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grbllib.c
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902 lines (694 loc) · 24.9 KB
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/*
grbllib.c - An embedded CNC Controller with rs274/ngc (g-code) support
Part of grblHAL
Copyright (c) 2017-2026 Terje Io
Copyright (c) 2011-2015 Sungeun K. Jeon
Copyright (c) 2009-2011 Simen Svale Skogsrud
grblHAL is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
grblHAL is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with grblHAL. If not, see <http://www.gnu.org/licenses/>.
*/
#include <string.h>
#include <stdlib.h>
#include <assert.h>
#include "hal.h"
#include "nuts_bolts.h"
#include "tool_change.h"
#include "override.h"
#include "protocol.h"
#include "machine_limits.h"
#include "report.h"
#include "state_machine.h"
#include "nvs_buffer.h"
#include "stream.h"
#if NGC_EXPRESSIONS_ENABLE
#include "ngc_expr.h"
#endif
#if ENABLE_BACKLASH_COMPENSATION
#include "motion_control.h"
#endif
#ifdef KINEMATICS_API
#include "kinematics.h"
#endif
#if COREXY
#include "kinematics/corexy.h"
#endif
#if WALL_PLOTTER
#include "kinematics/wall_plotter.h"
#endif
#if DELTA_ROBOT
#include "kinematics/delta.h"
#endif
#if POLAR_ROBOT
#include "kinematics/polar.h"
#endif
static void task_execute (sys_state_t state);
typedef union {
uint8_t ok;
struct {
uint8_t init :1,
setup :1,
spindle :1,
amass :1,
pulse_delay :1,
unused :3;
};
} driver_startup_t;
#ifndef CORE_TASK_POOL_SIZE
#define CORE_TASK_POOL_SIZE 40
#endif
typedef struct core_task {
uint32_t time;
foreground_task_ptr fn;
void *data;
struct core_task *next;
} core_task_t;
DCRAM system_t sys; //!< System global variable structure.
DCRAM grbl_t grbl;
DCRAM grbl_hal_t hal;
static driver_startup_t driver = { .ok = 0xFF };
static on_linestate_changed_ptr on_linestate_changed;
static settings_changed_ptr hal_settings_changed;
static stepper_enable_ptr stepper_enable;
DCRAM static struct {
volatile core_task_t *immediate; //!< Pointer to first entry of linked list of tasks to run immediately.
volatile core_task_t *delayed; //!< Pointer to first entry of linked list of delayed tasks to run, in execution order.
volatile core_task_t *systick; //!< Pointer to first entry of linked list of systick (1 ms) tasks to run.
volatile core_task_t *on_booted; //!< Pointer to first entry of linked list of tasks to run once on cold boot.
volatile core_task_t *on_reset; //!< Pointer to first entry of linked list of tasks to on soft reset.
volatile core_task_t *last_freed; //!< Pointer to last freed task.
core_task_t pool[CORE_TASK_POOL_SIZE];
} tasks;
#ifdef KINEMATICS_API
kinematics_t kinematics;
#endif
__attribute__((weak)) void board_ports_init (void)
{
// NOOP
}
__attribute__((always_inline)) static inline void task_free (core_task_t *task)
{
task->fn = NULL;
task->next = NULL;
if(tasks.last_freed == NULL)
tasks.last_freed = task;
}
__attribute__((always_inline)) static inline core_task_t *task_run (core_task_t *task)
{
hal.irq_disable();
core_task_t *t = task;
foreground_task_ptr fn = task->fn;
void *data = task->data;
task = task->next;
task_free(t);
hal.irq_enable();
fn(data);
return task;
}
void dummy_bool_handler (bool arg)
{
// NOOP
}
void reset_handler (void)
{
report_init_fns();
grbl.on_macro_return = NULL;
}
static bool dummy_irq_claim (irq_type_t irq, uint_fast8_t id, irq_callback_ptr callback)
{
return false;
}
FLASHMEM static void report_driver_error (void *data)
{
char msg[40];
driver.ok = ~driver.ok;
strcpy(msg, "Fatal: Incompatible driver (");
strcat(msg, uitoa(driver.ok));
strcat(msg, ")");
report_message(msg, Message_Plain);
}
static void auto_realtime_report (void *data);
static void realtime_report_check (void *data)
{
task_add_delayed(sys.flags.auto_reporting ? auto_realtime_report : realtime_report_check, NULL, settings.report_interval);
}
static void auto_realtime_report (void *data)
{
if(sys.flags.auto_reporting) {
system_set_exec_state_flag(EXEC_STATUS_REPORT);
task_add_delayed(auto_realtime_report, NULL, settings.report_interval);
} else if(settings.report_interval)
task_add_delayed(realtime_report_check, NULL, settings.report_interval);
}
// "Wire" homing signals to limit signals, used when max limit inputs not available.
