mcu: Pass print_time directly to MCU calls
Now that the print_time is always synchronized with the mcu_time, there is no longer a need to track mcu_time as a separate quantity. Eliminate references to mcu_time from the code and pass print_time directly in its place. Signed-off-by: Kevin O'Connor <kevin@koconnor.net>
This commit is contained in:
parent
5dfe4e1eb9
commit
a100f174f9
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@ -62,16 +62,16 @@ class CartKinematics:
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# Set final homed position
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coord[axis] = s.position_endstop + s.get_homed_offset()
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homing_state.set_homed_position(coord)
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def motor_off(self, move_time):
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def motor_off(self, print_time):
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self.limits = [(1.0, -1.0)] * 3
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for stepper in self.steppers:
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stepper.motor_enable(move_time, 0)
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stepper.motor_enable(print_time, 0)
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self.need_motor_enable = True
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def _check_motor_enable(self, move_time, move):
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def _check_motor_enable(self, print_time, move):
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need_motor_enable = False
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for i in StepList:
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if move.axes_d[i]:
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self.steppers[i].motor_enable(move_time, 1)
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self.steppers[i].motor_enable(print_time, 1)
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need_motor_enable |= self.steppers[i].need_motor_enable
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self.need_motor_enable = need_motor_enable
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def query_endstops(self, print_time):
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@ -101,15 +101,15 @@ class CartKinematics:
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z_ratio = move.move_d / abs(move.axes_d[2])
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move.limit_speed(
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self.max_z_velocity * z_ratio, self.max_z_accel * z_ratio)
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def move(self, move_time, move):
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def move(self, print_time, move):
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if self.need_motor_enable:
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self._check_motor_enable(move_time, move)
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self._check_motor_enable(print_time, move)
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for i in StepList:
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axis_d = move.axes_d[i]
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if not axis_d:
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continue
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mcu_stepper = self.steppers[i].mcu_stepper
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mcu_time = mcu_stepper.print_to_mcu_time(move_time)
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move_time = print_time
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start_pos = move.start_pos[i]
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axis_r = abs(axis_d) / move.move_d
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accel = move.accel * axis_r
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@ -119,18 +119,18 @@ class CartKinematics:
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if move.accel_r:
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accel_d = move.accel_r * axis_d
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mcu_stepper.step_const(
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mcu_time, start_pos, accel_d, move.start_v * axis_r, accel)
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move_time, start_pos, accel_d, move.start_v * axis_r, accel)
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start_pos += accel_d
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mcu_time += move.accel_t
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move_time += move.accel_t
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# Cruising steps
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if move.cruise_r:
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cruise_d = move.cruise_r * axis_d
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mcu_stepper.step_const(
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mcu_time, start_pos, cruise_d, cruise_v, 0.)
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move_time, start_pos, cruise_d, cruise_v, 0.)
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start_pos += cruise_d
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mcu_time += move.cruise_t
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move_time += move.cruise_t
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# Deceleration steps
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if move.decel_r:
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decel_d = move.decel_r * axis_d
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mcu_stepper.step_const(
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mcu_time, start_pos, decel_d, cruise_v, -accel)
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move_time, start_pos, decel_d, cruise_v, -accel)
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@ -67,17 +67,17 @@ class CoreXYKinematics:
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# Support endstop phase detection on Z axis
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coord[axis] = s.position_endstop + s.get_homed_offset()
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homing_state.set_homed_position(coord)
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def motor_off(self, move_time):
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def motor_off(self, print_time):
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self.limits = [(1.0, -1.0)] * 3
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for stepper in self.steppers:
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stepper.motor_enable(move_time, 0)
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stepper.motor_enable(print_time, 0)
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self.need_motor_enable = True
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def _check_motor_enable(self, move_time, move):
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def _check_motor_enable(self, print_time, move):
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if move.axes_d[0] or move.axes_d[1]:
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self.steppers[0].motor_enable(move_time, 1)
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self.steppers[1].motor_enable(move_time, 1)
