4f9bcde40e
Conflicts: README.md gcode.c motion_control.c planner.c planner.h protocol.c report.c settings.c settings.h stepper.c stepper.h
747 lines
36 KiB
C
747 lines
36 KiB
C
/*
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stepper.c - stepper motor driver: executes motion plans using stepper motors
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Part of Grbl
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Copyright (c) 2011-2013 Sungeun K. Jeon
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Copyright (c) 2009-2011 Simen Svale Skogsrud
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Grbl is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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Grbl is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with Grbl. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <avr/interrupt.h>
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#include "stepper.h"
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#include "config.h"
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#include "settings.h"
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#include "planner.h"
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#include "nuts_bolts.h"
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// Some useful constants
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#define TICKS_PER_MICROSECOND (F_CPU/1000000)
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#define RAMP_NOOP_CRUISE 0
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#define RAMP_ACCEL 1
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#define RAMP_DECEL 2
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#define LOAD_NOOP 0
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#define LOAD_SEGMENT 1
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#define LOAD_BLOCK 2
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#define SEGMENT_NOOP 0
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#define SEGMENT_END_OF_BLOCK bit(0)
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#define SEGMENT_ACCEL bit(1)
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#define SEGMENT_DECEL bit(2)
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#define MINIMUM_STEPS_PER_SEGMENT 1 // Don't change
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#define SEGMENT_BUFFER_SIZE 6
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// Stepper state variable. Contains running data and trapezoid variables.
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typedef struct {
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// Used by the bresenham line algorithm
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int32_t counter_x, // Counter variables for the bresenham line tracer
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counter_y,
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counter_z;
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uint8_t segment_steps_remaining; // Steps remaining in line segment motion
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// Used by inverse time algorithm to track step rate
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int32_t counter_d; // Inverse time distance traveled since last step event
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uint32_t delta_d; // Inverse time distance traveled per interrupt tick
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uint32_t d_per_tick;
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// Used by the stepper driver interrupt
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uint8_t execute_step; // Flags step execution for each interrupt.
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uint8_t step_pulse_time; // Step pulse reset time after step rise
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uint8_t out_bits; // The next stepping-bits to be output
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uint8_t load_flag;
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uint8_t ramp_count;
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uint8_t ramp_type;
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} stepper_t;
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static stepper_t st;
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// Stores stepper common data for executing steps in the segment buffer. Data can change mid-block when the
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// planner updates the remaining block velocity profile with a more optimal plan or a feedrate override occurs.
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// NOTE: Normally, this buffer is partially in-use, but, for the worst case scenario, it will never exceed
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// the number of accessible stepper buffer segments (SEGMENT_BUFFER_SIZE-1).
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typedef struct {
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int32_t step_events_remaining; // Tracks step event count for the executing planner block
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uint32_t d_next; // Scaled distance to next step
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uint32_t initial_rate; // Initialized step rate at re/start of a planner block
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uint32_t nominal_rate; // The nominal step rate for this block in step_events/minute
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uint32_t rate_delta; // The steps/minute to add or subtract when changing speed (must be positive)
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uint32_t current_approx_rate; // Tracks the approximate segment rate to predict steps per segment to execute
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int32_t decelerate_after; // Tracks when to initiate deceleration according to the planner block
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float mm_per_step;
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} st_data_t;
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static st_data_t segment_data[SEGMENT_BUFFER_SIZE-1];
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// Primary stepper segment ring buffer. Contains small, short line segments for the stepper algorithm to execute,
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// which are "checked-out" incrementally from the first block in the planner buffer. Once "checked-out", the steps
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// in the segments buffer cannot be modified by the planner, where the remaining planner block steps still can.
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typedef struct {
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uint8_t n_step; // Number of step events to be executed for this segment
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uint8_t st_data_index; // Stepper buffer common data index. Uses this information to execute this segment.
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uint8_t flag; // Stepper algorithm bit-flag for special execution conditions.
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} st_segment_t;
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static st_segment_t segment_buffer[SEGMENT_BUFFER_SIZE];
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// Step segment ring buffer indices
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static volatile uint8_t segment_buffer_tail;
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static volatile uint8_t segment_buffer_head;
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static uint8_t segment_next_head;
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static volatile uint8_t busy; // Used to avoid ISR nesting of the "Stepper Driver Interrupt". Should never occur though.
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static plan_block_t *pl_current_block; // A pointer to the planner block currently being traced
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static st_segment_t *st_current_segment;
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static st_data_t *st_current_data;
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// Pointers for the step segment being prepped from the planner buffer. Accessed only by the
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// main program. Pointers may be planning segments or planner blocks ahead of what being executed.
