kinematics: Add dual_carriage to hybrid-corexyz (#4296)

- Add dual_carriage abilities for hybrid-corexy and hybrid-corexz
- Introduce the module idex_mode
- Fix add_stepper to the correct rail in hybrid-corexy

Signed-off-by: Fabrice GALLET <tircown@gmail.com>
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Tircown 2021-06-28 00:37:05 +02:00 committed by GitHub
parent 274d52729a
commit 4d559633e3
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6 changed files with 233 additions and 9 deletions

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@ -322,6 +322,15 @@ The following information is available in the `toolhead` object
the printer had to be paused because the toolhead moved faster than
moves could be read from the G-Code input.
# dual_carriage
The following information is available in
[dual_carriage](Config_Reference.md#dual_carriage)
on a hybrid_corexy or hybrid_corexz robot
- `mode`: The current mode. Possible values are: "FULL_CONTROL"
- `active_carriage`: The current active carriage.
Possible values are: "CARRIAGE_0", "CARRIAGE_1"
# virtual_sdcard
The following information is available in the

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@ -80,6 +80,7 @@ defs_trapq = """
defs_kin_cartesian = """
struct stepper_kinematics *cartesian_stepper_alloc(char axis);
struct stepper_kinematics *cartesian_reverse_stepper_alloc(char axis);
"""
defs_kin_corexy = """

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@ -49,3 +49,42 @@ cartesian_stepper_alloc(char axis)
}
return sk;
}
static double
cart_reverse_stepper_x_calc_position(struct stepper_kinematics *sk
, struct move *m, double move_time)
{
return -move_get_coord(m, move_time).x;
}
static double
cart_reverse_stepper_y_calc_position(struct stepper_kinematics *sk
, struct move *m, double move_time)
{
return -move_get_coord(m, move_time).y;
}
static double
cart_reverse_stepper_z_calc_position(struct stepper_kinematics *sk
, struct move *m, double move_time)
{
return -move_get_coord(m, move_time).z;
}
struct stepper_kinematics * __visible
cartesian_reverse_stepper_alloc(char axis)
{
struct stepper_kinematics *sk = malloc(sizeof(*sk));
memset(sk, 0, sizeof(*sk));
if (axis == 'x') {
sk->calc_position_cb = cart_reverse_stepper_x_calc_position;
sk->active_flags = AF_X;
} else if (axis == 'y') {
sk->calc_position_cb = cart_reverse_stepper_y_calc_position;
sk->active_flags = AF_Y;
} else if (axis == 'z') {
sk->calc_position_cb = cart_reverse_stepper_z_calc_position;
sk->active_flags = AF_Z;
}
return sk;
}

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@ -4,7 +4,7 @@
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import logging
import stepper
import stepper, idex_modes
# The hybrid-corexy kinematic is also known as Markforged kinematics
class HybridCoreXYKinematics:
@ -15,7 +15,7 @@ class HybridCoreXYKinematics:
self.rails = [ stepper.PrinterRail(config.getsection('stepper_x')),
stepper.LookupMultiRail(config.getsection('stepper_y')),
stepper.LookupMultiRail(config.getsection('stepper_z'))]
self.rails[2].get_endstops()[0][0].add_stepper(
self.rails[1].get_endstops()[0][0].add_stepper(
self.rails[0].get_steppers()[0])
self.rails[0].setup_itersolve('corexy_stepper_alloc', '-')
self.rails[1].setup_itersolve('cartesian_stepper_alloc', 'y')
@ -23,6 +23,26 @@ class HybridCoreXYKinematics:
ranges = [r.get_range() for r in self.rails]
self.axes_min = toolhead.Coord(*[r[0] for r in ranges], e=0.)
self.axes_max = toolhead.Coord(*[r[1] for r in ranges], e=0.)
self.dc_module = None
if config.has_section('dual_carriage'):
dc_config = config.getsection('dual_carriage')
# dummy for cartesian config users
dc_config.getchoice('axis', {'x': 'x'}, default='x')
# setup second dual carriage rail
self.rails.append(stepper.PrinterRail(dc_config))
self.rails[1].get_endstops()[0][0].add_stepper(
self.rails[3].get_steppers()[0])
self.rails[3].setup_itersolve('cartesian_stepper_alloc', 'y')
dc_rail_0 = idex_modes.DualCarriagesRail(
self.printer, self.rails[0], axis=0, active=True,
stepper_alloc_active=('corexy_stepper_alloc','-'),
stepper_alloc_inactive=('cartesian_reverse_stepper_alloc','y'))
dc_rail_1 = idex_modes.DualCarriagesRail(
self.printer, self.rails[3], axis=0, active=False,
stepper_alloc_active=('corexy_stepper_alloc','+'),
stepper_alloc_inactive=('cartesian_stepper_alloc','y'))
self.dc_module = idex_modes.DualCarriages(self.printer,
dc_rail_0, dc_rail_1, axis=0)
for s in self.get_steppers():
s.set_trapq(toolhead.get_trapq())
toolhead.register_step_generator(s.generate_steps)
@ -39,7 +59,15 @@ class HybridCoreXYKinematics:
return [s for rail in self.rails for s in rail.get_steppers()]
def calc_position(self, stepper_positions):
pos = [stepper_positions[rail.get_name()] for rail in self.rails]
return [pos[0] + pos[1], pos[1], pos[2]]
if (self.dc_module is not None and 'CARRIAGE_1' == \
self.dc_module.get_status()['active_carriage']):
return [pos[0] - pos[1], pos[1], pos[2]]
else:
return [pos[0] + pos[1], pos[1], pos[2]]
def update_limits(self, i, range):
self.limits[i] = range
def override_rail(self, i, rail):
self.rails[i] = rail
def set_position(self, newpos, homing_axes):
for i, rail in enumerate(self.rails):
rail.set_position(newpos)
@ -62,7 +90,14 @@ class HybridCoreXYKinematics:
homing_state.home_rails([rail], forcepos, homepos)
def home(self, homing_state):
for axis in homing_state.get_axes():
self._home_axis(homing_state, axis, self.rails[axis])
if (self.dc_module is not None and axis == 0):
self.dc_module.save_idex_state()
for i in [0,1]:
self.dc_module.toggle_active_dc_rail(i)
self._home_axis(homing_state, axis, self.rails[0])
self.dc_module.restore_idex_state()
else:
self._home_axis(homing_state, axis, self.rails[axis])
def _motor_off(self, print_time):
self.limits = [(1.0, -1.0)] * 3
def _check_endstops(self, move):
@ -93,7 +128,7 @@ class HybridCoreXYKinematics:
return {
'homed_axes': "".join(axes),
'axis_minimum': self.axes_min,
'axis_maximum': self.axes_max,
'axis_maximum': self.axes_max
}
def load_kinematics(toolhead, config):

