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- //xyzcal.cpp - xyz calibration with image processing
- #include "Configuration_var.h"
- #ifdef NEW_XYZCAL
- #include "xyzcal.h"
- #include <avr/wdt.h>
- #include "stepper.h"
- #include "temperature.h"
- #include "sm4.h"
- #define XYZCAL_PINDA_HYST_MIN 20 //50um
- #define XYZCAL_PINDA_HYST_MAX 100 //250um
- #define XYZCAL_PINDA_HYST_DIF 5 //12.5um
- #define ENABLE_FANCHECK_INTERRUPT() EIMSK |= (1<<7)
- #define DISABLE_FANCHECK_INTERRUPT() EIMSK &= ~(1<<7)
- #define _PINDA ((READ(Z_MIN_PIN) != Z_MIN_ENDSTOP_INVERTING)?1:0)
- static const char endl[2] PROGMEM = "\n";
- #define DBG(args...) printf_P(args)
- //#define DBG(args...)
- #ifndef _n
- #define _n PSTR
- #endif //_n
- #define _X ((int16_t)count_position[X_AXIS])
- #define _Y ((int16_t)count_position[Y_AXIS])
- #define _Z ((int16_t)count_position[Z_AXIS])
- #define _E ((int16_t)count_position[E_AXIS])
- #define _X_ (count_position[X_AXIS])
- #define _Y_ (count_position[Y_AXIS])
- #define _Z_ (count_position[Z_AXIS])
- #define _E_ (count_position[E_AXIS])
- #ifndef M_PI
- const constexpr float M_PI = 3.1415926535897932384626433832795f;
- #endif
- const constexpr uint8_t X_PLUS = 0;
- const constexpr uint8_t X_MINUS = 1;
- const constexpr uint8_t Y_PLUS = 0;
- const constexpr uint8_t Y_MINUS = 1;
- const constexpr uint8_t Z_PLUS = 0;
- const constexpr uint8_t Z_MINUS = 1;
- const constexpr uint8_t X_PLUS_MASK = 0;
- const constexpr uint8_t X_MINUS_MASK = X_AXIS_MASK;
- const constexpr uint8_t Y_PLUS_MASK = 0;
- const constexpr uint8_t Y_MINUS_MASK = Y_AXIS_MASK;
- const constexpr uint8_t Z_PLUS_MASK = 0;
- const constexpr uint8_t Z_MINUS_MASK = Z_AXIS_MASK;
- /// Max. jerk in PrusaSlicer, 10000 = 1 mm/s
- const constexpr uint16_t MAX_DELAY = 10000;
- const constexpr float MIN_SPEED = 0.01f / (MAX_DELAY * 0.000001f);
- /// 200 = 50 mm/s
- const constexpr uint16_t Z_MIN_DELAY = 200;
- const constexpr uint16_t Z_ACCEL = 1000;
- /// \returns positive value always
- #define ABS(a) \
- ({ __typeof__ (a) _a = (a); \
- _a >= 0 ? _a : (-_a); })
- /// \returns maximum of the two
- #define MAX(a, b) \
- ({ __typeof__ (a) _a = (a); \
- __typeof__ (b) _b = (b); \
- _a >= _b ? _a : _b; })
- /// \returns minimum of the two
- #define MIN(a, b) \
- ({ __typeof__ (a) _a = (a); \
- __typeof__ (b) _b = (b); \
- _a <= _b ? _a : _b; })
- /// swap values
- #define SWAP(a, b) \
- ({ __typeof__ (a) c = (a); \
- a = (b); \
- b = c; })
- /// Saturates value
- /// \returns min if value is less than min
- /// \returns max if value is more than min
- /// \returns value otherwise
- #define CLAMP(value, min, max) \
- ({ __typeof__ (value) a_ = (value); \
- __typeof__ (min) min_ = (min); \
- __typeof__ (max) max_ = (max); \
- ( a_ < min_ ? min_ : (a_ <= max_ ? a_ : max_)); })
- /// \returns square of the value
- #define SQR(a) \
- ({ __typeof__ (a) a_ = (a); \
- (a_ * a_); })
- /// position types
- typedef int16_t pos_i16_t;
- typedef long pos_i32_t;
- typedef float pos_mm_t;
- typedef int16_t usteps_t;
- uint8_t check_pinda_0();
- uint8_t check_pinda_1();
- void xyzcal_update_pos(uint16_t dx, uint16_t dy, uint16_t dz, uint16_t de);
- uint16_t xyzcal_calc_delay(uint16_t nd, uint16_t dd);
- uint8_t round_to_u8(float f){
- return (uint8_t)(f + .5f);
- }
- uint16_t round_to_u16(float f){
- return (uint16_t)(f + .5f);
- }
- int16_t round_to_i16(float f){
- return (int16_t)(f + .5f);
- }
- /// converts millimeters to integer position
- pos_i16_t mm_2_pos(pos_mm_t mm){
- return (pos_i16_t)(0.5f + mm * 100);
- }
- /// converts integer position to millimeters
- pos_mm_t pos_2_mm(pos_i16_t pos){
- return pos * 0.01f;
- }
- pos_mm_t pos_2_mm(float pos){
- return pos * 0.01f;
- }
- void xyzcal_meassure_enter(void)
- {
- DBG(_n("xyzcal_meassure_enter\n"));
- // disable heaters and stop motion before we initialize sm4
- disable_heater();
- st_synchronize();
- // disable incompatible interrupts