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static plan_block_t *pl_prep_block; // Pointer to the planner block being prepped
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static st_data_t *st_prep_data; // Pointer to the stepper common data being prepped
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static uint8_t pl_prep_index; // Index of planner block being prepped
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static uint8_t st_data_prep_index; // Index of stepper common data block being prepped
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static uint8_t pl_partial_block_flag; // Flag indicating the planner has modified the prepped planner block
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/* __________________________
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/| |\ _________________ ^
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/ | | \ /| |\ |
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/ | | \ / | | \ s
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/ | | | | | \ p
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/ | | | | | \ e
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+-----+------------------------+---+--+---------------+----+ e
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| BLOCK 1 | BLOCK 2 | d
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time ----->
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The trapezoid is the shape the speed curve over time. It starts at block->initial_rate, accelerates by block->rate_delta
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until reaching cruising speed block->nominal_rate, and/or until step_events_remaining reaches block->decelerate_after
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after which it decelerates until the block is completed. The driver uses constant acceleration, which is applied as
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+/- block->rate_delta velocity increments by the midpoint rule at each ACCELERATION_TICKS_PER_SECOND.
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*/
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// Stepper state initialization. Cycle should only start if the st.cycle_start flag is
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// enabled. Startup init and limits call this function but shouldn't start the cycle.
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void st_wake_up()
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{
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// Enable steppers by resetting the stepper disable port
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if (bit_istrue(settings.flags,BITFLAG_INVERT_ST_ENABLE)) {
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STEPPERS_DISABLE_PORT |= (1<<STEPPERS_DISABLE_BIT);
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} else {
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STEPPERS_DISABLE_PORT &= ~(1<<STEPPERS_DISABLE_BIT);
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}
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if (sys.state == STATE_CYCLE) {
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// Initialize stepper output bits
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st.out_bits = settings.invert_mask;
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// Initialize step pulse timing from settings.
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st.step_pulse_time = -(((settings.pulse_microseconds-2)*TICKS_PER_MICROSECOND) >> 3);
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// Enable stepper driver interrupt
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st.execute_step = false;
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st.load_flag = LOAD_BLOCK;
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TCNT2 = 0; // Clear Timer2
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TIMSK2 |= (1<<OCIE2A); // Enable Timer2 Compare Match A interrupt
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TCCR2B = (1<<CS21); // Begin Timer2. Full speed, 1/8 prescaler
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}
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}
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// Stepper shutdown
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void st_go_idle()
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{
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// Disable stepper driver interrupt. Allow Timer0 to finish. It will disable itself.
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TIMSK2 &= ~(1<<OCIE2A); // Disable Timer2 interrupt
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TCCR2B = 0; // Disable Timer2
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busy = false;
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// Disable steppers only upon system alarm activated or by user setting to not be kept enabled.
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if ((settings.stepper_idle_lock_time != 0xff) || bit_istrue(sys.execute,EXEC_ALARM)) {
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// Force stepper dwell to lock axes for a defined amount of time to ensure the axes come to a complete
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// stop and not drift from residual inertial forces at the end of the last movement.
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delay_ms(settings.stepper_idle_lock_time);
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if (bit_istrue(settings.flags,BITFLAG_INVERT_ST_ENABLE)) {
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STEPPERS_DISABLE_PORT &= ~(1<<STEPPERS_DISABLE_BIT);
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} else {
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STEPPERS_DISABLE_PORT |= (1<<STEPPERS_DISABLE_BIT);
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}
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}
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}
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/* "The Stepper Driver Interrupt" - This timer interrupt is the workhorse of Grbl. It is based
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on an inverse time stepper algorithm, where a timer ticks at a constant frequency and uses
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time-distance counters to track when its the approximate time for a step event. For reference,
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a similar inverse-time algorithm by Pramod Ranade is susceptible to numerical round-off,
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meaning that some axes steps may not execute correctly for a given multi-axis motion.
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Grbl's algorithm differs by using a single inverse time-distance counter to manage a
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Bresenham line algorithm for multi-axis step events, which ensures the number of steps for
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each axis are executed exactly. In other words, Grbl uses a Bresenham within a Bresenham
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algorithm, where one tracks time for step events and the other steps for multi-axis moves.
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Grbl specifically uses the Bresenham algorithm due to its innate mathematical exactness and
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low computational overhead, requiring simple integer +,- counters only.
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This interrupt pops blocks from the step segment buffer and executes them by pulsing the
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stepper pins appropriately. It is supported by The Stepper Port Reset Interrupt which it uses
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to reset the stepper port after each pulse. The bresenham line tracer algorithm controls all
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three stepper outputs simultaneously with these two interrupts.
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*/
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/* TODO:
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- Measure time in ISR. Typical and worst-case. Should be virtually identical to last algorithm.
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There are no major changes to the base operations of this ISR with the new segment buffer.
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- Write how the acceleration counters work and why they are set at half via mid-point rule.
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- Determine if placing the position counters elsewhere (or change them to 8-bit variables that
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are added to the system position counters at the end of a segment) frees up cycles.
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- Write a blurb about how the acceleration should be handled within the ISR. All of the
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time/step/ramp counters accurately keep track of the remainders and phasing of the variables
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with time. This means we do not have to compute them via expensive floating point beforehand.