ISR_CODE static home_signals_t ISR_FUNC(get_homing_status)(void)
{
home_signals_t home;
limit_signals_t limits = hal.limits.get_state();
home.a.value = limits.min.value;
home.b.value = limits.min2.value;
return home;
}
// "Wire" homing signals to limit signals, used when max limit inputs available.
ISR_CODE static home_signals_t ISR_FUNC(get_homing_status2)(void)
{
home_signals_t home;
limit_signals_t source = xbar_get_homing_source(), limits = hal.limits.get_state();
home.a.value = (limits.min.value & source.min.mask) | (limits.max.value & source.max.mask);
home.b.value = (limits.min2.value & source.min2.mask) | (limits.max2.value & source.max2.mask);
return home;
}
FLASHMEM static void output_welcome_message (void *data)
{
grbl.report.init_message(hal.stream.write);
}
FLASHMEM static void onLinestateChanged (serial_linestate_t state)
{
if(state.dtr) {
task_delete(output_welcome_message, NULL);
task_add_delayed(output_welcome_message, NULL, 200);
}
if(on_linestate_changed)
on_linestate_changed(state);
}
FLASHMEM static void stepperEnable (axes_signals_t enable, bool hold)
{
if(stepper_enable)
stepper_enable(enable, hold);
sys.steppers_enabled = /*!hold &&*/ enable.bits == AXES_BITMASK;
}
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wdiscarded-qualifiers"
#endif
FLASHMEM static void print_pos_msg (void *data)
{
hal.stream.write("grblHAL: power on self-test (POS) failed!" ASCII_EOL);
if(tasks.on_booted) do {
} while((tasks.on_booted = task_run(tasks.on_booted)));
}
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif
FLASHMEM static void onPosFailure (serial_linestate_t state)
{
if(state.dtr) // delay a bit to let the USB stack come up
task_add_delayed(print_pos_msg, NULL, 50);
}
FLASHMEM static bool onProbeToolsetter (tool_data_t *tool, coord_data_t *position, bool at_g59_3, bool on)
{
bool ok = false;
if(at_g59_3 && settings.probe.toolsetter_auto_select)
ok = hal.probe.select(on ? Probe_Toolsetter : Probe_Default);
return ok;
}
FLASHMEM static void tool_changed (tool_data_t *tool)
{
if(settings.flags.tool_persistent && tool->tool_id != settings.tool_id) {
settings.tool_id = tool->tool_id;
settings_write_global();
}
}
FLASHMEM static void settings_changed (settings_t *settings, settings_changed_flags_t changed)
{
hal_settings_changed(settings, changed);
if(grbl.on_settings_changed)
grbl.on_settings_changed(settings, changed);
}
FLASHMEM static atc_status_t atc_get_state (void)
{
return hal.driver_cap.atc ? ATC_Online : ATC_None;
}
// main entry point