- DISABLE_STEPPER_DRIVER_INTERRUPT();
- #ifdef WATCHDOG
- wdt_disable();
- #endif //WATCHDOG
- // setup internal callbacks
- sm4_stop_cb = 0;
- sm4_update_pos_cb = xyzcal_update_pos;
- sm4_calc_delay_cb = xyzcal_calc_delay;
- }
- void xyzcal_meassure_leave(void)
- {
- DBG(_n("xyzcal_meassure_leave\n"));
- // resync planner position from counters (changed by xyzcal_update_pos)
- planner_reset_position();
- // re-enable interrupts
- #ifdef WATCHDOG
- wdt_enable(WDTO_4S);
- #ifdef EMERGENCY_HANDLERS
- WDTCSR |= (1 << WDIE);
- #endif //EMERGENCY_HANDLERS
- #endif //WATCHDOG
- ENABLE_STEPPER_DRIVER_INTERRUPT();
- }
- uint8_t check_pinda_0()
- {
- return _PINDA?0:1;
- }
- uint8_t check_pinda_1()
- {
- return _PINDA?1:0;
- }
- uint8_t xyzcal_dm = 0;
- void xyzcal_update_pos(uint16_t dx, uint16_t dy, uint16_t dz, uint16_t)
- {
- // DBG(_n("xyzcal_update_pos dx=%d dy=%d dz=%d dir=%02x\n"), dx, dy, dz, xyzcal_dm);
- if (xyzcal_dm&1) count_position[0] -= dx; else count_position[0] += dx;
- if (xyzcal_dm&2) count_position[1] -= dy; else count_position[1] += dy;
- if (xyzcal_dm&4) count_position[2] -= dz; else count_position[2] += dz;
- // DBG(_n(" after xyzcal_update_pos x=%ld y=%ld z=%ld\n"), count_position[0], count_position[1], count_position[2]);
- }
- uint16_t xyzcal_sm4_delay = 0;
- //#define SM4_ACCEL_TEST
- #ifdef SM4_ACCEL_TEST
- uint16_t xyzcal_sm4_v0 = 2000;
- uint16_t xyzcal_sm4_vm = 45000;
- uint16_t xyzcal_sm4_v = xyzcal_sm4_v0;
- uint16_t xyzcal_sm4_ac = 2000;
- uint16_t xyzcal_sm4_ac2 = (uint32_t)xyzcal_sm4_ac * 1024 / 10000;
- //float xyzcal_sm4_vm = 10000;
- #endif //SM4_ACCEL_TEST
- #ifdef SM4_ACCEL_TEST
- uint16_t xyzcal_calc_delay(uint16_t nd, uint16_t dd)
- {
- uint16_t del_us = 0;
- if (xyzcal_sm4_v & 0xf000) //>=4096
- {
- del_us = (uint16_t)62500 / (uint16_t)(xyzcal_sm4_v >> 4);
- xyzcal_sm4_v += (xyzcal_sm4_ac2 * del_us + 512) >> 10;
- if (xyzcal_sm4_v > xyzcal_sm4_vm) xyzcal_sm4_v = xyzcal_sm4_vm;
- if (del_us > 25) return del_us - 25;
- }
- else
- {
- del_us = (uint32_t)1000000 / xyzcal_sm4_v;
- xyzcal_sm4_v += ((uint32_t)xyzcal_sm4_ac2 * del_us + 512) >> 10;
- if (xyzcal_sm4_v > xyzcal_sm4_vm) xyzcal_sm4_v = xyzcal_sm4_vm;
- if (del_us > 50) return del_us - 50;
- }
- // uint16_t del_us = (uint16_t)(((float)1000000 / xyzcal_sm4_v) + 0.5);
- // uint16_t del_us = (uint32_t)1000000 / xyzcal_sm4_v;
- // uint16_t del_us = 100;
- // uint16_t del_us = (uint16_t)10000 / xyzcal_sm4_v;
- // v += (ac * del_us + 500) / 1000;
- // xyzcal_sm4_v += (xyzcal_sm4_ac * del_us) / 1000;
- // return xyzcal_sm4_delay;
- // DBG(_n("xyzcal_calc_delay nd=%d dd=%d v=%d del_us=%d\n"), nd, dd, xyzcal_sm4_v, del_us);
- return 0;
- }
- #else //SM4_ACCEL_TEST
- uint16_t xyzcal_calc_delay(uint16_t, uint16_t)
- {
- return xyzcal_sm4_delay;
- }
- #endif //SM4_ACCEL_TEST
- /// Moves printer to absolute position [x,y,z] defined in integer position system
- /// check_pinda == 0: ordinary move
- /// check_pinda == 1: stop when PINDA triggered
- /// check_pinda == -1: stop when PINDA untriggered
- bool xyzcal_lineXYZ_to(int16_t x, int16_t y, int16_t z, uint16_t delay_us, int8_t check_pinda)
- {
- // DBG(_n("xyzcal_lineXYZ_to x=%d y=%d z=%d check=%d\n"), x, y, z, check_pinda);
- x -= (int16_t)count_position[0];
- y -= (int16_t)count_position[1];
- z -= (int16_t)count_position[2];
- xyzcal_dm = ((x<0)?1:0) | ((y<0)?2:0) | ((z<0)?4:0);
- sm4_set_dir_bits(xyzcal_dm);
- sm4_stop_cb = check_pinda?((check_pinda<0)?check_pinda_0:check_pinda_1):0;
- xyzcal_sm4_delay = delay_us;
- // uint32_t u = _micros();
- bool ret = sm4_line_xyz_ui(abs(x), abs(y), abs(z)) ? true : false;
- // u = _micros() - u;
- return ret;
- }
- /// Moves printer to absolute position [x,y,z] defined in millimeters
- bool xyzcal_lineXYZ_to_float(pos_mm_t x, pos_mm_t y, pos_mm_t z, uint16_t delay_us, int8_t check_pinda){
- return xyzcal_lineXYZ_to(mm_2_pos(x), mm_2_pos(y), mm_2_pos(z), delay_us, check_pinda);
