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kToshibaACBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, Trotec) {
IRTrotecESP ac(0);
IRac irac(0);
ac.begin();
irac.trotec(&ac,
true, // Power
stdAc::opmode_t::kCool, // Mode
18, // Celsius
stdAc::fanspeed_t::kHigh, // Fan speed
8 * 60 + 17); // Sleep
EXPECT_TRUE(ac.getPower());
EXPECT_EQ(kTrotecCool, ac.getMode());
EXPECT_EQ(18, ac.getTemp());
EXPECT_EQ(kTrotecFanHigh, ac.getSpeed());
EXPECT_TRUE(ac.getSleep());
}
TEST(TestIRac, Vestel) {
IRVestelAc ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Power: On, Mode: 0 (AUTO), Temp: 22C, Fan: 5 (LOW), Sleep: On, "
"Turbo: Off, Ion: On, Swing: On";
ac.begin();
irac.vestel(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
22, // Celsius
stdAc::fanspeed_t::kLow, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
false, // Turbo
true, // Filter
8 * 60 + 0); // Sleep time
// 13 * 60 + 45); // Clock
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(VESTEL_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kVestelAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
ac._irsend.reset();
char expected_clocks[] =
"Time: 13:45, Timer: Off, On Timer: Off, Off Timer: Off";
ac.begin();
irac.vestel(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
22, // Celsius
stdAc::fanspeed_t::kLow, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
false, // Turbo
true, // Filter
8 * 60 + 0, // Sleep time
13 * 60 + 45, // Clock
false); // Don't send the normal message.
// Just for testing purposes.
ASSERT_EQ(expected_clocks, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(VESTEL_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kVestelAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected_clocks, ac.toString());
// Now check it sends both messages during normal operation when the
// clock is set.
ac._irsend.reset();
ac.begin();
irac.vestel(&ac,
true, // Power
stdAc::opmode_t::kAuto, // Mode
22, // Celsius
stdAc::fanspeed_t::kLow, // Fan speed
stdAc::swingv_t::kHigh, // Veritcal swing
false, // Turbo
true, // Filter
8 * 60 + 0, // Sleep time
13 * 60 + 45); // Clock
EXPECT_EQ(
"f38000d50"
"m3110s9066"
"m520s1535m520s480m520s480m520s480m520s480m520s480m520s480m520s480"
"m520s480m520s1535m520s480m520s480m520s480m520s480m520s480m520s480"
"m520s1535m520s1535m520s1535m520s1535m520s480m520s1535m520s480m520s1535"
"m520s1535m520s1535m520s480m520s480m520s480m520s480m520s480m520s480"
"m520s480m520s480m520s480m520s480m520s480m520s1535m520s1535m520s480"
"m520s1535m520s480m520s1535m520s480m520s480m520s480m520s480m520s480"
"m520s480m520s480m520s1535m520s480m520s1535m520s1535m520s1535m520s1535"
"m520s100000"
"m3110s9066"
"m520s1535m520s480m520s480m520s480m520s480m520s480m520s480m520s480"
"m520s480m520s1535m520s480m520s480m520s480m520s1535m520s1535m520s480"
"m520s1535m520s1535m520s1535m520s1535m520s480m520s480m520s480m520s480"
"m520s480m520s480m520s480m520s480m520s480m520s480m520s480m520s480"
"m520s480m520s480m520s480m520s480m520s1535m520s480m520s1535m520s1535"
"m520s480m520s480m520s480m520s480m520s1535m520s480m520s1535m520s1535"
"m520s480m520s1535m520s480m520s480m520s480m520s480m520s480m520s480"
"m520s100000", ac._irsend.outputStr());
}
TEST(TestIRac, Whirlpool) {
IRWhirlpoolAc ac(0);
IRac irac(0);
IRrecv capture(0);
char expected[] =
"Model: 1 (DG11J13A), Power toggle: On, Mode: 1 (AUTO), Temp: 21C, "
"Fan: 3 (LOW), Swing: On, Light: On, Clock: 23:58, On Timer: Off, "
"Off Timer: Off, Sleep: On, Super: Off, Command: 1 (POWER)";
ac.begin();
irac.whirlpool(&ac,
DG11J13A,
true, // Power
stdAc::opmode_t::kAuto, // Mode
21, // Celsius
stdAc::fanspeed_t::kMedium, // Fan speed
stdAc::swingv_t::kAuto, // Veritcal swing
false, // Turbo
true, // Light
8 * 60 + 30, // Sleep
23 * 60 + 58); // Clock