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- Need to do an analysis to determine if these counters are really that much cheaper. At least
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find out when it isn't anymore. Particularly when the ISR is at a very high frequency.
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*/
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ISR(TIMER2_COMPA_vect)
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{
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// SPINDLE_ENABLE_PORT ^= 1<<SPINDLE_ENABLE_BIT; // Debug: Used to time ISR
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if (busy) { return; } // The busy-flag is used to avoid reentering this interrupt
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// Pulse stepper port pins, if flagged. New block dir will always be set one timer tick
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// before any step pulse due to algorithm design.
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if (st.execute_step) {
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st.execute_step = false;
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STEPPING_PORT = ( STEPPING_PORT & ~(DIRECTION_MASK | STEP_MASK) ) | st.out_bits;
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TCNT0 = st.step_pulse_time; // Reload Timer0 counter.
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TCCR0B = (1<<CS21); // Begin Timer0. Full speed, 1/8 prescaler
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}
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busy = true;
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sei(); // Re-enable interrupts to allow Stepper Port Reset Interrupt to fire on-time.
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// NOTE: The remaining code in this ISR will finish before returning to main program.
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// If there is no step segment, attempt to pop one from the stepper buffer
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if (st.load_flag != LOAD_NOOP) {
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// Anything in the buffer? If so, load and initialize next step segment.
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if (segment_buffer_head != segment_buffer_tail) {
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// NOTE: Loads after a step event. At high rates above 1/2 ISR frequency, there is
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// a small chance that this will load at the same time as a step event. Hopefully,
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// the overhead for this loading event isn't too much.. possibly 2-5 usec.
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// NOTE: The stepper algorithm must control the planner buffer tail as it completes
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// the block moves. Otherwise, a feed hold can leave a few step buffer line moves
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// without the correct planner block information.
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st_current_segment = &segment_buffer[segment_buffer_tail];
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// Load number of steps to execute from stepper buffer
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st.segment_steps_remaining = st_current_segment->n_step;
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// Check if the counters need to be reset for a new planner block
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if (st.load_flag == LOAD_BLOCK) {
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pl_current_block = plan_get_current_block(); // Should always be there. Stepper buffer handles this.
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st_current_data = &segment_data[segment_buffer[segment_buffer_tail].st_data_index]; //st_current_segment->st_data_index];
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// Initialize direction bits for block
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st.out_bits = pl_current_block->direction_bits ^ settings.invert_mask;
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st.execute_step = true; // Set flag to set direction bits upon next ISR tick.
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// Initialize Bresenham line counters
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st.counter_x = (pl_current_block->step_event_count >> 1);
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st.counter_y = st.counter_x;
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st.counter_z = st.counter_x;
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// Initialize inverse time and step rate counter data
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st.counter_d = st_current_data->d_next; // d_next always greater than delta_d.
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if (st.delta_d < MINIMUM_STEP_RATE) { st.d_per_tick = MINIMUM_STEP_RATE; }
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else { st.d_per_tick = st.delta_d; }
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// During feed hold, do not update rate, ramp type, or ramp counters. Keep decelerating.
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// if (sys.state == STATE_CYCLE) {
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st.delta_d = st_current_data->initial_rate;
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st.ramp_count = ISR_TICKS_PER_ACCELERATION_TICK/2; // Initialize ramp counter via midpoint rule
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st.ramp_type = RAMP_NOOP_CRUISE; // Initialize as no ramp operation. Corrected later if necessary.
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// }
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}
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// Acceleration and cruise handled by ramping. Just check if deceleration needs to begin.
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if ( st_current_segment->flag & (SEGMENT_DECEL | SEGMENT_ACCEL) ) {
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/* Compute correct ramp count for a ramp change. Upon a switch from acceleration to deceleration,
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or vice-versa, the new ramp count must be set to trigger the next acceleration tick equal to
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the number of ramp ISR ticks counted since the last acceleration tick. This is ensures the
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ramp is executed exactly as the plan dictates. Otherwise, when a ramp begins from a known
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rate (nominal/cruise or initial), the ramp count must be set to ISR_TICKS_PER_ACCELERATION_TICK/2
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as mandated by the mid-point rule. For these conditions, the ramp count have been initialized
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such that the following computation is still correct. */
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st.ramp_count = ISR_TICKS_PER_ACCELERATION_TICK-st.ramp_count;
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if ( st_current_segment->flag & SEGMENT_DECEL ) { st.ramp_type = RAMP_DECEL; }
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else { st.ramp_type = RAMP_ACCEL; }
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}
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st.load_flag = LOAD_NOOP; // Segment motion loaded. Set no-operation flag to skip during execution.
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} else {
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// Can't discard planner block here if a feed hold stops in middle of block.
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st_go_idle();
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bit_true(sys.execute,EXEC_CYCLE_STOP); // Flag main program for cycle end
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return; // Nothing to do but exit.
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}
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}
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// Adjust inverse time counter for ac/de-celerations
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// NOTE: Accelerations are handled by the stepper algorithm as it's thought to be more computationally
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// efficient on the Arduino AVR. This could may not be true with higher ISR frequencies or faster CPUs.
