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betaflight/src/test/unit/blackbox_unittest.cc

403 lines
13 KiB
C++

/*
*
* Cleanflight is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Cleanflight is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Cleanflight. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdint.h>
#include <string.h>
extern "C" {
#include "platform.h"
#include "blackbox/blackbox.h"
#include "common/utils.h"
#include "pg/pg.h"
#include "pg/pg_ids.h"
#include "pg/rx.h"
#include "drivers/accgyro/accgyro.h"
#include "drivers/accgyro/gyro_sync.h"
#include "drivers/serial.h"
#include "flight/failsafe.h"
#include "flight/mixer.h"
#include "flight/pid.h"
#include "fc/rc_controls.h"
#include "fc/rc_modes.h"
#include "io/gps.h"
#include "io/serial.h"
#include "rx/rx.h"
#include "sensors/battery.h"
#include "sensors/gyro.h"
extern int16_t blackboxIInterval;
extern int16_t blackboxPInterval;
}
#include "unittest_macros.h"
#include "gtest/gtest.h"
gyroDev_t gyroDev;
TEST(BlackboxTest, TestInitIntervals)
{
blackboxConfigMutable()->p_ratio = 32;
// 250Hz PIDloop
targetPidLooptime = 4000;
blackboxInit();
EXPECT_EQ(8, blackboxIInterval);
EXPECT_EQ(0, blackboxPInterval);
EXPECT_EQ(2048, blackboxSInterval);
// 500Hz PIDloop
targetPidLooptime = 2000;
blackboxInit();
EXPECT_EQ(16, blackboxIInterval);
EXPECT_EQ(0, blackboxPInterval);
EXPECT_EQ(4096, blackboxSInterval);
// 1kHz PIDloop
gyro.targetLooptime = gyroSetSampleRate(&gyroDev, GYRO_HARDWARE_LPF_1KHZ_SAMPLE, 1);
targetPidLooptime = gyro.targetLooptime * 1;
blackboxInit();
EXPECT_EQ(32, blackboxIInterval);
EXPECT_EQ(1, blackboxPInterval);
EXPECT_EQ(8192, blackboxSInterval);
// 2kHz PIDloop
targetPidLooptime = 500;
blackboxInit();
EXPECT_EQ(64, blackboxIInterval);
EXPECT_EQ(2, blackboxPInterval);
EXPECT_EQ(16384, blackboxSInterval);
// 4kHz PIDloop
targetPidLooptime = 250;
blackboxInit();
EXPECT_EQ(128, blackboxIInterval);
EXPECT_EQ(4, blackboxPInterval);
EXPECT_EQ(32768, blackboxSInterval);
// 8kHz PIDloop
targetPidLooptime = 125;
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(8, blackboxPInterval);
EXPECT_EQ(65536, blackboxSInterval);
// 16kHz PIDloop
targetPidLooptime = 63; // rounded from 62.5
blackboxInit();
EXPECT_EQ(512, blackboxIInterval); // note rounding
EXPECT_EQ(16, blackboxPInterval);
EXPECT_EQ(131072, blackboxSInterval);
// 32kHz PIDloop
targetPidLooptime = 31; // rounded from 31.25
blackboxInit();
EXPECT_EQ(1024, blackboxIInterval); // note rounding
EXPECT_EQ(32, blackboxPInterval);
EXPECT_EQ(262144, blackboxSInterval);
}
TEST(BlackboxTest, Test_500Hz)
{
blackboxConfigMutable()->p_ratio = 32;
// 500Hz PIDloop
targetPidLooptime = 2000;
blackboxInit();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
for (int ii = 0; ii < 15; ++ii) {
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
}
blackboxAdvanceIterationTimers();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
}
TEST(BlackboxTest, Test_1kHz)
{
blackboxConfigMutable()->p_ratio = 32;
// 1kHz PIDloop
targetPidLooptime = 1000;
blackboxInit();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
EXPECT_EQ(0, blackboxSlowFrameIterationTimer);
EXPECT_EQ(false, blackboxSlowFrameIterationTimer >= blackboxSInterval);
blackboxSlowFrameIterationTimer = blackboxSInterval;
EXPECT_EQ(true, writeSlowFrameIfNeeded());
EXPECT_EQ(0, blackboxSlowFrameIterationTimer);
for (int ii = 0; ii < 31; ++ii) {
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
EXPECT_EQ(ii + 1, blackboxSlowFrameIterationTimer);
EXPECT_EQ(false, writeSlowFrameIfNeeded());
}
blackboxAdvanceIterationTimers();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
