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gerrit.openbmc.org / openbmc / phosphor-pid-control / 7c6d35d5c439196254a7ca600b2d6bc0650adf4a / . / test / pid_json_unittest.cpp
blob: c58f3f4116cb411849f4ecc652cb2a45c8902d4e [file] [log] [blame]
#include "pid/buildjson.hpp"
#include <gmock/gmock.h>
#include <gtest/gtest.h>
namespace pid_control
{
namespace
{
TEST(ZoneFromJson, emptyZone)
{
// There is a zone key, but it's empty.
// This is technically invalid.
std::map<int64_t, conf::PIDConf> pidConfig;
std::map<int64_t, conf::ZoneConfig> zoneConfig;
auto j2 = R"(
{
"zones": []
}
)"_json;
std::tie(pidConfig, zoneConfig) = buildPIDsFromJson(j2);
EXPECT_TRUE(pidConfig.empty());
EXPECT_TRUE(zoneConfig.empty());
}
TEST(ZoneFromJson, oneZoneOnePid)
{
// Parse a valid configuration with one zone and one PID.
// Intentionally omits "derivativeCoeff" to test that it is optional.
std::map<int64_t, conf::PIDConf> pidConfig;
std::map<int64_t, conf::ZoneConfig> zoneConfig;
auto j2 = R"(
{
"zones" : [{
"id": 1,
"minThermalOutput": 3000.0,
"failsafePercent": 75.0,
"pids": [{
"name": "fan1-5",
"type": "fan",
"inputs": ["fan1", "fan5"],
"setpoint": 90.0,
"pid": {
"samplePeriod": 0.1,
"proportionalCoeff": 0.0,
"integralCoeff": 0.0,
"feedFwdOffsetCoeff": 0.0,
"feedFwdGainCoeff": 0.010,
"integralLimit_min": 0.0,
"integralLimit_max": 0.0,
"outLim_min": 30.0,
"outLim_max": 100.0,
"slewNeg": 0.0,
"slewPos": 0.0
}
}]
}]
}
)"_json;
std::tie(pidConfig, zoneConfig) = buildPIDsFromJson(j2);
EXPECT_EQ(pidConfig.size(), static_cast<u_int64_t>(1));
EXPECT_EQ(zoneConfig.size(), static_cast<u_int64_t>(1));
EXPECT_EQ(pidConfig[1]["fan1-5"].type, "fan");
EXPECT_DOUBLE_EQ(zoneConfig[1].minThermalOutput, 3000.0);
}
TEST(ZoneFromJson, oneZoneOnePidWithHysteresis)
{
// Parse a valid configuration with one zone and one PID and the PID uses
// Hysteresis parameters.
std::map<int64_t, conf::PIDConf> pidConfig;
std::map<int64_t, conf::ZoneConfig> zoneConfig;
auto j2 = R"(
{
"zones" : [{
"id": 1,
"minThermalOutput": 3000.0,
"failsafePercent": 75.0,
"pids": [{
"name": "fan1-5",
"type": "fan",
"inputs": ["fan1", "fan5"],
"setpoint": 90.0,
"pid": {
"samplePeriod": 0.1,
"proportionalCoeff": 0.0,
"integralCoeff": 0.0,
"derivativeCoeff": 0.0,
"feedFwdOffsetCoeff": 0.0,
"feedFwdGainCoeff": 0.010,
"integralLimit_min": 0.0,
"integralLimit_max": 0.0,
"outLim_min": 30.0,
"outLim_max": 100.0,
"slewNeg": 0.0,
"slewPos": 0.0,
"positiveHysteresis": 1000.0,
"negativeHysteresis": 9000.0
}
}]
}]
}
)"_json;
std::tie(pidConfig, zoneConfig) = buildPIDsFromJson(j2);
EXPECT_EQ(pidConfig.size(), static_cast<u_int64_t>(1));
EXPECT_EQ(zoneConfig.size(), static_cast<u_int64_t>(1));
EXPECT_EQ(pidConfig[1]["fan1-5"].type, "fan");
EXPECT_DOUBLE_EQ(pidConfig[1]["fan1-5"].pidInfo.positiveHysteresis, 1000.0);
EXPECT_DOUBLE_EQ(zoneConfig[1].minThermalOutput, 3000.0);
}
TEST(ZoneFromJson, oneZoneOneStepwiseWithHysteresis)
{
// Parse a valid configuration with one zone and one PID and the PID uses
// Hysteresis parameters.