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if (st.ramp_type) { // Ignored when ramp type is NOOP_CRUISE
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st.ramp_count--; // Tick acceleration ramp counter
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if (st.ramp_count == 0) { // Adjust step rate when its time
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if (st.ramp_type == RAMP_ACCEL) { // Adjust velocity for acceleration
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st.ramp_count = ISR_TICKS_PER_ACCELERATION_TICK; // Reload ramp counter
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st.delta_d += st_current_data->rate_delta;
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if (st.delta_d >= st_current_data->nominal_rate) { // Reached nominal rate.
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st.delta_d = st_current_data->nominal_rate; // Set cruising velocity
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st.ramp_type = RAMP_NOOP_CRUISE; // Set ramp flag to cruising
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st.ramp_count = ISR_TICKS_PER_ACCELERATION_TICK/2; // Re-initialize counter for next ramp.
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}
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} else { // Adjust velocity for deceleration.
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st.ramp_count = ISR_TICKS_PER_ACCELERATION_TICK; // Reload ramp counter
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if (st.delta_d > st_current_data->rate_delta) {
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st.delta_d -= st_current_data->rate_delta;
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} else { // Moving near zero feed rate. Gracefully slow down.
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st.delta_d >>= 1; // Integer divide by 2 until complete. Also prevents overflow.
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// TODO: Check for and handle feed hold exit? At this point, machine is stopped.
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// - Set system flag to recompute plan and reset segment buffer.
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// - Segment steps in buffer needs to be returned to planner correctly.
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// busy = false;
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// return;
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}
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}
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// Finalize adjusted step rate. Ensure minimum.
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if (st.delta_d < MINIMUM_STEP_RATE) { st.d_per_tick = MINIMUM_STEP_RATE; }
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else { st.d_per_tick = st.delta_d; }
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}
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}
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// Iterate inverse time counter. Triggers each Bresenham step event.
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st.counter_d -= st.d_per_tick;
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// Execute Bresenham step event, when it's time to do so.
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if (st.counter_d < 0) {
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st.counter_d += st_current_data->d_next; // Reload inverse time counter
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st.out_bits = pl_current_block->direction_bits; // Reset out_bits and reload direction bits
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st.execute_step = true;
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// Execute step displacement profile by Bresenham line algorithm
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st.counter_x -= pl_current_block->steps[X_AXIS];
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if (st.counter_x < 0) {
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st.out_bits |= (1<<X_STEP_BIT);
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st.counter_x += pl_current_block->step_event_count;
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// st.steps_x++;
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if (st.out_bits & (1<<X_DIRECTION_BIT)) { sys.position[X_AXIS]--; }
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else { sys.position[X_AXIS]++; }
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}
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st.counter_y -= pl_current_block->steps[Y_AXIS];
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if (st.counter_y < 0) {
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st.out_bits |= (1<<Y_STEP_BIT);
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st.counter_y += pl_current_block->step_event_count;
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// st.steps_y++;
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if (st.out_bits & (1<<Y_DIRECTION_BIT)) { sys.position[Y_AXIS]--; }
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else { sys.position[Y_AXIS]++; }
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}
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st.counter_z -= pl_current_block->steps[Z_AXIS];
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if (st.counter_z < 0) {
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st.out_bits |= (1<<Z_STEP_BIT);
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st.counter_z += pl_current_block->step_event_count;
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// st.steps_z++;
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if (st.out_bits & (1<<Z_DIRECTION_BIT)) { sys.position[Z_AXIS]--; }
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else { sys.position[Z_AXIS]++; }
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}
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// Check step events for trapezoid change or end of block.
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st.segment_steps_remaining--; // Decrement step events count
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if (st.segment_steps_remaining == 0) {
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/*
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NOTE: sys.position updates could be done here. The bresenham counters can have
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their own fast 8-bit addition-only counters. Here we would check the direction and
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apply it to sys.position accordingly. However, this could take too much time
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combined with loading a new segment during next cycle too.
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TODO: Measure the time it would take in the worst case. It could still be faster
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overall during segment execution if uint8 step counters tracked this and was added
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to the system position variables here. Compared to worst case now, it wouldn't be
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that much different.
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// TODO: Upon loading, step counters would need to be zeroed.
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// TODO: For feedrate overrides, we will have to execute add these values.. although
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// for probing, this breaks. Current values won't be correct, unless we query it.
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// It makes things more complicated, but still manageable.