- }
- bool xyzcal_spiral2(int16_t cx, int16_t cy, int16_t z0, int16_t dz, int16_t radius, int16_t rotation, uint16_t delay_us, int8_t check_pinda, uint16_t* pad)
- {
- bool ret = false;
- float r = 0; //radius
- uint16_t ad = 0; //angle [deg]
- float ar; //angle [rad]
- uint8_t dad = 0; //delta angle [deg]
- uint8_t dad_min = 4; //delta angle min [deg]
- uint8_t dad_max = 16; //delta angle max [deg]
- uint8_t k = 720 / (dad_max - dad_min); //delta calculation constant
- ad = 0;
- if (pad) ad = *pad % 720;
-
- //@size=214
- DBG(_n("xyzcal_spiral2 cx=%d cy=%d z0=%d dz=%d radius=%d ad=%d\n"), cx, cy, z0, dz, radius, ad);
- // lcd_set_cursor(0, 4);
- // char text[10];
- // snprintf(text, 10, "%4d", z0);
- // lcd_print(text);
- for (; ad < 720; ad++)
- {
- if (radius > 0)
- {
- dad = dad_max - (ad / k);
- r = (float)(((uint32_t)ad) * radius) / 720;
- }
- else
- {
- dad = dad_max - ((719 - ad) / k);
- r = (float)(((uint32_t)(719 - ad)) * (-radius)) / 720;
- }
- ar = radians(ad + rotation);
- int x = (int)(cx + (cos(ar) * r));
- int y = (int)(cy + (sin(ar) * r));
- int z = (int)(z0 - ((float)((int32_t)dz * ad) / 720));
- if (xyzcal_lineXYZ_to(x, y, z, delay_us, check_pinda))
- {
- ad += dad + 1;
- ret = true;
- break;
- }
- ad += dad;
- }
- if (pad) *pad = ad;
- // if(ret){
- // lcd_set_cursor(0, 4);
- // lcd_print(" ");
- // }
- return ret;
- }
- bool xyzcal_spiral8(int16_t cx, int16_t cy, int16_t z0, int16_t dz, int16_t radius, uint16_t delay_us, int8_t check_pinda, uint16_t* pad)
- {
- bool ret = false;
- uint16_t ad = 0;
- if (pad) ad = *pad;
- //@size=274
- DBG(_n("xyzcal_spiral8 cx=%d cy=%d z0=%d dz=%d radius=%d ad=%d\n"), cx, cy, z0, dz, radius, ad);
- if (!ret && (ad < 720))
- if ((ret = xyzcal_spiral2(cx, cy, z0 - 0*dz, dz, radius, 0, delay_us, check_pinda, &ad)) != 0)
- ad += 0;
- if (!ret && (ad < 1440))
- if ((ret = xyzcal_spiral2(cx, cy, z0 - 1*dz, dz, -radius, 0, delay_us, check_pinda, &ad)) != 0)
- ad += 720;
- if (!ret && (ad < 2160))
- if ((ret = xyzcal_spiral2(cx, cy, z0 - 2*dz, dz, radius, 180, delay_us, check_pinda, &ad)) != 0)
- ad += 1440;
- if (!ret && (ad < 2880))
- if ((ret = xyzcal_spiral2(cx, cy, z0 - 3*dz, dz, -radius, 180, delay_us, check_pinda, &ad)) != 0)
- ad += 2160;
- if (pad) *pad = ad;
- return ret;
- }
- #ifdef XYZCAL_MEASSURE_PINDA_HYSTEREZIS
- int8_t xyzcal_meassure_pinda_hysterezis(int16_t min_z, int16_t max_z, uint16_t delay_us, uint8_t samples)
- {
- DBG(_n("xyzcal_meassure_pinda_hysterezis\n"));
- int8_t ret = -1; // PINDA signal error
- int16_t z = _Z;
- int16_t sum_up = 0;
- int16_t sum_dn = 0;
- int16_t up;
- int16_t dn;
- uint8_t sample;
- xyzcal_lineXYZ_to(_X, _Y, min_z, delay_us, 1);
- xyzcal_lineXYZ_to(_X, _Y, max_z, delay_us, -1);
- if (!_PINDA)
- {
- for (sample = 0; sample < samples; sample++)
- {
- dn = _Z;
- if (!xyzcal_lineXYZ_to(_X, _Y, min_z, delay_us, 1)) break;
- dn = dn - _Z;
- up = _Z;
- if (!xyzcal_lineXYZ_to(_X, _Y, max_z, delay_us, -1)) break;
- up = _Z - up;
- DBG(_n("%d. up=%d dn=%d\n"), sample, up, dn);
- sum_up += up;
- sum_dn += dn;
- if (abs(up - dn) > XYZCAL_PINDA_HYST_DIF)
- {
- ret = -2; // difference between up-dn to high
- break;
- }
- }
- if (sample == samples)
- {
- up = sum_up / samples;
- dn = sum_dn / samples;
- uint16_t hyst = (up + dn) / 2;
- if (abs(up - dn) > XYZCAL_PINDA_HYST_DIF)
- ret = -2; // difference between up-dn to high
- else if ((hyst < XYZCAL_PINDA_HYST_MIN) || (hyst > XYZCAL_PINDA_HYST_MAX))
- ret = -3; // hysterezis out of range
- else
- ret = hyst;
- }
- }
- xyzcal_lineXYZ_to(_X, _Y, z, delay_us, 0);
- return ret;
- }
- #endif //XYZCAL_MEASSURE_PINDA_HYSTEREZIS
- void print_hysteresis(int16_t min_z, int16_t max_z, int16_t step){
- int16_t delay_us = 600;
- int16_t trigger = 0;
- int16_t untrigger = 0;
- DBG(_n("Hysteresis\n"));
- xyzcal_lineXYZ_to(_X, _Y, min_z, delay_us, 0);
- for (int16_t z = min_z; z <= max_z; z += step){
