pimoroni-pico/drivers/servo/calibration.cpp

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#include "calibration.hpp"
namespace servo {
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Calibration::Point::Point()
: pulse(0.0f), value(0.0f) {
}
Calibration::Point::Point(float pulse, float value)
: pulse(pulse), value(value) {
}
Calibration::Calibration()
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: calibration(nullptr), calibration_size(0), limit_lower(true), limit_upper(true) {
}
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Calibration::Calibration(CalibrationType default_type)
: Calibration() {
apply_default(default_type);
}
Calibration::Calibration(const Calibration &other)
: calibration(nullptr), calibration_size(0), limit_lower(other.limit_lower), limit_upper(other.limit_upper) {
uint size = other.size();
apply_blank(size);
for(uint i = 0; i < size; i++) {
calibration[i] = other.calibration[i];
}
}
Calibration::~Calibration() {
if(calibration != nullptr) {
delete[] calibration;
calibration = nullptr;
}
}
Calibration& Calibration::operator=(const Calibration &other) {
uint size = other.size();
apply_blank(size);
for(uint i = 0; i < size; i++) {
calibration[i] = other.calibration[i];
}
limit_lower = other.limit_lower;
limit_upper = other.limit_upper;
return *this;
}
Calibration::Point& Calibration::operator[](uint8_t index) const {
return calibration[index];
}
void Calibration::apply_blank(uint size) {
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if(calibration != nullptr) {
delete[] calibration;
}
if(size > 0) {
calibration = new Point[size];
calibration_size = size;
}
else {
calibration = nullptr;
calibration_size = 0;
}
}
void Calibration::apply_two_point(float min_pulse, float max_pulse, float min_value, float max_value) {
apply_blank(2);
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calibration[0] = Point(min_pulse, min_value);
calibration[1] = Point(max_pulse, max_value);
}
void Calibration::apply_three_point(float min_pulse, float mid_pulse, float max_pulse, float min_value, float mid_value, float max_value) {
apply_blank(3);
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calibration[0] = Point(min_pulse, min_value);
calibration[1] = Point(mid_pulse, mid_value);
calibration[2] = Point(max_pulse, max_value);
}
void Calibration::apply_uniform(uint size, float min_pulse, float max_pulse, float min_value, float max_value) {
apply_blank(size);
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if(size > 0) {
float size_minus_one = (float)(size - 1);
for(uint i = 0; i < size; i++) {
float pulse = Calibration::map_float((float)i, 0.0f, size_minus_one, min_pulse, max_pulse);
float value = Calibration::map_float((float)i, 0.0f, size_minus_one, min_value, max_value);
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calibration[i] = Point(pulse, value);
}
}
}
void Calibration::apply_default(CalibrationType default_type) {
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switch(default_type) {
default:
case ANGULAR:
apply_three_point(DEFAULT_MIN_PULSE, DEFAULT_MID_PULSE, DEFAULT_MAX_PULSE,
-90.0f, 0.0f, +90.0f);
break;
case LINEAR:
apply_two_point(DEFAULT_MIN_PULSE, DEFAULT_MAX_PULSE,
0.0f, 1.0f);
break;
case CONTINUOUS:
apply_three_point(DEFAULT_MIN_PULSE, DEFAULT_MID_PULSE, DEFAULT_MAX_PULSE,
-1.0f, 0.0f, +1.0f);
break;
}
}
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uint Calibration::size() const {
return calibration_size;
}
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Calibration::Point* Calibration::point_at(uint8_t index) const {
if(index < calibration_size) {
return &calibration[index];
}
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return nullptr;
}
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Calibration::Point* Calibration::first_point() const {
if(calibration_size > 0) {
return &calibration[0];
}
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return nullptr;
}
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Calibration::Point* Calibration::last_point() const {
if(calibration_size > 0) {
return &calibration[calibration_size - 1];
}
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return nullptr;
}
bool Calibration::has_lower_limit() const {
return limit_lower;
}
bool Calibration::has_upper_limit() const {
return limit_upper;
}
void Calibration::limit_to_calibration(bool lower, bool upper) {
limit_lower = lower;
limit_upper = upper;
}
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bool Calibration::value_to_pulse(float value, float &pulse_out, float &value_out) const {
bool success = false;
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if(calibration_size >= 2) {
uint8_t last = calibration_size - 1;
value_out = value;
// Is the value below the bottom most calibration point?
if(value < calibration[0].value) {
// Should the value be limited to the calibration or projected below it?