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if (st.steps_x > 0) {
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if (st.out_bits & (1<<X_DIRECTION_BIT)) { sys.position[X_AXIS] += st.steps_x; }
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else { sys.position[X_AXIS] -= st.steps_x; }
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}
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if (st.steps_y > 0) {
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if (st.out_bits & (1<<Y_DIRECTION_BIT)) { sys.position[Y_AXIS] += st.steps_y; }
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|
else { sys.position[Y_AXIS] -= st.steps_y; }
|
|
}
|
|
if (st.steps_z > 0) {
|
|
if (st.out_bits & (1<<Z_DIRECTION_BIT)) { sys.position[Z_AXIS] += st.steps_z; }
|
|
else { sys.position[Z_AXIS] -= st.steps_z; }
|
|
}
|
|
*/
|
|
|
|
// Line move is complete, set load line flag to check for new move.
|
|
// Check if last line move in planner block. Discard if so.
|
|
if (st_current_segment->flag & SEGMENT_END_OF_BLOCK) {
|
|
plan_discard_current_block();
|
|
st.load_flag = LOAD_BLOCK;
|
|
} else {
|
|
st.load_flag = LOAD_SEGMENT;
|
|
}
|
|
|
|
// Discard current segment by advancing buffer tail index
|
|
if ( ++segment_buffer_tail == SEGMENT_BUFFER_SIZE) { segment_buffer_tail = 0; }
|
|
|
|
}
|
|
|
|
st.out_bits ^= settings.invert_mask; // Apply step port invert mask
|
|
}
|
|
busy = false;
|
|
// SPINDLE_ENABLE_PORT ^= 1<<SPINDLE_ENABLE_BIT;
|
|
}
|
|
|
|
|
|
// The Stepper Port Reset Interrupt: Timer0 OVF interrupt handles the falling edge of the step
|
|
// pulse. This should always trigger before the next Timer2 COMPA interrupt and independently
|
|
// finish, if Timer2 is disabled after completing a move.
|
|
ISR(TIMER0_OVF_vect)
|
|
{
|
|
STEPPING_PORT = (STEPPING_PORT & ~STEP_MASK) | (settings.invert_mask & STEP_MASK);
|
|
TCCR0B = 0; // Disable timer until needed.
|
|
}
|
|
|
|
|
|
// Reset and clear stepper subsystem variables
|
|
void st_reset()
|
|
{
|
|
memset(&st, 0, sizeof(st));
|
|
|
|
st.load_flag = LOAD_BLOCK;
|
|
busy = false;
|
|
|
|
pl_current_block = NULL; // Planner block pointer used by stepper algorithm
|
|
pl_prep_block = NULL; // Planner block pointer used by segment buffer
|
|
pl_prep_index = 0; // Planner buffer indices are also reset to zero.
|
|
st_data_prep_index = 0;
|
|
|
|
segment_buffer_tail = 0;
|
|
segment_buffer_head = 0; // empty = tail
|
|
segment_next_head = 1;
|
|
|
|
pl_partial_block_flag = false;
|
|
}
|
|
|
|
|
|
// Initialize and start the stepper motor subsystem
|
|
void st_init()
|
|
{
|
|
// Configure directions of interface pins
|
|
STEPPING_DDR |= STEPPING_MASK;
|
|
STEPPING_PORT = (STEPPING_PORT & ~STEPPING_MASK) | settings.invert_mask;
|
|
STEPPERS_DISABLE_DDR |= 1<<STEPPERS_DISABLE_BIT;
|
|
|
|
// Configure Timer 2
|
|
TIMSK2 &= ~(1<<OCIE2A); // Disable Timer2 interrupt while configuring it
|
|
TCCR2B = 0; // Disable Timer2 until needed
|
|
TCNT2 = 0; // Clear Timer2 counter
|
|
TCCR2A = (1<<WGM21); // Set CTC mode
|
|
OCR2A = (F_CPU/ISR_TICKS_PER_SECOND)/8 - 1; // Set Timer2 CTC rate
|
|
|
|
// Configure Timer 0
|
|
TIMSK0 &= ~(1<<TOIE0);
|
|
TCCR0A = 0; // Normal operation
|
|
TCCR0B = 0; // Disable Timer0 until needed
|
|
TIMSK0 |= (1<<TOIE0); // Enable overflow interrupt
|
|
|
|
// Start in the idle state, but first wake up to check for keep steppers enabled option.
|
|
st_wake_up();
|
|
st_go_idle();
|
|
}
|
|
|
|
|
|
// Planner external interface to start stepper interrupt and execute the blocks in queue. Called
|
|
// by the main program functions: planner auto-start and run-time command execution.
|
|
void st_cycle_start()
|
|
{
|
|
if (sys.state == STATE_QUEUED) {
|
|
sys.state = STATE_CYCLE;
|
|
st_wake_up();
|
|
}
|
|
}
|
|
|
|
|
|
// Execute a feed hold with deceleration, only during cycle. Called by main program.
|
|
void st_feed_hold()
|
|
{
|
|
if (sys.state == STATE_CYCLE) {
|
|
sys.state = STATE_HOLD;
|
|
sys.auto_start = false; // Disable planner auto start upon feed hold.
|
|
}
|
|
}
|
|
|
|
|
|
// Reinitializes the cycle plan and stepper system after a feed hold for a resume. Called by
|
|
// runtime command execution in the main program, ensuring that the planner re-plans safely.