- xyzcal_lineXYZ_to(_X, _Y, z, delay_us, -1);
- untrigger = _Z;
- xyzcal_lineXYZ_to(_X, _Y, z, delay_us, 0);
- xyzcal_lineXYZ_to(_X, _Y, min_z, delay_us, 1);
- trigger = _Z;
- //xyzcal_lineXYZ_to(_X, _Y, min_z, delay_us, 0);
- //@size=114
- DBG(_n("min, trigger, untrigger, max: [%d %d %d %d]\n"), _Z, trigger, untrigger, z);
- }
- }
- void update_position_1_step(uint8_t axis, uint8_t dir){
- if (axis & X_AXIS_MASK)
- _X_ += dir & X_AXIS_MASK ? -1 : 1;
- if (axis & Y_AXIS_MASK)
- _Y_ += dir & Y_AXIS_MASK ? -1 : 1;
- if (axis & Z_AXIS_MASK)
- _Z_ += dir & Z_AXIS_MASK ? -1 : 1;
- }
- void set_axes_dir(uint8_t axes, uint8_t dir){
- if (axes & X_AXIS_MASK)
- sm4_set_dir(X_AXIS, dir & X_AXIS_MASK);
- if (axes & Y_AXIS_MASK)
- sm4_set_dir(Y_AXIS, dir & Y_AXIS_MASK);
- if (axes & Z_AXIS_MASK)
- sm4_set_dir(Z_AXIS, dir & Z_AXIS_MASK);
- }
- /// Accelerate up to max.speed (defined by @min_delay_us)
- /// does not update global positions
- void accelerate_1_step(uint8_t axes, int16_t acc, uint16_t &delay_us, uint16_t min_delay_us){
- sm4_do_step(axes);
- /// keep max speed (avoid extra computation)
- if (acc > 0 && delay_us == min_delay_us){
- delayMicroseconds(delay_us);
- return;
- }
- // v1 = v0 + a * t
- // 0.01 = length of a step
- const float t0 = delay_us * 0.000001f;
- const float v1 = (0.01f / t0 + acc * t0);
- uint16_t t1;
- if (v1 <= 0.16f){ ///< slowest speed convertible to uint16_t delay
- t1 = MAX_DELAY; ///< already too slow so it wants to move back
- } else {
- /// don't exceed max.speed
- t1 = MAX(min_delay_us, round_to_u16(0.01f / v1 * 1000000.f));
- }
- /// make sure delay has changed a bit at least
- if (t1 == delay_us && acc != 0){
- if (acc > 0)
- t1--;
- else
- t1++;
- }
-
- //DBG(_n("%d "), t1);
- delayMicroseconds(t1);
- delay_us = t1;
- }
- /// Goes defined number of steps while accelerating
- /// updates global positions
- void accelerate(uint8_t axes, uint8_t dir, int16_t acc, uint16_t &delay_us, uint16_t min_delay_us, uint16_t steps){
- set_axes_dir(axes, dir);
- while (steps--){
- accelerate_1_step(axes, acc, delay_us, min_delay_us);
- update_position_1_step(axes, dir);
- }
- }
- /// keeps speed and then it decelerates to a complete stop (if possible)
- /// it goes defined number of steps
- /// returns after each step
- /// \returns true if step was done
- /// does not update global positions
- bool go_and_stop_1_step(uint8_t axes, int16_t dec, uint16_t &delay_us, uint16_t &steps){
- if (steps <= 0 || dec <= 0)
- return false;
- /// deceleration distance in steps, s = 1/2 v^2 / a
- uint16_t s = round_to_u16(100 * 0.5f * SQR(0.01f) / (SQR((float)delay_us) * dec));
- if (steps > s){
- /// go steady
- sm4_do_step(axes);
- delayMicroseconds(delay_us);
- } else {
- /// decelerate
- accelerate_1_step(axes, -dec, delay_us, delay_us);
- }
- --steps;
- return true;
- }
- /// \param dir sets direction of movement
- /// updates global positions
- void go_and_stop(uint8_t axes, uint8_t dir, int16_t dec, uint16_t &delay_us, uint16_t steps){
- set_axes_dir(axes, dir);
- while (go_and_stop_1_step(axes, dec, delay_us, steps)){
- update_position_1_step(axes, dir);
- }
- }
- /// goes all the way to stop
- /// \returns steps done
- /// updates global positions
- void stop_smoothly(uint8_t axes, uint8_t dir, int16_t dec, uint16_t &delay_us){
- if (dec <= 0)
- return;
- set_axes_dir(axes, dir);
- while (delay_us < MAX_DELAY){
- accelerate_1_step(axes, -dec, delay_us, delay_us);
- update_position_1_step(axes, dir);
- }
- }
- void go_start_stop(uint8_t axes, uint8_t dir, int16_t acc, uint16_t min_delay_us, uint16_t steps){
- if (steps == 0)
- return;
- uint16_t current_delay_us = MAX_DELAY;
- const uint16_t half = steps / 2;
- accelerate(axes, dir, acc, current_delay_us, min_delay_us, half);
- go_and_stop(axes, dir, -acc, current_delay_us, steps - half);
- }
- /// moves X, Y, Z one after each other
- /// starts and ends at 0 speed