FLASHMEM int grbl_enter (void)
{
assert(NVS_ADDR_PARAMETERS + N_CoordinateSystems * (sizeof(coord_data_t) + NVS_CRC_BYTES) < NVS_ADDR_STARTUP_BLOCK);
assert(NVS_ADDR_STARTUP_BLOCK + N_STARTUP_LINE * (sizeof(stored_line_t) + NVS_CRC_BYTES) < NVS_ADDR_BUILD_INFO);
bool looping = true;
memset(&sys, 0, sizeof(system_t));
memset(&tasks, 0, sizeof(tasks));
// Clear all and set some core function pointers
memset(&grbl, 0, sizeof(grbl_t));
grbl.on_execute_realtime = grbl.on_execute_delay = task_execute;
grbl.enqueue_gcode = protocol_enqueue_gcode;
grbl.enqueue_realtime_command = stream_enqueue_realtime_command;
grbl.on_report_options = dummy_bool_handler;
grbl.on_report_command_help = system_command_help;
grbl.on_get_alarms = alarms_get_details;
grbl.on_get_errors = errors_get_details;
grbl.on_get_settings = settings_get_details;
grbl.on_tool_changed = tool_changed;
#if NGC_EXPRESSIONS_ENABLE
grbl.on_process_gcode_comment = ngc_process_comment;
#endif
// Clear all and set some HAL function pointers
memset(&hal, 0, sizeof(grbl_hal_t));
hal.version = HAL_VERSION; // Update when signatures and/or contract is changed - driver_init() should fail
hal.driver_reset = reset_handler;
hal.irq_enable = dummy_handler;
hal.irq_disable = dummy_handler;
hal.irq_claim = dummy_irq_claim;
hal.nvs.size = GRBL_NVS_SIZE;
hal.step_us_min = 2.0f;
hal.coolant_cap.flood = On;
hal.limits.interrupt_callback = limit_interrupt_handler;
hal.control.interrupt_callback = control_interrupt_handler;
hal.stepper.interrupt_callback = stepper_driver_interrupt_handler;
hal.stream_blocking_callback = stream_tx_blocking;
hal.tool.atc_get_state = atc_get_state;
hal.signals_pullup_disable_cap.value = (uint16_t)-1;
sys.cold_start = true;
limits_init();
settings_clear();
report_init_fns();
#ifdef KINEMATICS_API
memset(&kinematics, 0, sizeof(kinematics_t));
#endif
driver.init = driver_init();
#if NVSDATA_BUFFER_ENABLE
nvs_buffer_alloc(); // Allocate memory block for NVS buffer
#endif
#ifdef DEBUGOUT
debug_stream_init();
#endif
#if COMPATIBILITY_LEVEL > 0
hal.stream.suspend_read = NULL;
#endif
#ifdef NO_SAFETY_DOOR_SUPPORT
hal.signals_cap.safety_door_ajar = Off;
#endif
#if COREXY
corexy_init();
#endif
#if WALL_PLOTTER
wall_plotter_init();
#endif
#if DELTA_ROBOT
delta_robot_init();
#endif
#if POLAR_ROBOT
polar_init();
#endif
#if NVSDATA_BUFFER_ENABLE
nvs_buffer_init();
#endif
settings_init(); // Load settings from non-volatile storage
memset(sys.position, 0, sizeof(sys.position)); // Clear machine position.