|
|
// NOTE: Bresenham algorithm variables are still maintained through both the planner and stepper
|
|
// cycle reinitializations. The stepper path should continue exactly as if nothing has happened.
|
|
// Only the planner de/ac-celerations profiles and stepper rates have been updated.
|
|
void st_cycle_reinitialize()
|
|
{
|
|
// if (pl_current_block != NULL) {
|
|
// Replan buffer from the feed hold stop location.
|
|
|
|
// TODO: Need to add up all of the step events in the current planner block to give
|
|
// back to the planner. Should only need it for the current block.
|
|
// BUT! The planner block millimeters is all changed and may be changed into the next
|
|
// planner block. The block millimeters would need to be recalculated via step counts
|
|
// and the mm/step variable.
|
|
// OR. Do we plan the feed hold itself down with the planner.
|
|
|
|
// plan_cycle_reinitialize(st_current_data->step_events_remaining);
|
|
// st.ramp_type = RAMP_ACCEL;
|
|
// st.ramp_count = ISR_TICKS_PER_ACCELERATION_TICK/2;
|
|
// st.delta_d = 0;
|
|
// sys.state = STATE_QUEUED;
|
|
// } else {
|
|
// sys.state = STATE_IDLE;
|
|
// }
|
|
sys.state = STATE_IDLE;
|
|
|
|
}
|
|
|
|
|
|
/* Prepares step segment buffer. Continuously called from main program.
|
|
|
|
The segment buffer is an intermediary buffer interface between the execution of steps
|
|
by the stepper algorithm and the velocity profiles generated by the planner. The stepper
|
|
algorithm only executes steps within the segment buffer and is filled by the main program
|
|
when steps are "checked-out" from the first block in the planner buffer. This keeps the
|
|
step execution and planning optimization processes atomic and protected from each other.
|
|
The number of steps "checked-out" from the planner buffer and the number of segments in
|
|
the segment buffer is sized and computed such that no operation in the main program takes
|
|
longer than the time it takes the stepper algorithm to empty it before refilling it.
|
|
Currently, the segment buffer conservatively holds roughly up to 40-60 msec of steps.
|
|
|
|
NOTE: The segment buffer executes a set number of steps over an approximate time period.
|
|
If we try to execute over a set time period, it is difficult to guarantee or predict how
|
|
many steps will execute over it, especially when the step pulse phasing between the
|
|
neighboring segments are kept consistent. Meaning that, if the last segment step pulses
|
|
right before its end, the next segment must delay its first pulse so that the step pulses
|
|
are consistently spaced apart over time to keep the step pulse train nice and smooth.
|
|
Keeping track of phasing and ensuring that the exact number of steps are executed as
|
|
defined by the planner block, the related computational overhead gets quickly and
|
|
prohibitively expensive, especially in real-time.
|
|
Since the stepper algorithm automatically takes care of the step pulse phasing with
|
|
its ramp and inverse time counters, we don't have to explicitly and expensively track the
|
|
exact number of steps, time, or phasing of steps. All we need to do is approximate
|
|
the number of steps in each segment such that the segment buffer has enough execution time
|
|
for the main program to do what it needs to do and refill it when it has time. In other
|
|
words, we just need to compute a cheap approximation of the current velocity and the
|
|
number of steps over it.
|
|
*/
|
|
|
|
/*
|
|
TODO: Figure out how to enforce a deceleration when a feedrate override is reduced.
|
|
The problem is that when an override is reduced, the planner may not plan back to
|
|
the current rate. Meaning that the velocity profiles for certain conditions no longer
|
|
are trapezoidal or triangular. For example, if the current block is cruising at a
|
|
nominal rate and the feedrate override is reduced, the new nominal rate will now be
|
|
lower. The velocity profile must first decelerate to the new nominal rate and then
|
|
follow on the new plan. So the remaining velocity profile will have a decelerate,
|
|
cruise, and another decelerate.
|
|
Another issue is whether or not a feedrate override reduction causes a deceleration
|
|
that acts over several planner blocks. For example, say that the plan is already
|
|
heavily decelerating throughout it, reducing the feedrate will not do much to it. So,
|
|
how do we determine when to resume the new plan? How many blocks do we have to wait
|
|
until the new plan intersects with the deceleration curve? One plus though, the
|
|
deceleration will never be more than the number of blocks in the entire planner buffer,
|
|
but it theoretically can be equal to it when all planner blocks are decelerating already.
|
|
*/
|
|
void st_prep_buffer()
|
|
{
|
|
while (segment_buffer_tail != segment_next_head) { // Check if we need to fill the buffer.
|
|
|
|
// Initialize new segment
|
|
st_segment_t *prep_segment = &segment_buffer[segment_buffer_head];
|
|
prep_segment->flag = SEGMENT_NOOP;
|
|
|
|
// Determine if we need to load a new planner block.
|
|
if (pl_prep_block == NULL) {
|
|
pl_prep_block = plan_get_block_by_index(pl_prep_index); // Query planner for a queued block
|
|
if (pl_prep_block == NULL) { return; } // No planner blocks. Exit.