- void go_manhattan(int16_t x, int16_t y, int16_t z, int16_t acc, uint16_t min_delay_us){
- int32_t length;
- // DBG(_n("x %d -> %d, "), x, _X);
- length = x - _X;
- go_start_stop(X_AXIS_MASK, length < 0 ? X_MINUS_MASK : X_PLUS_MASK, acc, min_delay_us, ABS(length));
- // DBG(_n("y %d -> %d, "), y, _Y);
- length = y - _Y;
- go_start_stop(Y_AXIS_MASK, length < 0 ? Y_MINUS_MASK : Y_PLUS_MASK, acc, min_delay_us, ABS(length));
- // DBG(_n("z %d -> %d\n"), z, _Z);
- length = z - _Z;
- go_start_stop(Z_AXIS_MASK, length < 0 ? Z_MINUS_MASK : Z_PLUS_MASK, acc, min_delay_us, ABS(length));
- // DBG(_n("\n"));
- }
- void __attribute__((noinline)) xyzcal_scan_pixels_32x32_Zhop(int16_t cx, int16_t cy, int16_t min_z, int16_t max_z, uint16_t delay_us, uint8_t *pixels){
- if (!pixels)
- return;
- int16_t z_trig;
- uint16_t line_buffer[32];
- uint16_t current_delay_us = MAX_DELAY; ///< defines current speed
- int16_t start_z;
- uint16_t steps_to_go;
- DBG(_n("Scan countdown: "));
- for (uint8_t r = 0; r < 32; r++){ ///< Y axis
- for (uint8_t d = 0; d < 2; ++d){
- go_manhattan((d & 1) ? (cx + 992) : (cx - 992), cy - 992 + r * 64, _Z, Z_ACCEL, Z_MIN_DELAY);
- xyzcal_lineXYZ_to((d & 1) ? (cx + 992) : (cx - 992), cy - 992 + r * 64, _Z, delay_us, 0);
- sm4_set_dir(X_AXIS, d);
- //@size=242
- DBG(_n("%d\n"), 64 - (r * 2 + d)); ///< to keep OctoPrint connection alive
- for (uint8_t c = 0; c < 32; c++){ ///< X axis
- /// move to the next point and move Z up diagonally (if needed)
- current_delay_us = MAX_DELAY;
- const int16_t end_x = ((d & 1) ? 1 : -1) * (64 * (16 - c) - 32) + cx;
- const int16_t length_x = ABS(end_x - _X);
- const int16_t half_x = length_x / 2;
- /// don't go up if PINDA not triggered (optimization)
- const bool up = _PINDA;
- const uint8_t axes = up ? X_AXIS_MASK | Z_AXIS_MASK : X_AXIS_MASK;
- const uint8_t dir = Z_PLUS_MASK | (d & 1 ? X_MINUS_MASK : X_PLUS_MASK);
- accelerate(axes, dir, Z_ACCEL, current_delay_us, Z_MIN_DELAY, half_x);
- go_and_stop(axes, dir, Z_ACCEL, current_delay_us, length_x - half_x);
-
-
- z_trig = min_z;
- /// move up to un-trigger (surpress hysteresis)
- sm4_set_dir(Z_AXIS, Z_PLUS);
- /// speed up from stop, go half the way
- current_delay_us = MAX_DELAY;
- for (start_z = _Z; _Z < (max_z + start_z) / 2; ++_Z_){
- if (!_PINDA){
- break;
- }
- accelerate_1_step(Z_AXIS_MASK, Z_ACCEL, current_delay_us, Z_MIN_DELAY);
- }
- if (_PINDA){
- steps_to_go = MAX(0, max_z - _Z);
- while (_PINDA && _Z < max_z){
- go_and_stop_1_step(Z_AXIS_MASK, Z_ACCEL, current_delay_us, steps_to_go);
- ++_Z_;
- }
- }
- stop_smoothly(Z_AXIS_MASK, Z_PLUS_MASK, Z_ACCEL, current_delay_us);
- /// move down to trigger
- sm4_set_dir(Z_AXIS, Z_MINUS);
- /// speed up
- current_delay_us = MAX_DELAY;
- for (start_z = _Z; _Z > (min_z + start_z) / 2; --_Z_){
- if (_PINDA){
- z_trig = _Z;
- break;
- }
- accelerate_1_step(Z_AXIS_MASK, Z_ACCEL, current_delay_us, Z_MIN_DELAY);
- }
- /// slow down
- if (!_PINDA){
- steps_to_go = MAX(0, _Z - min_z);
- while (!_PINDA && _Z > min_z){
- go_and_stop_1_step(Z_AXIS_MASK, Z_ACCEL, current_delay_us, steps_to_go);
- --_Z_;
- }
- z_trig = _Z;
- }
- /// slow down to stop but not lower than min_z
- while (_Z > min_z && current_delay_us < MAX_DELAY){
- accelerate_1_step(Z_AXIS_MASK, -Z_ACCEL, current_delay_us, Z_MIN_DELAY);
- --_Z_;
- }
- if (d == 0){
- line_buffer[c] = (uint16_t)(z_trig - min_z);
- } else {
- /// !!! data reversed in X
- // DBG(_n("%04x"), ((uint32_t)line_buffer[31 - c] + (z_trig - min_z)) / 2);
- /// save average of both directions (filters effect of hysteresis)
- pixels[(uint16_t)r * 32 + (31 - c)] = (uint8_t)MIN((uint32_t)255, ((uint32_t)line_buffer[31 - c] + (z_trig - min_z)) / 2);
- }
- }
- }
- }
- DBG(endl);
- }
- /// Returns rate of match
- /// max match = 132, min match = 0
- uint8_t xyzcal_match_pattern_12x12_in_32x32(uint16_t* pattern, uint8_t* pixels, uint8_t c, uint8_t r){
- uint8_t thr = 16;
- uint8_t match = 0;