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self.steppers[0].motor_enable(print_time, 1)
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self.steppers[1].motor_enable(print_time, 1)
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if move.axes_d[2]:
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self.steppers[2].motor_enable(move_time, 1)
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self.steppers[2].motor_enable(print_time, 1)
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need_motor_enable = False
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for i in StepList:
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need_motor_enable |= self.steppers[i].need_motor_enable
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@ -109,9 +109,9 @@ class CoreXYKinematics:
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z_ratio = move.move_d / abs(move.axes_d[2])
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move.limit_speed(
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self.max_z_velocity * z_ratio, self.max_z_accel * z_ratio)
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def move(self, move_time, move):
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def move(self, print_time, move):
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if self.need_motor_enable:
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self._check_motor_enable(move_time, move)
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self._check_motor_enable(print_time, move)
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sxp = move.start_pos[0]
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syp = move.start_pos[1]
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move_start_pos = (sxp + syp, sxp - syp, move.start_pos[2])
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@ -124,7 +124,7 @@ class CoreXYKinematics:
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if not axis_d:
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continue
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mcu_stepper = self.steppers[i].mcu_stepper
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mcu_time = mcu_stepper.print_to_mcu_time(move_time)
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move_time = print_time
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start_pos = move_start_pos[i]
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axis_r = abs(axis_d) / move.move_d
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accel = move.accel * axis_r
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@ -134,18 +134,18 @@ class CoreXYKinematics:
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if move.accel_r:
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accel_d = move.accel_r * axis_d
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mcu_stepper.step_const(
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mcu_time, start_pos, accel_d, move.start_v * axis_r, accel)
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move_time, start_pos, accel_d, move.start_v * axis_r, accel)
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start_pos += accel_d
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mcu_time += move.accel_t
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move_time += move.accel_t
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# Cruising steps
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if move.cruise_r:
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cruise_d = move.cruise_r * axis_d
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mcu_stepper.step_const(
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mcu_time, start_pos, cruise_d, cruise_v, 0.)
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move_time, start_pos, cruise_d, cruise_v, 0.)
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start_pos += cruise_d
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mcu_time += move.cruise_t
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move_time += move.cruise_t
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# Deceleration steps
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if move.decel_r:
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decel_d = move.decel_r * axis_d
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mcu_stepper.step_const(
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mcu_time, start_pos, decel_d, cruise_v, -accel)
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move_time, start_pos, decel_d, cruise_v, -accel)
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@ -123,14 +123,14 @@ class DeltaKinematics:
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+ self.steppers[i].get_homed_offset()
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for i in StepList]
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homing_state.set_homed_position(self._actuator_to_cartesian(spos))
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def motor_off(self, move_time):
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def motor_off(self, print_time):
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self.limit_xy2 = -1.
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for stepper in self.steppers:
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stepper.motor_enable(move_time, 0)
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stepper.motor_enable(print_time, 0)
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self.need_motor_enable = self.need_home = True
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def _check_motor_enable(self, move_time):
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def _check_motor_enable(self, print_time):
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for i in StepList:
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self.steppers[i].motor_enable(move_time, 1)
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self.steppers[i].motor_enable(print_time, 1)
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self.need_motor_enable = False
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def query_endstops(self, print_time):
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endstops = [(s, s.query_endstop(print_time)) for s in self.steppers]
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@ -164,9 +164,9 @@ class DeltaKinematics:
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move.limit_speed(max_velocity * r, self.max_accel * r)
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limit_xy2 = -1.
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self.limit_xy2 = min(limit_xy2, self.slow_xy2)
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def move(self, move_time, move):
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def move(self, print_time, move):
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if self.need_motor_enable:
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self._check_motor_enable(move_time)
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self._check_motor_enable(print_time)
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axes_d = move.axes_d
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move_d = move.move_d
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movexy_r = 1.