|
|
|
|
// Increment stepper common data index
|
|
if ( ++st_data_prep_index == (SEGMENT_BUFFER_SIZE-1) ) { st_data_prep_index = 0; }
|
|
|
|
// Check if the planner has re-computed this block mid-execution. If so, push the previous segment
|
|
// data. Otherwise, prepare a new segment data for the new planner block.
|
|
if (pl_partial_block_flag) {
|
|
|
|
// Prepare new shared segment block data and copy the relevant last segment block data.
|
|
st_data_t *last_st_prep_data;
|
|
last_st_prep_data = st_prep_data;
|
|
st_prep_data = &segment_data[st_data_prep_index];
|
|
|
|
st_prep_data->step_events_remaining = last_st_prep_data->step_events_remaining;
|
|
st_prep_data->rate_delta = last_st_prep_data->rate_delta;
|
|
st_prep_data->d_next = last_st_prep_data->d_next;
|
|
st_prep_data->nominal_rate = last_st_prep_data->nominal_rate; // TODO: Feedrate overrides recomputes this.
|
|
|
|
st_prep_data->mm_per_step = last_st_prep_data->mm_per_step;
|
|
|
|
pl_partial_block_flag = false; // Reset flag
|
|
|
|
} else {
|
|
|
|
// Prepare commonly shared planner block data for the ensuing segment buffer moves ad-hoc, since
|
|
// the planner buffer can dynamically change the velocity profile data as blocks are added.
|
|
st_prep_data = &segment_data[st_data_prep_index];
|
|
|
|
// Initialize Bresenham variables
|
|
st_prep_data->step_events_remaining = pl_prep_block->step_event_count;
|
|
|
|
// Convert planner block velocity profile data to stepper rate and step distance data.
|
|
st_prep_data->nominal_rate = ceil(sqrt(pl_prep_block->nominal_speed_sqr)*(INV_TIME_MULTIPLIER/(60.0*ISR_TICKS_PER_SECOND))); // (mult*mm/isr_tic)
|
|
st_prep_data->rate_delta = ceil(pl_prep_block->acceleration*
|
|
((INV_TIME_MULTIPLIER/(60.0*60.0))/(ISR_TICKS_PER_SECOND*ACCELERATION_TICKS_PER_SECOND))); // (mult*mm/isr_tic/accel_tic)
|
|
st_prep_data->d_next = ceil((pl_prep_block->millimeters*INV_TIME_MULTIPLIER)/pl_prep_block->step_event_count); // (mult*mm/step)
|
|
|
|
// TODO: Check if we really need to store this.
|
|
st_prep_data->mm_per_step = pl_prep_block->millimeters/pl_prep_block->step_event_count;
|
|
|
|
}
|
|
|
|
// Convert planner entry speed to stepper initial rate.
|
|
st_prep_data->initial_rate = ceil(sqrt(pl_prep_block->entry_speed_sqr)*(INV_TIME_MULTIPLIER/(60.0*ISR_TICKS_PER_SECOND))); // (mult*mm/isr_tic)
|
|
|
|
// TODO: Nominal rate changes with feedrate override.
|
|
// st_prep_data->nominal_rate = ceil(sqrt(pl_prep_block->nominal_speed_sqr)*(INV_TIME_MULTIPLIER/(60.0*ISR_TICKS_PER_SECOND))); // (mult*mm/isr_tic)
|
|
|
|
st_prep_data->current_approx_rate = st_prep_data->initial_rate;
|
|
|
|
// Calculate the planner block velocity profile type, determine deceleration point, and initial ramp.
|
|
float mm_decelerate_after = plan_calculate_velocity_profile(pl_prep_index);
|
|
st_prep_data->decelerate_after = ceil( mm_decelerate_after/st_prep_data->mm_per_step );
|
|
if (st_prep_data->decelerate_after > 0) { // If 0, SEGMENT_DECEL flag is set later.
|
|
if (st_prep_data->initial_rate != st_prep_data->nominal_rate) { prep_segment->flag = SEGMENT_ACCEL; }
|
|
}
|
|
}
|
|
|
|
// Set new segment to point to the current segment data block.
|
|
prep_segment->st_data_index = st_data_prep_index;
|
|
|
|
// Approximate the velocity over the new segment using the already computed rate values.
|
|
// NOTE: This assumes that each segment will have an execution time roughly equal to every ACCELERATION_TICK.
|
|
// We do this to minimize memory and computational requirements. However, this could easily be replaced with
|
|
// a more exact approximation or have a unique time per segment, if CPU and memory overhead allows.