- for (uint8_t i = 0; i < 12; ++i){
- for (uint8_t j = 0; j < 12; ++j){
- /// skip corners (3 pixels in each)
- if (((i == 0) || (i == 11)) && ((j < 2) || (j >= 10))) continue;
- if (((j == 0) || (j == 11)) && ((i < 2) || (i >= 10))) continue;
- const uint16_t idx = (c + j) + 32 * ((uint16_t)r + i);
- const bool high_pix = pixels[idx] > thr;
- const bool high_pat = pattern[i] & (1 << j);
- if (high_pix == high_pat)
- match++;
- }
- }
- return match;
- }
- /// Searches for best match of pattern by shifting it
- /// Returns rate of match and the best location
- /// max match = 132, min match = 0
- uint8_t xyzcal_find_pattern_12x12_in_32x32(uint8_t* pixels, uint16_t* pattern, uint8_t* pc, uint8_t* pr){
- if (!pixels || !pattern || !pc || !pr)
- return -1;
- uint8_t max_c = 0;
- uint8_t max_r = 0;
- uint8_t max_match = 0;
- // DBG(_n("Matching:\n"));
- /// pixel precision
- for (uint8_t r = 0; r < (32 - 12); ++r){
- for (uint8_t c = 0; c < (32 - 12); ++c){
- const uint8_t match = xyzcal_match_pattern_12x12_in_32x32(pattern, pixels, c, r);
- if (max_match < match){
- max_c = c;
- max_r = r;
- max_match = match;
- }
- // DBG(_n("%d "), match);
- }
- // DBG(_n("\n"));
- }
- //@size=278
- DBG(_n("Pattern center [%f %f], match %f%%\n"), max_c + 5.5f, max_r + 5.5f, max_match / 1.32f);
- *pc = max_c;
- *pr = max_r;
- return max_match;
- }
- const uint16_t xyzcal_point_pattern_10[12] PROGMEM = {0x000, 0x0f0, 0x1f8, 0x3fc, 0x7fe, 0x7fe, 0x7fe, 0x7fe, 0x3fc, 0x1f8, 0x0f0, 0x000};
- const uint16_t xyzcal_point_pattern_08[12] PROGMEM = {0x000, 0x000, 0x0f0, 0x1f8, 0x3fc, 0x3fc, 0x3fc, 0x3fc, 0x1f8, 0x0f0, 0x000, 0x000};
- bool xyzcal_searchZ(void) {
- //@size=118
- DBG(_n("xyzcal_searchZ x=%ld y=%ld z=%ld\n"), count_position[X_AXIS], count_position[Y_AXIS], count_position[Z_AXIS]);
- int16_t x0 = _X;
- int16_t y0 = _Y;
- int16_t z = _Z;
- // int16_t min_z = -6000;
- // int16_t dz = 100;
- while (z > -2300) { //-6mm + 0.25mm
- uint16_t ad = 0;
- if (xyzcal_spiral8(x0, y0, z, 100, 900, 320, 1, &ad)) { //dz=100 radius=900 delay=400
- //@size=82
- DBG(_n(" ON-SIGNAL at x=%d y=%d z=%d ad=%d\n"), _X, _Y, _Z, ad);
- /// return to starting XY position
- /// magic constant, lowers min_z after searchZ to obtain more dense data in scan
- const pos_i16_t lower_z = 72;
- xyzcal_lineXYZ_to(x0, y0, _Z - lower_z, 200, 0);
- return true;
- }
- z -= 400;
- }
- //@size=138
- DBG(_n("xyzcal_searchZ no signal\n x=%ld y=%ld z=%ld\n"), count_position[X_AXIS], count_position[Y_AXIS], count_position[Z_AXIS]);
- return false;
- }
- /// returns value of any location within data
- /// uses bilinear interpolation
- float get_value(uint8_t * matrix_32x32, float c, float r){
- if (c <= 0 || r <= 0 || c >= 31 || r >= 31)
- return 0;
- /// calculate weights of nearby points
- const float wc1 = c - floor(c);
- const float wr1 = r - floor(r);
- const float wc0 = 1 - wc1;
- const float wr0 = 1 - wr1;
- const float w00 = wc0 * wr0;
- const float w01 = wc0 * wr1;
- const float w10 = wc1 * wr0;
- const float w11 = wc1 * wr1;
- const uint16_t c0 = c;
- const uint16_t c1 = c0 + 1;
- const uint16_t r0 = r;
- const uint16_t r1 = r0 + 1;
- const uint16_t idx00 = c0 + 32 * r0;
- const uint16_t idx01 = c0 + 32 * r1;
- const uint16_t idx10 = c1 + 32 * r0;
- const uint16_t idx11 = c1 + 32 * r1;
- /// bilinear resampling
- return w00 * matrix_32x32[idx00] + w01 * matrix_32x32[idx01] + w10 * matrix_32x32[idx10] + w11 * matrix_32x32[idx11];
- }
- const constexpr float m_infinity = -1000.f;
- /// replaces the highest number by m_infinity
- void remove_highest(float *points, const uint8_t num_points){
- if (num_points <= 0)
- return;
- float max = points[0];
- uint8_t max_i = 0;
- for (uint8_t i = 0; i < num_points; ++i){
- if (max < points[i]){
- max = points[i];
- max_i = i;
- }
- }
- points[max_i] = m_infinity;
- }
- /// return the highest number in the list
- float highest(float *points, const uint8_t num_points){