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@ -203,24 +203,24 @@ class DeltaKinematics:
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# Generate steps
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mcu_stepper = self.steppers[i].mcu_stepper
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mcu_time = mcu_stepper.print_to_mcu_time(move_time)
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move_time = print_time
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if accel_d:
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mcu_stepper.step_delta(
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mcu_time, accel_d, move.start_v, accel,
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move_time, accel_d, move.start_v, accel,
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vt_startz, vt_startxy_d, vt_arm_d, movez_r)
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vt_startz += accel_d * movez_r
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vt_startxy_d -= accel_d * movexy_r
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mcu_time += move.accel_t
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move_time += move.accel_t
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if cruise_d:
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mcu_stepper.step_delta(
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mcu_time, cruise_d, cruise_v, 0.,
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move_time, cruise_d, cruise_v, 0.,
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vt_startz, vt_startxy_d, vt_arm_d, movez_r)
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vt_startz += cruise_d * movez_r
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vt_startxy_d -= cruise_d * movexy_r
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mcu_time += move.cruise_t
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move_time += move.cruise_t
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if decel_d:
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mcu_stepper.step_delta(
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mcu_time, decel_d, cruise_v, -accel,
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move_time, decel_d, cruise_v, -accel,
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vt_startz, vt_startxy_d, vt_arm_d, movez_r)
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@ -50,8 +50,8 @@ class PrinterExtruder:
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if is_active:
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return self.activate_gcode
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return self.deactivate_gcode
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def motor_off(self, move_time):
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self.stepper.motor_enable(move_time, 0)
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def motor_off(self, print_time):
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self.stepper.motor_enable(print_time, 0)
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self.need_motor_enable = True
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def check_move(self, move):
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move.extrude_r = move.axes_d[3] / move.move_d
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@ -131,9 +131,9 @@ class PrinterExtruder:
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return i
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move.extrude_max_corner_v = max_corner_v
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return flush_count
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def move(self, move_time, move):
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def move(self, print_time, move):
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if self.need_motor_enable:
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self.stepper.motor_enable(move_time, 1)
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self.stepper.motor_enable(print_time, 1)
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self.need_motor_enable = False
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axis_d = move.axes_d[3]
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axis_r = abs(axis_d) / move.move_d
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@ -190,27 +190,28 @@ class PrinterExtruder:
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# Prepare for steps
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mcu_stepper = self.stepper.mcu_stepper
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mcu_time = mcu_stepper.print_to_mcu_time(move_time)
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move_time = print_time
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# Acceleration steps
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if accel_d:
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mcu_stepper.step_const(mcu_time, start_pos, accel_d, start_v, accel)
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mcu_stepper.step_const(move_time, start_pos, accel_d, start_v, accel)
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start_pos += accel_d
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mcu_time += accel_t
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move_time += accel_t
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# Cruising steps
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if cruise_d:
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mcu_stepper.step_const(mcu_time, start_pos, cruise_d, cruise_v, 0.)
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mcu_stepper.step_const(move_time, start_pos, cruise_d, cruise_v, 0.)
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start_pos += cruise_d
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mcu_time += cruise_t
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move_time += cruise_t
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# Deceleration steps
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if decel_d:
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mcu_stepper.step_const(mcu_time, start_pos, decel_d, decel_v, -accel)
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mcu_stepper.step_const(
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move_time, start_pos, decel_d, decel_v, -accel)
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start_pos += decel_d
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mcu_time += decel_t
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move_time += decel_t
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# Retraction steps
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if retract_d:
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mcu_stepper.step_const(
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mcu_time, start_pos, -retract_d, retract_v, accel)
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move_time, start_pos, -retract_d, retract_v, accel)
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start_pos -= retract_d
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self.extrude_pos = start_pos
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@ -18,23 +18,19 @@ class PrinterFan:
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self.mcu_fan.setup_max_duration(0.)