}
TEST(BlackboxTest, Test_2kHz)
{
blackboxConfigMutable()->p_ratio = 32;
// 2kHz PIDloop
targetPidLooptime = 500;
blackboxInit();
EXPECT_EQ(64, blackboxIInterval);
EXPECT_EQ(2, blackboxPInterval);
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(false, blackboxShouldLogPFrame());
for (int ii = 0; ii < 31; ++ii) {
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(false, blackboxShouldLogPFrame());
}
blackboxAdvanceIterationTimers();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(false, blackboxShouldLogPFrame());
}
TEST(BlackboxTest, Test_8kHz)
{
blackboxConfigMutable()->p_ratio = 32;
// 8kHz PIDloop
targetPidLooptime = 125;
blackboxInit();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
EXPECT_EQ(0, blackboxSlowFrameIterationTimer);
EXPECT_EQ(false, blackboxSlowFrameIterationTimer >= blackboxSInterval);
blackboxSlowFrameIterationTimer = blackboxSInterval;
EXPECT_EQ(true, writeSlowFrameIfNeeded());
EXPECT_EQ(0, blackboxSlowFrameIterationTimer);
for (int ii = 0; ii < 255; ++ii) {
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(ii + 1, blackboxSlowFrameIterationTimer);
EXPECT_EQ(false, writeSlowFrameIfNeeded());
}
blackboxAdvanceIterationTimers();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(true, blackboxShouldLogPFrame());
}
TEST(BlackboxTest, Test_zero_p_ratio)
{
blackboxConfigMutable()->p_ratio = 0;
// 1kHz PIDloop
targetPidLooptime = 1000;
blackboxInit();
EXPECT_EQ(32, blackboxIInterval);
EXPECT_EQ(0, blackboxPInterval);
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(false, blackboxShouldLogPFrame());
for (int ii = 0; ii < 31; ++ii) {
blackboxAdvanceIterationTimers();
EXPECT_EQ(false, blackboxShouldLogIFrame());
EXPECT_EQ(false, blackboxShouldLogPFrame());
}
blackboxAdvanceIterationTimers();
EXPECT_EQ(true, blackboxShouldLogIFrame());
EXPECT_EQ(false, blackboxShouldLogPFrame());
}
TEST(BlackboxTest, Test_CalculatePDenom)
{
blackboxConfigMutable()->p_ratio = 0;
// note I-frame is logged every 32ms regardless of PIDloop rate
// so p_ratio is 32 when blackbox logging rate is 1kHz
// 1kHz PIDloop
targetPidLooptime = 1000;
blackboxInit();
EXPECT_EQ(32, blackboxIInterval);
EXPECT_EQ(32, blackboxCalculatePDenom(1, 1)); // 1kHz logging
EXPECT_EQ(16, blackboxCalculatePDenom(1, 2));
EXPECT_EQ(8, blackboxCalculatePDenom(1, 4));
// 2kHz PIDloop
targetPidLooptime = 500;
blackboxInit();
EXPECT_EQ(64, blackboxIInterval);
EXPECT_EQ(64, blackboxCalculatePDenom(1, 1));
EXPECT_EQ(32, blackboxCalculatePDenom(1, 2)); // 1kHz logging
EXPECT_EQ(16, blackboxCalculatePDenom(1, 4));
// 4kHz PIDloop
targetPidLooptime = 250;
blackboxInit();
EXPECT_EQ(128, blackboxIInterval);
EXPECT_EQ(128, blackboxCalculatePDenom(1, 1));
EXPECT_EQ(64, blackboxCalculatePDenom(1, 2));
EXPECT_EQ(32, blackboxCalculatePDenom(1, 4)); // 1kHz logging
EXPECT_EQ(16, blackboxCalculatePDenom(1, 8));
// 8kHz PIDloop
targetPidLooptime = 125;
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(256, blackboxCalculatePDenom(1, 1));
EXPECT_EQ(128, blackboxCalculatePDenom(1, 2));
EXPECT_EQ(64, blackboxCalculatePDenom(1, 4));
EXPECT_EQ(32, blackboxCalculatePDenom(1, 8)); // 1kHz logging
EXPECT_EQ(16, blackboxCalculatePDenom(1, 16));
}
TEST(BlackboxTest, Test_CalculateRates)
{
// 1kHz PIDloop
targetPidLooptime = 1000;
blackboxConfigMutable()->p_ratio = 32;
blackboxInit();
EXPECT_EQ(32, blackboxIInterval);
EXPECT_EQ(1, blackboxPInterval);
EXPECT_EQ(1, blackboxGetRateDenom());
blackboxConfigMutable()->p_ratio = 16;
blackboxInit();
EXPECT_EQ(32, blackboxIInterval);
EXPECT_EQ(2, blackboxPInterval);
EXPECT_EQ(2, blackboxGetRateDenom());
blackboxConfigMutable()->p_ratio = 8;