std::map<int64_t, conf::PIDConf> pidConfig;
std::map<int64_t, conf::ZoneConfig> zoneConfig;
auto j2 = R"(
{
"zones" : [{
"id": 1,
"minThermalOutput": 3000.0,
"failsafePercent": 75.0,
"pids": [{
"name": "temp1",
"type": "stepwise",
"inputs": ["temp1"],
"setpoint": 30.0,
"pid": {
"samplePeriod": 0.1,
"positiveHysteresis": 1.0,
"negativeHysteresis": 1.0,
"isCeiling": false,
"reading": {
"0": 45,
"1": 46,
"2": 47,
"3": 48,
"4": 49,
"5": 50,
"6": 51,
"7": 52,
"8": 53,
"9": 54,
"10": 55,
"11": 56,
"12": 57,
"13": 58,
"14": 59,
"15": 60,
"16": 61,
"17": 62,
"18": 63,
"19": 64
},
"output": {
"0": 5000,
"1": 2400,
"2": 2600,
"3": 2800,
"4": 3000,
"5": 3200,
"6": 3400,
"7": 3600,
"8": 3800,
"9": 4000,
"10": 4200,
"11": 4400,
"12": 4600,
"13": 4800,
"14": 5000,
"15": 5200,
"16": 5400,
"17": 5600,
"18": 5800,
"19": 6000
}
}
}]
}]
}
)"_json;
std::tie(pidConfig, zoneConfig) = buildPIDsFromJson(j2);
EXPECT_EQ(pidConfig.size(), static_cast<u_int64_t>(1));
EXPECT_EQ(zoneConfig.size(), static_cast<u_int64_t>(1));
EXPECT_EQ(pidConfig[1]["temp1"].type, "stepwise");
EXPECT_DOUBLE_EQ(pidConfig[1]["temp1"].stepwiseInfo.positiveHysteresis,
1.0);
EXPECT_DOUBLE_EQ(zoneConfig[1].minThermalOutput, 3000.0);
}
TEST(ZoneFromJson, getCycleInterval)
{
// Parse a valid configuration with one zone and one PID and the zone have
// cycleIntervalTime and updateThermalsTime parameters.
std::map<int64_t, conf::PIDConf> pidConfig;
std::map<int64_t, conf::ZoneConfig> zoneConfig;
auto j2 = R"(
{
"zones" : [{
"id": 1,
"minThermalOutput": 3000.0,
"failsafePercent": 75.0,
"cycleIntervalTimeMS": 1000.0,
"updateThermalsTimeMS": 1000.0,
"pids": [{
"name": "fan1-5",
"type": "fan",
"inputs": ["fan1", "fan5"],
"setpoint": 90.0,
"pid": {
"samplePeriod": 0.1,
"proportionalCoeff": 0.0,
"integralCoeff": 0.0,
"derivativeCoeff": 0.0,
"feedFwdOffsetCoeff": 0.0,
"feedFwdGainCoeff": 0.010,
"integralLimit_min": 0.0,
"integralLimit_max": 0.0,
"outLim_min": 30.0,
"outLim_max": 100.0,
"slewNeg": 0.0,
"slewPos": 0.0
}
}]
}]
}
)"_json;
std::tie(pidConfig, zoneConfig) = buildPIDsFromJson(j2);
EXPECT_EQ(pidConfig.size(), 1);
EXPECT_EQ(zoneConfig.size(), 1);
EXPECT_EQ(pidConfig[1]["fan1-5"].type, "fan");
EXPECT_EQ(zoneConfig[1].cycleTime.cycleIntervalTimeMS, 1000);
EXPECT_EQ(zoneConfig[1].cycleTime.updateThermalsTimeMS, 1000);
EXPECT_DOUBLE_EQ(zoneConfig[1].minThermalOutput, 3000.0);
}
} // namespace
} // namespace pid_control