// check and configure driver
stepper_enable = hal.stepper.enable;
hal.stepper.enable = stepperEnable;
#if ADAPTIVE_MULTI_AXIS_STEP_SMOOTHING
driver.amass = hal.driver_cap.amass_level >= MAX_AMASS_LEVEL;
hal.driver_cap.amass_level = MAX_AMASS_LEVEL;
#else
hal.driver_cap.amass_level = 0;
#endif
#ifdef DEFAULT_STEP_PULSE_DELAY
driver.pulse_delay = hal.driver_cap.step_pulse_delay;
#endif
/*
#if AXIS_N_SETTINGS > 4
driver_ok = driver_ok & hal.driver_cap.axes >= AXIS_N_SETTINGS;
#endif
*/
sys.mpg_mode = false;
if((sys.ioinit_pending = driver.ok == 0xFF)) {
hal_settings_changed = hal.settings_changed;
hal.settings_changed = settings_changed;
driver.setup = hal.driver_setup(&settings);
sys.ioinit_pending = false;
}
spindle_id_t spindle_id, encoder_spindle;
// Sanity checks
if(!spindle_get_id(settings.spindle.ref_id, &spindle_id)) {
spindle_ptrs_t *spindle = spindle_get_hal(spindle_get_default(), SpindleHAL_Raw);
spindle_id = spindle ? spindle->id : 0;
settings.spindle.ref_id = spindle ? spindle->ref_id : DEFAULT_SPINDLE;
}
if(!spindle_get_id(settings.spindle.encoder_spindle, &encoder_spindle))
settings.spindle.encoder_spindle = settings.spindle.ref_id;
//
if((driver.spindle = spindle_select(spindle_id))) {
spindle_ptrs_t *spindle = spindle_get(0);
driver.spindle = spindle->get_pwm == NULL || spindle->update_pwm != NULL;
} else
driver.spindle = spindle_select(spindle_add_null());
if(!hal.driver_cap.sd_card)
settings.macro_atc_flags.error_on_no_macro = Off;
if(driver.ok != 0xFF) {
sys.alarm = Alarm_SelftestFailed;
task_run_on_startup(report_driver_error, NULL);
}
hal.stepper.enable(settings.steppers.energize, true);
spindle_all_off(true);
hal.coolant.set_state((coolant_state_t){0});
if(hal.get_position)
hal.get_position(&sys.position); // TODO: restore on abort when returns true?
#if ENABLE_BACKLASH_COMPENSATION
mc_backlash_init((axes_signals_t){AXES_BITMASK});
#endif
sys.driver_started = sys.alarm != Alarm_SelftestFailed;
// "Wire" homing switches to limit switches if not provided by the driver.
if(hal.homing.get_state == NULL || settings.homing.flags.use_limit_switches)
hal.homing.get_state = hal.limits_cap.max.mask ? get_homing_status2 : get_homing_status;
if(settings.report_interval)
task_add_delayed(auto_realtime_report, NULL, settings.report_interval);
if(hal.driver_cap.sd_card || hal.driver_cap.littlefs) {
fs_options_t fs_options = { .hierarchical_listing = On };
fs_options.lfs_hidden = hal.driver_cap.littlefs;
fs_options.sd_mount_on_boot = hal.driver_cap.sd_card;
setting_remove_elements(Setting_FSOptions, fs_options.mask, true);
}
if(hal.stream.state.linestate_event && !hal.stream.state.passthru) {
on_linestate_changed = hal.stream.on_linestate_changed;
hal.stream.on_linestate_changed = onLinestateChanged;
}
if(grbl.on_probe_toolsetter == NULL && hal.driver_cap.toolsetter && hal.probe.select)
grbl.on_probe_toolsetter = onProbeToolsetter;
if(hal.driver_cap.probe && hal.signals_cap.probe_disconnected)
task_run_on_startup(probe_connected_event, hal.control.get_state().probe_disconnected ? NULL : (void *)1);
// Initialization loop upon power-up or a system abort. For the latter, all processes
// will return to this loop to be cleanly re-initialized.
while(looping) {
spindle_num_t spindle_num = N_SYS_SPINDLE;
// Reset report entry points
report_init_fns();
overrides_t override;
memcpy(&override, &sys.override, sizeof(overrides_t));
if(!sys.position_lost || settings.homing.flags.keep_on_reset)
memset(&sys, 0, offsetof(system_t, homed)); // Clear system variables except alarm & homed status.
else
memset(&sys, 0, offsetof(system_t, alarm)); // Clear system variables except state & alarm.