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self.mcu_fan.setup_cycle_time(PWM_CYCLE_TIME)
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self.mcu_fan.setup_hard_pwm(config.getint('hard_pwm', 0))
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def set_pwm(self, mcu_time, value):
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def set_speed(self, print_time, value):
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value = max(0., min(self.max_power, value))
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if value == self.last_fan_value:
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return
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mcu_time = max(self.last_fan_time + FAN_MIN_TIME, mcu_time)
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print_time = max(self.last_fan_time + FAN_MIN_TIME, print_time)
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if (value and value < self.max_power
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and not self.last_fan_value and self.kick_start_time):
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# Run fan at full speed for specified kick_start_time
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self.mcu_fan.set_pwm(mcu_time, self.max_power)
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mcu_time += self.kick_start_time
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self.mcu_fan.set_pwm(mcu_time, value)
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self.last_fan_time = mcu_time
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self.mcu_fan.set_pwm(print_time, self.max_power)
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print_time += self.kick_start_time
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self.mcu_fan.set_pwm(print_time, value)
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self.last_fan_time = print_time
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self.last_fan_value = value
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# External commands
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def set_speed(self, print_time, value):
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mcu_time = self.mcu_fan.get_mcu().print_to_mcu_time(print_time)
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self.set_pwm(mcu_time, value)
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class PrinterHeaterFan:
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def __init__(self, printer, config):
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@ -42,7 +42,7 @@ class Homing:
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move_end_print_time = self.toolhead.get_last_move_time()
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self.toolhead.reset_print_time()
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for s, es, last_pos in endstops:
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es.home_finalize(es.get_mcu().print_to_mcu_time(move_end_print_time))
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es.home_finalize(move_end_print_time)
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# Wait for endstops to trigger
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for s, es, last_pos in endstops:
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try:
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@ -25,7 +25,6 @@ class MCU_stepper:
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self._mcu_freq = self._min_stop_interval = 0.
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self._reset_cmd = self._get_position_cmd = None
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self._ffi_lib = self._stepqueue = None
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self.print_to_mcu_time = mcu.print_to_mcu_time
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def get_mcu(self):
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return self._mcu
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def setup_dir_pin(self, pin_params):
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@ -48,7 +47,8 @@ class MCU_stepper:
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"config_stepper oid=%d step_pin=%s dir_pin=%s"
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" min_stop_interval=%d invert_step=%d" % (
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self._oid, self._step_pin, self._dir_pin,
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min_stop_interval * self._mcu_freq, self._invert_step))
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self._mcu.seconds_to_clock(min_stop_interval),
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self._invert_step))
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step_cmd = self._mcu.lookup_command(
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"queue_step oid=%c interval=%u count=%hu add=%hi")
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dir_cmd = self._mcu.lookup_command(
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@ -58,9 +58,8 @@ class MCU_stepper:
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self._get_position_cmd = self._mcu.lookup_command(
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"stepper_get_position oid=%c")
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ffi_main, self._ffi_lib = chelper.get_ffi()
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max_error = int(max_error * self._mcu_freq)
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self._stepqueue = ffi_main.gc(self._ffi_lib.stepcompress_alloc(
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max_error, step_cmd.msgid, dir_cmd.msgid,
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self._mcu.seconds_to_clock(max_error), step_cmd.msgid, dir_cmd.msgid,
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self._invert_dir, self._oid),
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self._ffi_lib.stepcompress_free)
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self._mcu.register_stepqueue(self._stepqueue)
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@ -97,8 +96,8 @@ class MCU_stepper:
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if self._invert_dir:
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pos = -pos
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self._mcu_position_offset = pos - self._commanded_pos
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def reset_step_clock(self, mcu_time):
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clock = int(mcu_time * self._mcu_freq)
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def reset_step_clock(self, print_time):
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clock = self._mcu.print_time_to_clock(print_time)
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ret = self._ffi_lib.stepcompress_reset(self._stepqueue, clock)
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if ret:
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raise error("Internal error in stepcompress")
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@ -107,28 +106,29 @@ class MCU_stepper:
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self._stepqueue, data, len(data))
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if ret:
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raise error("Internal error in stepcompress")
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def step(self, mcu_time, sdir):
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count = self._ffi_lib.stepcompress_push(
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self._stepqueue, mcu_time * self._mcu_freq, sdir)
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def step(self, print_time, sdir):
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clock = print_time * self._mcu_freq
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count = self._ffi_lib.stepcompress_push(self._stepqueue, clock, sdir)
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if count == STEPCOMPRESS_ERROR_RET:
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raise error("Internal error in stepcompress")
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self._commanded_pos += count
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def step_const(self, mcu_time, start_pos, dist, start_v, accel):
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def step_const(self, print_time, start_pos, dist, start_v, accel):
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clock = print_time * self._mcu_freq
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inv_step_dist = self._inv_step_dist
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step_offset = self._commanded_pos - start_pos * inv_step_dist
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count = self._ffi_lib.stepcompress_push_const(
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self._stepqueue, mcu_time * self._mcu_freq, step_offset,
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dist * inv_step_dist, start_v * self._velocity_factor,
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accel * self._accel_factor)
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self._stepqueue, clock, step_offset, dist * inv_step_dist,
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start_v * self._velocity_factor, accel * self._accel_factor)
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if count == STEPCOMPRESS_ERROR_RET:
|
||||
raise error("Internal error in stepcompress")
|
||||
self._commanded_pos += count
|
||||
def step_delta(self, mcu_time, dist, start_v, accel
|
||||
def step_delta(self, print_time, dist, start_v, accel
|
||||
, height_base, startxy_d, arm_d, movez_r):
|
||||
clock = print_time * self._mcu_freq
|
||||
inv_step_dist = self._inv_step_dist
|
||||
height = self._commanded_pos - height_base * inv_step_dist
|
||||
count = self._ffi_lib.stepcompress_push_delta(
|
||||
self._stepqueue, mcu_time * self._mcu_freq, dist * inv_step_dist,
|
||||
self._stepqueue, clock, dist * inv_step_dist,
|
||||
start_v * self._velocity_factor, accel * self._accel_factor,
|
||||