ASSERT_EQ(expected, ac.toString());
ac._irsend.makeDecodeResult();
EXPECT_TRUE(capture.decode(&ac._irsend.capture));
ASSERT_EQ(WHIRLPOOL_AC, ac._irsend.capture.decode_type);
ASSERT_EQ(kWhirlpoolAcBits, ac._irsend.capture.bits);
ac.setRaw(ac._irsend.capture.state);
ASSERT_EQ(expected, ac.toString());
}
TEST(TestIRac, strToBool) {
EXPECT_TRUE(IRac::strToBool("ON"));
EXPECT_TRUE(IRac::strToBool("1"));
EXPECT_TRUE(IRac::strToBool("TRUE"));
EXPECT_TRUE(IRac::strToBool("YES"));
EXPECT_FALSE(IRac::strToBool("OFF"));
EXPECT_FALSE(IRac::strToBool("0"));
EXPECT_FALSE(IRac::strToBool("FALSE"));
EXPECT_FALSE(IRac::strToBool("NO"));
EXPECT_FALSE(IRac::strToBool("FOOBAR"));
EXPECT_TRUE(IRac::strToBool("FOOBAR", true));
}
TEST(TestIRac, strToOpmode) {
EXPECT_EQ(stdAc::opmode_t::kAuto, IRac::strToOpmode("AUTO"));
EXPECT_EQ(stdAc::opmode_t::kCool, IRac::strToOpmode("COOL"));
EXPECT_EQ(stdAc::opmode_t::kHeat, IRac::strToOpmode("HEAT"));
EXPECT_EQ(stdAc::opmode_t::kDry, IRac::strToOpmode("DRY"));
EXPECT_EQ(stdAc::opmode_t::kFan, IRac::strToOpmode("FAN"));
EXPECT_EQ(stdAc::opmode_t::kFan, IRac::strToOpmode("FAN_ONLY"));
EXPECT_EQ(stdAc::opmode_t::kAuto, IRac::strToOpmode("FOOBAR"));
EXPECT_EQ(stdAc::opmode_t::kOff, IRac::strToOpmode("OFF"));
EXPECT_EQ(stdAc::opmode_t::kOff, IRac::strToOpmode("FOOBAR",
stdAc::opmode_t::kOff));
}
TEST(TestIRac, strToFanspeed) {
EXPECT_EQ(stdAc::fanspeed_t::kAuto, IRac::strToFanspeed("AUTO"));
EXPECT_EQ(stdAc::fanspeed_t::kMin, IRac::strToFanspeed("MIN"));
EXPECT_EQ(stdAc::fanspeed_t::kLow, IRac::strToFanspeed("LOW"));
EXPECT_EQ(stdAc::fanspeed_t::kMedium, IRac::strToFanspeed("MEDIUM"));
EXPECT_EQ(stdAc::fanspeed_t::kHigh, IRac::strToFanspeed("HIGH"));
EXPECT_EQ(stdAc::fanspeed_t::kMax, IRac::strToFanspeed("MAX"));
EXPECT_EQ(stdAc::fanspeed_t::kAuto, IRac::strToFanspeed("FOOBAR"));
EXPECT_EQ(stdAc::fanspeed_t::kMin,
IRac::strToFanspeed("FOOBAR", stdAc::fanspeed_t::kMin));
}
TEST(TestIRac, strToSwingV) {
EXPECT_EQ(stdAc::swingv_t::kAuto, IRac::strToSwingV("AUTO"));
EXPECT_EQ(stdAc::swingv_t::kLowest, IRac::strToSwingV("LOWEST"));
EXPECT_EQ(stdAc::swingv_t::kLow, IRac::strToSwingV("LOW"));
EXPECT_EQ(stdAc::swingv_t::kMiddle, IRac::strToSwingV("MIDDLE"));
EXPECT_EQ(stdAc::swingv_t::kHigh, IRac::strToSwingV("HIGH"));
EXPECT_EQ(stdAc::swingv_t::kHighest, IRac::strToSwingV("HIGHEST"));
EXPECT_EQ(stdAc::swingv_t::kOff, IRac::strToSwingV("OFF"));
EXPECT_EQ(stdAc::swingv_t::kOff, IRac::strToSwingV("FOOBAR"));
EXPECT_EQ(stdAc::swingv_t::kAuto,
IRac::strToSwingV("FOOBAR", stdAc::swingv_t::kAuto));
}
TEST(TestIRac, strToSwingH) {
EXPECT_EQ(stdAc::swingh_t::kAuto, IRac::strToSwingH("AUTO"));
EXPECT_EQ(stdAc::swingh_t::kLeftMax, IRac::strToSwingH("MAX LEFT"));
EXPECT_EQ(stdAc::swingh_t::kLeft, IRac::strToSwingH("LEFT"));
EXPECT_EQ(stdAc::swingh_t::kMiddle, IRac::strToSwingH("CENTRE"));
EXPECT_EQ(stdAc::swingh_t::kRight, IRac::strToSwingH("RIGHT"));
EXPECT_EQ(stdAc::swingh_t::kRightMax, IRac::strToSwingH("RIGHTMAX"));
EXPECT_EQ(stdAc::swingh_t::kOff, IRac::strToSwingH("OFF"));
EXPECT_EQ(stdAc::swingh_t::kOff, IRac::strToSwingH("FOOBAR"));
EXPECT_EQ(stdAc::swingh_t::kAuto,
IRac::strToSwingH("FOOBAR", stdAc::swingh_t::kAuto));
}
TEST(TestIRac, strToModel) {
EXPECT_EQ(panasonic_ac_remote_model_t::kPanasonicLke,
IRac::strToModel("LKE"));
EXPECT_EQ(panasonic_ac_remote_model_t::kPanasonicLke,
IRac::strToModel("PANASONICLKE"));
EXPECT_EQ(fujitsu_ac_remote_model_t::ARRAH2E,
IRac::strToModel("ARRAH2E"));
EXPECT_EQ(whirlpool_ac_remote_model_t::DG11J13A,
IRac::strToModel("DG11J13A"));
EXPECT_EQ(1, IRac::strToModel("1"));
EXPECT_EQ(10, IRac::strToModel("10"));
EXPECT_EQ(-1, IRac::strToModel("0"));
EXPECT_EQ(-1, IRac::strToModel("FOOBAR"));
EXPECT_EQ(0, IRac::strToModel("FOOBAR", 0));
}