|
|
if (st_prep_data->decelerate_after <= 0) {
|
|
if (st_prep_data->decelerate_after == 0) { prep_segment->flag = SEGMENT_DECEL; } // Set segment deceleration flag
|
|
else { st_prep_data->current_approx_rate -= st_prep_data->rate_delta; }
|
|
if (st_prep_data->current_approx_rate < st_prep_data->rate_delta) { st_prep_data->current_approx_rate >>= 1; }
|
|
} else {
|
|
if (st_prep_data->current_approx_rate < st_prep_data->nominal_rate) {
|
|
st_prep_data->current_approx_rate += st_prep_data->rate_delta;
|
|
if (st_prep_data->current_approx_rate > st_prep_data->nominal_rate) {
|
|
st_prep_data->current_approx_rate = st_prep_data->nominal_rate;
|
|
}
|
|
}
|
|
}
|
|
|
|
// Compute the number of steps in the prepped segment based on the approximate current rate.
|
|
// NOTE: The d_next divide cancels out the INV_TIME_MULTIPLIER and converts the rate value to steps.
|
|
prep_segment->n_step = ceil(max(MINIMUM_STEP_RATE,st_prep_data->current_approx_rate)*
|
|
(ISR_TICKS_PER_SECOND/ACCELERATION_TICKS_PER_SECOND)/st_prep_data->d_next);
|
|
// NOTE: Ensures it moves for very slow motions, but MINIMUM_STEP_RATE should always set this too. Perhaps
|
|
// a compile-time check to see if MINIMUM_STEP_RATE is set high enough is all that is needed.
|
|
prep_segment->n_step = max(prep_segment->n_step,MINIMUM_STEPS_PER_SEGMENT);
|
|
// NOTE: As long as the ACCELERATION_TICKS_PER_SECOND is valid, n_step should never exceed 255 and overflow.
|
|
// prep_segment->n_step = min(prep_segment->n_step,MAXIMUM_STEPS_PER_BLOCK); // Prevent unsigned int8 overflow.
|
|
|
|
// Check if n_step exceeds steps remaining in planner block. If so, truncate.
|
|
if (prep_segment->n_step > st_prep_data->step_events_remaining) {
|
|
prep_segment->n_step = st_prep_data->step_events_remaining;
|
|
}
|
|
|
|
// Check if n_step crosses decelerate point in block. If so, truncate to ensure the deceleration
|
|
// ramp counters are set correctly during execution.
|
|
if (st_prep_data->decelerate_after > 0) {
|
|
if (prep_segment->n_step > st_prep_data->decelerate_after) {
|
|
prep_segment->n_step = st_prep_data->decelerate_after;
|
|
}
|
|
}
|
|
|
|
// Update stepper common data variables.
|
|
st_prep_data->decelerate_after -= prep_segment->n_step;
|
|
st_prep_data->step_events_remaining -= prep_segment->n_step;
|
|
|
|
// Check for end of planner block
|
|
if ( st_prep_data->step_events_remaining == 0 ) {
|
|
// Set EOB bitflag so stepper algorithm discards the planner block after this segment completes.
|
|
prep_segment->flag |= SEGMENT_END_OF_BLOCK;
|
|
// Move planner pointer to next block and flag to load a new block for the next segment.
|
|
pl_prep_index = plan_next_block_index(pl_prep_index);
|
|
pl_prep_block = NULL;
|
|
}
|
|
|
|
// New step segment completed. Increment segment buffer indices.
|
|
segment_buffer_head = segment_next_head;
|
|
if ( ++segment_next_head == SEGMENT_BUFFER_SIZE ) { segment_next_head = 0; }
|
|
|
|
// long a = prep_segment->n_step;
|
|
// printInteger(a);
|
|
// printString(" ");
|
|
|
|
}
|
|
}
|
|
|
|
uint8_t st_get_prep_block_index()
|
|
{
|
|
// Returns only the index but doesn't state if the block has been partially executed. How do we simply check for this?
|
|
return(pl_prep_index);
|
|
}
|
|
|
|
void st_fetch_partial_block_parameters(uint8_t block_index, float *millimeters_remaining, uint8_t *is_decelerating)
|
|
{
|
|
// if called, can we assume that this always changes and needs to be updated? if so, then
|
|
// we can perform all of the segment buffer setup tasks here to make sure the next time
|
|
// the segments are loaded, the st_data buffer is updated correctly.
|
|
// !!! Make sure that this is always pointing to the correct st_prep_data block.
|
|
|
|
// When a mid-block acceleration occurs, we have to make sure the ramp counters are updated
|
|
// correctly, much in the same fashion as the deceleration counters. Need to think about this
|
|
// make sure this is right, but i'm pretty sure it is.
|
|
|
|
// TODO: NULL means that the segment buffer has just completed a planner block. Clean up!
|
|
if (pl_prep_block != NULL) {
|
|
*millimeters_remaining = st_prep_data->step_events_remaining*st_prep_data->mm_per_step;
|
|
if (st_prep_data->decelerate_after > 0) { *is_decelerating = false; }
|
|
else { *is_decelerating = true; }
|
|
|
|
// Flag for new prep_block when st_prep_buffer() is called after the planner recomputes.
|
|
pl_partial_block_flag = true;
|
|
pl_prep_block = NULL;
|
|
}
|
|
return;
|
|
}
|