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if(limit_lower) {
pulse_out = calibration[0].pulse;
value_out = calibration[0].value;
}
else {
pulse_out = map_float(value, calibration[0].value, calibration[1].value,
calibration[0].pulse, calibration[1].pulse);
}
}
// Is the value above the top most calibration point?
else if(value > calibration[last].value) {
// Should the value be limited to the calibration or projected above it?
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if(limit_upper) {
pulse_out = calibration[last].pulse;
value_out = calibration[last].value;
}
else {
pulse_out = map_float(value, calibration[last - 1].value, calibration[last].value,
calibration[last - 1].pulse, calibration[last].pulse);
}
}
else {
// The value must between two calibration points, so iterate through them to find which ones
for(uint8_t i = 0; i < last; i++) {
if(value <= calibration[i + 1].value) {
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pulse_out = map_float(value, calibration[i].value, calibration[i + 1].value,
calibration[i].pulse, calibration[i + 1].pulse);
break; // No need to continue checking so break out of the loop
}
}
}
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// Clamp the pulse between the hard limits
if(pulse_out < LOWER_HARD_LIMIT || pulse_out > UPPER_HARD_LIMIT) {
pulse_out = MIN(MAX(pulse_out, LOWER_HARD_LIMIT), UPPER_HARD_LIMIT);
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// Is the pulse below the bottom most calibration point?
if(pulse_out < calibration[0].pulse) {
value_out = map_float(pulse_out, calibration[0].pulse, calibration[1].pulse,
calibration[0].value, calibration[1].value);
}
// Is the pulse above the top most calibration point?
else if(pulse_out > calibration[last].pulse) {
value_out = map_float(pulse_out, calibration[last - 1].pulse, calibration[last].pulse,
calibration[last - 1].value, calibration[last].value);
}
else {
// The pulse must between two calibration points, so iterate through them to find which ones
for(uint8_t i = 0; i < last; i++) {
if(pulse_out <= calibration[i + 1].pulse) {
value_out = map_float(pulse_out, calibration[i].pulse, calibration[i + 1].pulse,
calibration[i].value, calibration[i + 1].value);
break; // No need to continue checking so break out of the loop
}
}
}
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}
success = true;
}
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return success;
}
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bool Calibration::pulse_to_value(float pulse, float &value_out, float &pulse_out) const {
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bool success = false;
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if(calibration_size >= 2) {
uint8_t last = calibration_size - 1;
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// Clamp the pulse between the hard limits
pulse_out = MIN(MAX(pulse, LOWER_HARD_LIMIT), UPPER_HARD_LIMIT);
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// Is the pulse below the bottom most calibration point?
if(pulse_out < calibration[0].pulse) {
// Should the pulse be limited to the calibration or projected below it?
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if(limit_lower) {
value_out = calibration[0].value;
pulse_out = calibration[0].pulse;
}
else {
value_out = map_float(pulse, calibration[0].pulse, calibration[1].pulse,
calibration[0].value, calibration[1].value);
}
}
// Is the pulse above the top most calibration point?
else if(pulse > calibration[last].pulse) {
// Should the pulse be limited to the calibration or projected above it?
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if(limit_upper) {
value_out = calibration[last].value;
pulse_out = calibration[last].pulse;
}
else {
value_out = map_float(pulse, calibration[last - 1].pulse, calibration[last].pulse,
calibration[last - 1].value, calibration[last].value);
}
}
else {
// The pulse must between two calibration points, so iterate through them to find which ones
for(uint8_t i = 0; i < last; i++) {
if(pulse <= calibration[i + 1].pulse) {
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value_out = map_float(pulse, calibration[i].pulse, calibration[i + 1].pulse,
calibration[i].value, calibration[i + 1].value);
break; // No need to continue checking so break out of the loop
}
}
}
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success = true;
}
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return success;
}
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float Calibration::map_float(float in, float in_min, float in_max, float out_min, float out_max) {
return (((in - in_min) * (out_max - out_min)) / (in_max - in_min)) + out_min;
}
};