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@ -4,7 +4,7 @@
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import logging
import stepper
import stepper, idex_modes
# The hybrid-corexz kinematic is also known as Markforged kinematics
class HybridCoreXZKinematics:
@ -23,6 +23,26 @@ class HybridCoreXZKinematics:
ranges = [r.get_range() for r in self.rails]
self.axes_min = toolhead.Coord(*[r[0] for r in ranges], e=0.)
self.axes_max = toolhead.Coord(*[r[1] for r in ranges], e=0.)
self.dc_module = None
if config.has_section('dual_carriage'):
dc_config = config.getsection('dual_carriage')
# dummy for cartesian config users
dc_config.getchoice('axis', {'x': 'x'}, default='x')
# setup second dual carriage rail
self.rails.append(stepper.PrinterRail(dc_config))
self.rails[2].get_endstops()[0][0].add_stepper(
self.rails[3].get_steppers()[0])
self.rails[3].setup_itersolve('cartesian_stepper_alloc', 'z')
dc_rail_0 = idex_modes.DualCarriagesRail(
self.printer, self.rails[0], axis=0, active=True,
stepper_alloc_active=('corexz_stepper_alloc','-'),
stepper_alloc_inactive=('cartesian_reverse_stepper_alloc','z'))
dc_rail_1 = idex_modes.DualCarriagesRail(
self.printer, self.rails[3], axis=0, active=False,
stepper_alloc_active=('corexz_stepper_alloc','+'),
stepper_alloc_inactive=('cartesian_stepper_alloc','z'))
self.dc_module = idex_modes.DualCarriages(self.printer,
dc_rail_0, dc_rail_1, axis=0)
for s in self.get_steppers():
s.set_trapq(toolhead.get_trapq())
toolhead.register_step_generator(s.generate_steps)
@ -39,7 +59,15 @@ class HybridCoreXZKinematics:
return [s for rail in self.rails for s in rail.get_steppers()]
def calc_position(self, stepper_positions):
pos = [stepper_positions[rail.get_name()] for rail in self.rails]
return [pos[0] + pos[2], pos[1], pos[2]]
if (self.dc_module is not None and 'CARRIAGE_1' == \
self.dc_module.get_status()['active_carriage']):
return [pos[0] - pos[2], pos[1], pos[2]]
else:
return [pos[0] + pos[2], pos[1], pos[2]]
def update_limits(self, i, range):
self.limits[i] = range
def override_rail(self, i, rail):
self.rails[i] = rail
def set_position(self, newpos, homing_axes):
for i, rail in enumerate(self.rails):
rail.set_position(newpos)
@ -62,7 +90,14 @@ class HybridCoreXZKinematics:
homing_state.home_rails([rail], forcepos, homepos)
def home(self, homing_state):
for axis in homing_state.get_axes():
self._home_axis(homing_state, axis, self.rails[axis])
if (self.dc_module is not None and axis == 0):
self.dc_module.save_idex_state()
for i in [0,1]:
self.dc_module.toggle_active_dc_rail(i)
self._home_axis(homing_state, axis, self.rails[0])
self.dc_module.restore_idex_state()
else:
self._home_axis(homing_state, axis, self.rails[axis])
def _motor_off(self, print_time):
self.limits = [(1.0, -1.0)] * 3
def _check_endstops(self, move):
@ -93,7 +128,7 @@ class HybridCoreXZKinematics:
return {
'homed_axes': "".join(axes),
'axis_minimum': self.axes_min,
'axis_maximum': self.axes_max,
'axis_maximum': self.axes_max
}
def load_kinematics(toolhead, config):