height, startxy_d * inv_step_dist, arm_d * inv_step_dist, movez_r)
|
||||
if count == STEPCOMPRESS_ERROR_RET:
|
||||
|
@ -147,7 +147,7 @@ class MCU_endstop:
|
|||
self._cmd_queue = mcu.alloc_command_queue()
|
||||
self._oid = self._home_cmd = self._query_cmd = None
|
||||
self._homing = False
|
||||
self._min_query_time = self._mcu_freq = 0.
|
||||
self._min_query_time = 0.
|
||||
self._next_query_clock = self._home_timeout_clock = 0
|
||||
self._retry_query_ticks = 0
|
||||
self._last_state = {}
|
||||
|
@ -156,7 +156,6 @@ class MCU_endstop:
|
|||
def add_stepper(self, stepper):
|
||||
self._steppers.append(stepper)
|
||||
def build_config(self):
|
||||
self._mcu_freq = self._mcu.get_mcu_freq()
|
||||
self._oid = self._mcu.create_oid()
|
||||
self._mcu.add_config_cmd(
|
||||
"config_end_stop oid=%d pin=%s pull_up=%d stepper_count=%d" % (
|
||||
|
@ -165,15 +164,15 @@ class MCU_endstop:
|
|||
self._mcu.add_config_cmd(
|
||||
"end_stop_set_stepper oid=%d pos=%d stepper_oid=%d" % (
|
||||
self._oid, i, s.get_oid()), is_init=True)
|
||||
self._retry_query_ticks = int(self._mcu_freq * self.RETRY_QUERY)
|
||||
self._retry_query_ticks = self._mcu.seconds_to_clock(self.RETRY_QUERY)
|
||||
self._home_cmd = self._mcu.lookup_command(
|
||||
"end_stop_home oid=%c clock=%u rest_ticks=%u pin_value=%c")
|
||||
self._query_cmd = self._mcu.lookup_command("end_stop_query oid=%c")
|
||||
self._mcu.register_msg(self._handle_end_stop_state, "end_stop_state"
|
||||
, self._oid)
|
||||
def home_start(self, mcu_time, rest_time):
|
||||
clock = int(mcu_time * self._mcu_freq)
|
||||
rest_ticks = int(rest_time * self._mcu_freq)
|
||||
def home_start(self, print_time, rest_time):
|
||||
clock = self._mcu.print_time_to_clock(print_time)
|
||||
rest_ticks = self._mcu.seconds_to_clock(rest_time)
|
||||
self._homing = True
|
||||
self._min_query_time = self._mcu.monotonic()
|
||||
self._next_query_clock = clock + self._retry_query_ticks
|
||||
|
@ -182,10 +181,10 @@ class MCU_endstop:
|
|||
self._mcu.send(msg, reqclock=clock, cq=self._cmd_queue)
|
||||
for s in self._steppers:
|
||||
s.note_homing_start(clock)
|
||||
def home_finalize(self, mcu_time):
|
||||
def home_finalize(self, print_time):
|
||||
for s in self._steppers:
|
||||
s.note_homing_finalized()
|
||||
self._home_timeout_clock = int(mcu_time * self._mcu_freq)
|
||||
self._home_timeout_clock = self._mcu.print_time_to_clock(print_time)
|
||||
def home_wait(self):
|
||||
eventtime = self._mcu.monotonic()
|
||||
while self._check_busy(eventtime):
|
||||
|
@ -220,11 +219,10 @@ class MCU_endstop:
|
|||
msg = self._query_cmd.encode(self._oid)
|
||||
self._mcu.send(msg, cq=self._cmd_queue)
|
||||
return True
|
||||
def query_endstop(self, mcu_time):
|
||||
clock = int(mcu_time * self._mcu_freq)
|
||||
def query_endstop(self, print_time):
|
||||
self._homing = False
|
||||
self._next_query_clock = self._mcu.print_time_to_clock(print_time)
|
||||
self._min_query_time = self._mcu.monotonic()
|
||||
self._next_query_clock = clock
|
||||
def query_endstop_wait(self):
|
||||
eventtime = self._mcu.monotonic()
|
||||
while self._check_busy(eventtime):
|
||||
|
@ -241,7 +239,6 @@ class MCU_digital_out:
|
|||
self._max_duration = 2.
|
||||
self._last_clock = 0
|
||||
self._last_value = None
|
||||
self._mcu_freq = 0.
|
||||
self._cmd_queue = mcu.alloc_command_queue()
|
||||
self._set_cmd = None
|
||||
def get_mcu(self):
|
||||
|
@ -251,7 +248,6 @@ class MCU_digital_out:
|
|||
def setup_static(self):
|
||||
self._static_value = not self._invert
|
||||
def build_config(self):
|
||||
self._mcu_freq = self._mcu.get_mcu_freq()
|
||||
if self._static_value is not None:
|
||||
self._mcu.add_config_cmd("set_digital_out pin=%s value=%d" % (
|
||||
self._pin, self._static_value))
|
||||
|
@ -261,11 +257,11 @@ class MCU_digital_out:
|
|||
"config_digital_out oid=%d pin=%s default_value=%d"
|
||||
" max_duration=%d" % (
|
||||
self._oid, self._pin, self._invert,
|
||||
self._max_duration * self._mcu_freq))
|
||||
self._mcu.seconds_to_clock(self._max_duration)))
|
||||
self._set_cmd = self._mcu.lookup_command(
|
||||
"schedule_digital_out oid=%c clock=%u value=%c")
|
||||
def set_digital(self, mcu_time, value):
|
||||
clock = int(mcu_time * self._mcu_freq)
|
||||
def set_digital(self, print_time, value):
|
||||
clock = self._mcu.print_time_to_clock(print_time)
|
||||
msg = self._set_cmd.encode(
|
||||
self._oid, clock, not not (value ^ self._invert))
|
||||
self._mcu.send(msg, minclock=self._last_clock, reqclock=clock
|
||||
|
@ -274,8 +270,8 @@ class MCU_digital_out:
|
|||
self._last_value = value
|
||||
def get_last_setting(self):
|
||||
return self._last_value
|
||||
def set_pwm(self, mcu_time, value):
|
||||
self.set_digital(mcu_time, value >= 0.5)
|
||||
def set_pwm(self, print_time, value):
|
||||
self.set_digital(print_time, value >= 0.5)
|
||||
|
||||
class MCU_pwm:
|
||||
def __init__(self, mcu, pin_params):
|
||||
|
@ -288,7 +284,6 @@ class MCU_pwm:
|
|||
self._pin = pin_params['pin']
|
||||
self._invert = pin_params['invert']
|
||||
self._last_clock = 0
|
||||
self._mcu_freq = 0.
|
||||
self._pwm_max = 0.