- if (num_points <= 0)
- return 0;
- float max = points[0];
- for (uint8_t i = 0; i < num_points; ++i){
- if (max < points[i]){
- max = points[i];
- }
- }
- return max;
- }
- /// slow bubble sort but short
- void sort(float *points, const uint8_t num_points){
- /// one direction bubble sort
- for (uint8_t i = 0; i < num_points; ++i){
- for (uint8_t j = 0; j < num_points - i - 1; ++j){
- if (points[j] > points[j + 1])
- SWAP(points[j], points[j + 1]);
- }
- }
-
- // DBG(_n("Sorted: "));
- // for (uint8_t i = 0; i < num_points; ++i)
- // DBG(_n("%f "), points[i]);
- // DBG(_n("\n"));
- }
- /// sort array and returns median value
- /// don't send empty array or nullptr
- float median(float *points, const uint8_t num_points){
- sort(points, num_points);
- return points[num_points / 2];
- }
- float __attribute__ ((noinline)) CLAMP_median(float *shifts, uint8_t blocks, float norm){
- const constexpr float max_change = 0.5f; ///< avoids too fast changes (avoid oscillation)
- return CLAMP( median(shifts, blocks) * norm, -max_change, max_change);
- }
- /// Searches for circle iteratively
- /// Uses points on the perimeter. If point is high it pushes circle out of the center (shift or change of radius),
- /// otherwise to the center.
- /// Algorithm is stopped after fixed number of iterations. Move is limited to 0.5 px per iteration.
- void dynamic_circle(uint8_t *matrix_32x32, float &x, float &y, float &r, uint8_t iterations){
- /// circle of 10.5 diameter has 33 in circumference, don't go much above
- const constexpr uint8_t num_points = 33;
- const float pi_2_div_num_points = 2 * M_PI / num_points;
- const constexpr uint8_t target_z = 32; ///< target z height of the circle
- const uint8_t blocks = num_points;
- float shifts_x[blocks];
- float shifts_y[blocks];
- float shifts_r[blocks];
- // DBG(_n(" [%f, %f][%f] start circle\n"), x, y, r);
- for (int8_t i = iterations; i > 0; --i){
-
- //@size=128B
- // DBG(_n(" [%f, %f][%f] circle\n"), x, y, r);
- /// read points on the circle
- for (uint8_t p = 0; p < num_points; ++p){
- const float angle = p * pi_2_div_num_points;
- const float height = get_value(matrix_32x32, r * cos(angle) + x, r * sin(angle) + y) - target_z;
- // DBG(_n("%f "), point);
- shifts_x[p] = cos(angle) * height;
- shifts_y[p] = sin(angle) * height;
- shifts_r[p] = height;
- }
- // DBG(_n(" points\n"));
- const float reducer = 32.f; ///< reduces speed of convergency to avoid oscillation
- const float norm = 1.f / reducer;
- // x += CLAMP(median(shifts_x, blocks) * norm, -max_change, max_change);
- // y += CLAMP(median(shifts_y, blocks) * norm, -max_change, max_change);
- // r += CLAMP(median(shifts_r, blocks) * norm * .5f, -max_change, max_change);
- //104B down
- x += CLAMP_median(shifts_x, blocks, norm);
- y += CLAMP_median(shifts_y, blocks, norm);
- r += CLAMP_median(shifts_r, blocks, norm * .5f);
- r = MAX(2, r);
- }
- //@size=118
- DBG(_n(" [%f, %f][%f] final circle\n"), x, y, r);
- }
- /// Prints matrix in hex to debug output (serial line)
- void print_image(const uint8_t *matrix_32x32){
- for (uint8_t y = 0; y < 32; ++y){
- const uint16_t idx_y = y * 32;
- for (uint8_t x = 0; x < 32; ++x){
- DBG(_n("%02x"), matrix_32x32[idx_y + x]);
- }
- DBG(endl);
- }
- DBG(endl);
- }
- /// Takes two patterns and searches them in matrix32
- /// \returns best match
- uint8_t find_patterns(uint8_t *matrix32, uint16_t *pattern08, uint16_t *pattern10, uint8_t &col, uint8_t &row){
- uint8_t c08 = 0;
- uint8_t r08 = 0;
- uint8_t match08 = 0;
- uint8_t c10 = 0;
- uint8_t r10 = 0;
- uint8_t match10 = 0;
- match08 = xyzcal_find_pattern_12x12_in_32x32(matrix32, pattern08, &c08, &r08);
- match10 = xyzcal_find_pattern_12x12_in_32x32(matrix32, pattern10, &c10, &r10);
- if (match08 > match10){
- col = c08;
- row = r08;
- return match08;
- }
-
- col = c10;
- row = r10;
- return match10;
- }
- /// Scan should include normal data.