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@ -0,0 +1,105 @@
# Support for duplication and mirroring modes for IDEX printers
#
# Copyright (C) 2021 Fabrice Gallet <tircown@gmail.com>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import math
class DualCarriages:
def __init__(self, printer, rail_0, rail_1, axis):
self.printer = printer
self.axis = axis
self.dc = (rail_0, rail_1)
self.saved_state = None
self.printer.add_object('dual_carriage', self)
gcode = self.printer.lookup_object('gcode')
gcode.register_command(
'SET_DUAL_CARRIAGE', self.cmd_SET_DUAL_CARRIAGE,
desc=self.cmd_SET_DUAL_CARRIAGE_help)
def toggle_active_dc_rail(self, index):
toolhead = self.printer.lookup_object('toolhead')
toolhead.flush_step_generation()
pos = toolhead.get_position()
kin = toolhead.get_kinematics()
for i, dc in enumerate(self.dc):
dc_rail = dc.get_rail()
if i != index:
dc.inactivate(pos)
kin.override_rail(3, dc_rail)
elif dc.is_active() is False:
newpos = pos[:self.axis] + [dc.axis_position] \
+ pos[self.axis+1:]
dc.activate(newpos)
kin.override_rail(self.axis, dc_rail)
toolhead.set_position(newpos)
kin.update_limits(self.axis, dc_rail.get_range())
def get_status(self, eventtime):
dc0, dc1 = self.dc
if (dc0.is_active() is True):
return { 'mode': 'FULL_CONTROL', 'active_carriage': 'CARRIAGE_0' }
else:
return { 'mode': 'FULL_CONTROL', 'active_carriage': 'CARRIAGE_1' }
def save_idex_state(self):
dc0, dc1 = self.dc
if (dc0.is_active() is True):
mode, active_carriage = ('FULL_CONTROL', 'CARRIAGE_0')
else:
mode, active_carriage = ('FULL_CONTROL', 'CARRIAGE_1')
self.saved_state = {
'mode': mode,
'active_carriage': active_carriage,
'axis_positions': (dc0.axis_position, dc1.axis_position)
}
def restore_idex_state(self):
if self.saved_state is not None:
# set carriage 0 active
if (self.saved_state['active_carriage'] == 'CARRIAGE_0'
and self.dc[0].is_active() is False):
self.toggle_active_dc_rail(0)
# set carriage 1 active
elif (self.saved_state['active_carriage'] == 'CARRIAGE_1'
and self.dc[1].is_active() is False):
self.toggle_active_dc_rail(1)
cmd_SET_DUAL_CARRIAGE_help = "Set which carriage is active"
def cmd_SET_DUAL_CARRIAGE(self, gcmd):
index = gcmd.get_int('CARRIAGE', minval=0, maxval=1)
if (not(self.dc[0].is_active() == self.dc[1].is_active() == True)
and self.dc[index].is_active() is False):
self.toggle_active_dc_rail(index)
class DualCarriagesRail:
ACTIVE=1
INACTIVE=2
def __init__(self, printer, rail, axis, active, stepper_alloc_active,
stepper_alloc_inactive=None):
self.printer = printer
self.rail = rail
self.axis = axis
self.status = (self.INACTIVE, self.ACTIVE)[active]
self.stepper_alloc_active = stepper_alloc_active
self.stepper_alloc_inactive = stepper_alloc_inactive
self.axis_position = -1
def _stepper_alloc(self, position, active=True):
toolhead = self.printer.lookup_object('toolhead')
self.axis_position = position[self.axis]
self.rail.set_trapq(None)
if active is True:
self.status = self.ACTIVE
if self.stepper_alloc_active is not None:
self.rail.setup_itersolve(*self.stepper_alloc_active)
self.rail.set_position(position)
self.rail.set_trapq(toolhead.get_trapq())
else:
self.status = self.INACTIVE
if self.stepper_alloc_inactive is not None:
self.rail.setup_itersolve(*self.stepper_alloc_inactive)
self.rail.set_position(position)
self.rail.set_trapq(toolhead.get_trapq())
def get_rail(self):
return self.rail
def is_active(self):
return self.status == self.ACTIVE
def activate(self, position):
self._stepper_alloc(position, active=True)
def inactivate(self, position):
self._stepper_alloc(position, active=False)