blackboxInit();
EXPECT_EQ(32, blackboxIInterval);
EXPECT_EQ(4, blackboxPInterval);
EXPECT_EQ(4, blackboxGetRateDenom());
// 8kHz PIDloop
targetPidLooptime = 125;
blackboxConfigMutable()->p_ratio = 32; // 1kHz logging
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(8, blackboxPInterval);
EXPECT_EQ(8, blackboxGetRateDenom());
blackboxConfigMutable()->p_ratio = 48; // 1.5kHz logging
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(5, blackboxPInterval);
EXPECT_EQ(5, blackboxGetRateDenom());
blackboxConfigMutable()->p_ratio = 64; // 2kHz logging
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(4, blackboxPInterval);
EXPECT_EQ(4, blackboxGetRateDenom());
blackboxConfigMutable()->p_ratio = 128; // 4kHz logging
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(2, blackboxPInterval);
EXPECT_EQ(2, blackboxGetRateDenom());
blackboxConfigMutable()->p_ratio = 256; // 8kHz logging
blackboxInit();
EXPECT_EQ(256, blackboxIInterval);
EXPECT_EQ(1, blackboxPInterval);
EXPECT_EQ(1, blackboxGetRateDenom());
// 0.126 PIDloop
targetPidLooptime = 126;
blackboxConfigMutable()->p_ratio = 32; // 1kHz logging
blackboxInit();
EXPECT_EQ(253, blackboxIInterval);
EXPECT_EQ(7, blackboxPInterval);
EXPECT_EQ(7, blackboxGetRateDenom());
}
// STUBS
extern "C" {
PG_REGISTER(flight3DConfig_t, flight3DConfig, PG_MOTOR_3D_CONFIG, 0);
PG_REGISTER(mixerConfig_t, mixerConfig, PG_MIXER_CONFIG, 0);
PG_REGISTER(motorConfig_t, motorConfig, PG_MOTOR_CONFIG, 0);
PG_REGISTER(batteryConfig_t, batteryConfig, PG_BATTERY_CONFIG, 0);
PG_REGISTER(rxConfig_t, rxConfig, PG_RX_CONFIG, 0);
PG_REGISTER_ARRAY(modeActivationCondition_t, MAX_MODE_ACTIVATION_CONDITION_COUNT, modeActivationConditions, PG_MODE_ACTIVATION_PROFILE, 0);
uint8_t armingFlags;
uint8_t stateFlags;
const uint32_t baudRates[] = {0, 9600, 19200, 38400, 57600, 115200, 230400, 250000,
400000, 460800, 500000, 921600, 1000000, 1500000, 2000000, 2470000}; // see baudRate_e
uint8_t debugMode;
int32_t blackboxHeaderBudget;
gpsSolutionData_t gpsSol;
int32_t GPS_home[2];
gyro_t gyro;
float motorOutputHigh, motorOutputLow;
float motor_disarmed[MAX_SUPPORTED_MOTORS];
struct pidProfile_s;
struct pidProfile_s *currentPidProfile;
uint32_t targetPidLooptime;
boxBitmask_t rcModeActivationMask;
void mspSerialAllocatePorts(void) {}
uint32_t getArmingBeepTimeMicros(void) {return 0;}
uint16_t getBatteryVoltageLatest(void) {return 0;}
uint8_t getMotorCount(void) {return 4;}
bool areMotorsRunning(void) { return false; }
bool IS_RC_MODE_ACTIVE(boxId_e) {return false;}
bool isModeActivationConditionPresent(boxId_e) {return false;}
uint32_t millis(void) {return 0;}
bool sensors(uint32_t) {return false;}
void serialWrite(serialPort_t *, uint8_t) {}
uint32_t serialTxBytesFree(const serialPort_t *) {return 0;}
bool isSerialTransmitBufferEmpty(const serialPort_t *) {return false;}
bool featureIsEnabled(uint32_t) {return false;}
void mspSerialReleasePortIfAllocated(serialPort_t *) {}
serialPortConfig_t *findSerialPortConfig(serialPortFunction_e ) {return NULL;}
serialPort_t *findSharedSerialPort(uint16_t , serialPortFunction_e ) {return NULL;}
serialPort_t *openSerialPort(serialPortIdentifier_e, serialPortFunction_e, serialReceiveCallbackPtr, void *, uint32_t, portMode_e, portOptions_e) {return NULL;}
void closeSerialPort(serialPort_t *) {}
portSharing_e determinePortSharing(const serialPortConfig_t *, serialPortFunction_e ) {return PORTSHARING_UNUSED;}
failsafePhase_e failsafePhase(void) {return FAILSAFE_IDLE;}
bool rxAreFlightChannelsValid(void) {return false;}
bool rxIsReceivingSignal(void) {return false;}
bool isRssiConfigured(void) {return false;}
}