|
||||
self._cmd_queue = mcu.alloc_command_queue()
|
||||
self._set_cmd = None
|
||||
|
@ -309,7 +304,6 @@ class MCU_pwm:
|
|||
value = 1. - value
|
||||
self._static_value = max(0., min(1., value))
|
||||
def build_config(self):
|
||||
self._mcu_freq = self._mcu.get_mcu_freq()
|
||||
if self._hard_pwm:
|
||||
self._pwm_max = self._mcu.serial.msgparser.get_constant_float(
|
||||
"PWM_MAX")
|
||||
|
@ -324,7 +318,7 @@ class MCU_pwm:
|
|||
"config_pwm_out oid=%d pin=%s cycle_ticks=%d default_value=%d"
|
||||
" max_duration=%d" % (
|
||||
self._oid, self._pin, self._cycle_time, self._invert,
|
||||
self._max_duration * self._mcu_freq))
|
||||
self._mcu.seconds_to_clock(self._max_duration)))
|
||||
self._set_cmd = self._mcu.lookup_command(
|
||||
"schedule_pwm_out oid=%c clock=%u value=%hu")
|
||||
else:
|
||||
|
@ -340,12 +334,14 @@ class MCU_pwm:
|
|||
self._mcu.add_config_cmd(
|
||||
"config_soft_pwm_out oid=%d pin=%s cycle_ticks=%d"
|
||||
" default_value=%d max_duration=%d" % (
|
||||
self._oid, self._pin, self._cycle_time * self._mcu_freq,
|
||||
self._invert, self._max_duration * self._mcu_freq))
|
||||
self._oid, self._pin,
|
||||
self._mcu.seconds_to_clock(self._cycle_time),
|
||||
self._invert,
|
||||
self._mcu.seconds_to_clock(self._max_duration)))
|
||||
self._set_cmd = self._mcu.lookup_command(
|
||||
"schedule_soft_pwm_out oid=%c clock=%u value=%hu")
|
||||
def set_pwm(self, mcu_time, value):
|
||||
clock = int(mcu_time * self._mcu_freq)
|
||||
def set_pwm(self, print_time, value):
|
||||
clock = self._mcu.print_time_to_clock(print_time)
|
||||
if self._invert:
|
||||
value = 1. - value
|
||||
value = int(max(0., min(1., value)) * self._pwm_max + 0.5)
|
||||
|
@ -364,7 +360,6 @@ class MCU_adc:
|
|||
self._report_clock = 0
|
||||
self._oid = self._callback = None
|
||||
self._inv_max_adc = 0.
|
||||
self._mcu_freq = 0.
|
||||
self._cmd_queue = mcu.alloc_command_queue()
|
||||
def get_mcu(self):
|
||||
return self._mcu
|
||||
|
@ -379,17 +374,17 @@ class MCU_adc:
|
|||
def build_config(self):
|
||||
if not self._sample_count:
|
||||
return
|
||||
self._mcu_freq = self._mcu.get_mcu_freq()
|
||||
self._oid = self._mcu.create_oid()
|
||||
self._mcu.add_config_cmd("config_analog_in oid=%d pin=%s" % (
|
||||
self._oid, self._pin))
|
||||
last_clock, last_clock_time = self._mcu.get_last_clock()
|
||||
clock = last_clock + int(self._mcu_freq * (1.0 + self._oid * 0.01)) # XXX
|
||||
sample_ticks = int(self._sample_time * self._mcu_freq)
|
||||
clock = last_clock + self._mcu.seconds_to_clock(
|
||||
1.0 + self._oid * 0.01) # XXX
|
||||
sample_ticks = self._mcu.seconds_to_clock(self._sample_time)
|
||||
mcu_adc_max = self._mcu.serial.msgparser.get_constant_float("ADC_MAX")
|
||||
max_adc = self._sample_count * mcu_adc_max
|
||||
self._inv_max_adc = 1.0 / max_adc
|
||||
self._report_clock = int(self._report_time * self._mcu_freq)
|
||||
self._report_clock = self._mcu.seconds_to_clock(self._report_time)
|
||||
min_sample = max(0, min(0xffff, int(self._min_sample * max_adc)))
|
||||
max_sample = max(0, min(0xffff, int(
|
||||
math.ceil(self._max_sample * max_adc))))
|
||||
|