- /// If it's too extreme (00, FF) it could be caused by biased sensor.
- /// \return true if data looks normal
- bool check_scan(uint8_t *matrix32){
- /// magic constants that define normality
- const int16_t threshold_total = 900;
- const int threshold_extreme = 50;
- int16_t mins = 0;
- int16_t maxs = 0;
- for (int16_t i = 0; i < 32*32;++i){
- if (matrix32[i] == 0) {
- ++mins;
- } else if (matrix32[i] == 0xFF){
- ++maxs;
- }
- }
- const int16_t rest = 1024 - mins - maxs;
- if (mins + maxs > threshold_total
- && mins > threshold_extreme
- && maxs > threshold_extreme
- && mins > rest
- && maxs > rest)
- return false;
- return true;
- }
- /// scans area around the current head location and
- /// searches for the center of the calibration pin
- BedSkewOffsetDetectionResultType xyzcal_scan_and_process(){
- //@size=44
- // DBG(_n("sizeof(block_buffer)=%d\n"), sizeof(block_t)*BLOCK_BUFFER_SIZE);
- BedSkewOffsetDetectionResultType ret = BED_SKEW_OFFSET_DETECTION_POINT_NOT_FOUND;
- int16_t x = _X;
- int16_t y = _Y;
- const int16_t z = _Z;
- uint8_t *matrix32 = (uint8_t *)block_buffer;
- uint16_t *pattern08 = (uint16_t *)(matrix32 + 32 * 32);
- uint16_t *pattern10 = (uint16_t *)(pattern08 + 12);
- for (uint8_t i = 0; i < 12; i++){
- pattern08[i] = pgm_read_word((uint16_t*)(xyzcal_point_pattern_08 + i));
- pattern10[i] = pgm_read_word((uint16_t*)(xyzcal_point_pattern_10 + i));
- }
- xyzcal_scan_pixels_32x32_Zhop(x, y, z, 2400, 200, matrix32);
- print_image(matrix32);
- if (!check_scan(matrix32))
- return BED_SKEW_OFFSET_DETECTION_POINT_SCAN_FAILED;
- /// SEARCH FOR BINARY CIRCLE
- uint8_t uc = 0;
- uint8_t ur = 0;
- /// max match = 132, 1/2 good = 66, 2/3 good = 88
- if (find_patterns(matrix32, pattern08, pattern10, uc, ur) >= 88){
- /// find precise circle
- /// move to the center of the pattern (+5.5)
- float xf = uc + 5.5f;
- float yf = ur + 5.5f;
- float radius = 4.5f; ///< default radius
- constexpr const uint8_t iterations = 20;
- dynamic_circle(matrix32, xf, yf, radius, iterations);
- if (fabs(xf - (uc + 5.5f)) > 3 || fabs(yf - (ur + 5.5f)) > 3 || fabs(radius - 5) > 3){
- //@size=88
- DBG(_n(" [%f %f][%f] mm divergence\n"), xf - (uc + 5.5f), yf - (ur + 5.5f), radius - 5);
- /// dynamic algorithm diverged, use original position instead
- xf = uc + 5.5f;
- yf = ur + 5.5f;
- }
- /// move to the center of area and convert to position
- xf = (float)x + (xf - 15.5f) * 64;
- yf = (float)y + (yf - 15.5f) * 64;
- //@size=114
- DBG(_n(" [%f %f] mm pattern center\n"), pos_2_mm(xf), pos_2_mm(yf));
- x = round_to_i16(xf);
- y = round_to_i16(yf);
- xyzcal_lineXYZ_to(x, y, z, 200, 0);
- ret = BED_SKEW_OFFSET_DETECTION_POINT_FOUND;
- }
- /// wipe buffer
- for (uint16_t i = 0; i < sizeof(block_t)*BLOCK_BUFFER_SIZE; i++)
- matrix32[i] = 0;
- return ret;
- }
- BedSkewOffsetDetectionResultType xyzcal_find_bed_induction_sensor_point_xy(void) {
- // DBG(_n("xyzcal_find_bed_induction_sensor_point_xy x=%ld y=%ld z=%ld\n"), count_position[X_AXIS], count_position[Y_AXIS], count_position[Z_AXIS]);
- BedSkewOffsetDetectionResultType ret = BED_SKEW_OFFSET_DETECTION_POINT_NOT_FOUND;
- xyzcal_meassure_enter();
- if (xyzcal_searchZ())
- ret = xyzcal_scan_and_process();
- xyzcal_meassure_leave();
- return ret;
- }
- #endif //NEW_XYZCAL
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