@ -403,7 +398,8 @@ class MCU_adc:
|
|||
def _handle_analog_in_state(self, params):
|
||||
last_value = params['value'] * self._inv_max_adc
|
||||
next_clock = self._mcu.serial.translate_clock(params['next_clock'])
|
||||
last_read_time = (next_clock - self._report_clock) / self._mcu_freq
|
||||
last_read_clock = next_clock - self._report_clock
|
||||
last_read_time = self._mcu.clock_to_print_time(last_read_clock)
|
||||
if self._callback is not None:
|
||||
self._callback(last_read_time, last_value)
|
||||
|
||||
|
@ -690,8 +686,6 @@ class MCU:
|
|||
def create_command(self, msg):
|
||||
return self.serial.msgparser.create_command(msg)
|
||||
# Clock syncing
|
||||
def print_to_mcu_time(self, print_time):
|
||||
return print_time
|
||||
def print_time_to_clock(self, print_time):
|
||||
return int(print_time * self._mcu_freq)
|
||||
def clock_to_print_time(self, clock):
|
||||
|
@ -700,6 +694,8 @@ class MCU:
|
|||
return self.clock_to_print_time(self.serial.get_clock(eventtime))
|
||||
def get_mcu_freq(self):
|
||||
return self._mcu_freq
|
||||
def seconds_to_clock(self, time):
|
||||
return int(time * self._mcu_freq)
|
||||
def get_last_clock(self):
|
||||
return self.serial.get_last_clock()
|
||||
def get_max_stepper_error(self):
|
||||
|
|
|
@ -38,14 +38,12 @@ class PrinterStepper:
|
|||
2. * self.step_dist, max_halt_velocity, max_accel)
|
||||
min_stop_interval = second_last_step_time - last_step_time
|
||||
self.mcu_stepper.setup_min_stop_interval(min_stop_interval)
|
||||
def motor_enable(self, move_time, enable=0):
|
||||
def motor_enable(self, print_time, enable=0):
|
||||
if enable and self.need_motor_enable:
|
||||
mcu_time = self.mcu_stepper.print_to_mcu_time(move_time)
|
||||
self.mcu_stepper.reset_step_clock(mcu_time)
|
||||
self.mcu_stepper.reset_step_clock(print_time)
|
||||
if (self.mcu_enable is not None
|
||||
and self.mcu_enable.get_last_setting() != enable):
|
||||
mcu_time = self.mcu_enable.get_mcu().print_to_mcu_time(move_time)
|
||||
self.mcu_enable.set_digital(mcu_time, enable)
|
||||
self.mcu_enable.set_digital(print_time, enable)
|
||||
self.need_motor_enable = not enable
|
||||
|
||||
class PrinterHomingStepper(PrinterStepper):
|
||||
|
@ -97,13 +95,11 @@ class PrinterHomingStepper(PrinterStepper):
|
|||
self.homing_stepper_phases = None
|
||||
if self.mcu_endstop.get_mcu().is_fileoutput():
|
||||
self.homing_endstop_accuracy = self.homing_stepper_phases
|
||||
def enable_endstop_checking(self, move_time, step_time):
|
||||
mcu_time = self.mcu_endstop.get_mcu().print_to_mcu_time(move_time)
|
||||
self.mcu_endstop.home_start(mcu_time, step_time)
|
||||
def enable_endstop_checking(self, print_time, step_time):
|
||||
self.mcu_endstop.home_start(print_time, step_time)
|
||||
return self.mcu_endstop
|
||||
def query_endstop(self, print_time):
|
||||
mcu_time = self.mcu_endstop.get_mcu().print_to_mcu_time(print_time)
|
||||
self.mcu_endstop.query_endstop(mcu_time)
|
||||
self.mcu_endstop.query_endstop(print_time)
|
||||
return self.mcu_endstop
|
||||
def get_homing_speed(self):
|
||||
# Round the configured homing speed so that it is an even
|
||||
|
|
Loading…
Reference in New Issue