sys.var5399 = -2; // Clear last M66 result
sys.override.feed_rate = sys.cold_start || !settings.flags.keep_feed_override_on_reset ? DEFAULT_FEED_OVERRIDE : override.feed_rate;
sys.override.rapid_rate = sys.cold_start || !settings.flags.keep_rapids_override_on_reset ? DEFAULT_RAPID_OVERRIDE : override.rapid_rate;
do {
if(spindle_is_enabled(--spindle_num))
spindle_get(spindle_num)->param->override_pct = DEFAULT_SPINDLE_RPM_OVERRIDE; // Set to 100%
} while(spindle_num);
sys.flags.auto_reporting = settings.report_interval != 0;
if(settings.parking.flags.enabled)
sys.override.control.parking_disable = settings.parking.flags.deactivate_upon_init;
flush_override_buffers();
// Reset primary systems.
hal.stream.reset_read_buffer(); // Clear input stream buffer
gc_init(settings.flags.keep_offsets_on_reset); // Set g-code parser to default state
hal.limits.enable(settings.limits.flags.hard_enabled, (axes_signals_t){0});
plan_reset(); // Clear block buffer and planner variables
st_reset(); // Clear stepper subsystem variables.
limits_set_homing_axes(); // Set axes to be homed from settings.
system_init_switches(); // Set switches from inputs.
// Sync cleared gcode and planner positions to current system position.
sync_position();
if(hal.stepper.disable_motors)
hal.stepper.disable_motors((axes_signals_t){0}, SquaringMode_Both);
if(!hal.driver_cap.atc)
tc_init();
// Print welcome message. Indicates an initialization has occurred at power-up or with a reset.
grbl.report.init_message(hal.stream.write_all);
if(!settings.flags.no_unlock_after_estop && state_get() == STATE_ESTOP)
state_set(STATE_ALARM);
if(hal.driver_cap.mpg_mode)
protocol_enqueue_realtime_command(sys.mpg_mode ? CMD_STATUS_REPORT_ALL : CMD_STATUS_REPORT);
if(tasks.on_reset)
system_set_exec_state_flag(EXEC_RT_COMMAND); // execute any reset tasks
// Start main loop. Processes program inputs and executes them.
if(!(looping = protocol_main_loop()))
looping = hal.driver_release == NULL || hal.driver_release();
sys.cold_start = false;
}
nvs_buffer_free();
return 0;
}
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wdiscarded-qualifiers"
#endif
__attribute__((always_inline)) static inline core_task_t *task_alloc (void)
{
core_task_t *task = NULL;
uint_fast8_t idx = CORE_TASK_POOL_SIZE;
if(tasks.last_freed) {
task = tasks.last_freed;
tasks.last_freed = NULL;
} else do {
if(tasks.pool[--idx].fn == NULL)
task = &tasks.pool[idx];
} while(task == NULL && idx);
return task;
}
static void task_execute (sys_state_t state)
{
static uint32_t last_ms = 0;
static volatile bool lock = false;
core_task_t *task;
if(tasks.immediate && sys.driver_started) {
hal.irq_disable();
if((task = tasks.immediate))
tasks.immediate = NULL;
hal.irq_enable();
if(task) do {
} while((task = task_run(task)));
}
if(lock)
return;
lock = true;
uint32_t now = hal.get_elapsed_ticks();
if(!(now == last_ms || tasks.delayed == tasks.systick)) {
last_ms = now;
if((task = tasks.systick)) do {
task->fn(task->data);
} while((task = task->next));
while((task = tasks.delayed) && (int32_t)(task->time - now) <= 0) {
hal.irq_disable();
if(task == tasks.delayed)
tasks.delayed = task->next;
else {
core_task_t *t;
if((t = tasks.delayed)) {
while(t->next && t->next != task)
t = t->next;
if(t->next && t->next == task)
t->next = task->next;
}
}
void *data = task->data;
foreground_task_ptr fn = task->fn;
task_free(task);
hal.irq_enable();
fn(data);
}
}
lock = false;
}
ISR_CODE bool ISR_FUNC(task_add_delayed)(foreground_task_ptr fn, void *data, uint32_t delay_ms)
{
core_task_t *task = NULL;
hal.irq_disable();
if(fn && (task = task_alloc())) {
task->time = hal.get_elapsed_ticks() + delay_ms;
task->fn = fn;
task->data = data;
task->next = NULL;
if(tasks.delayed == NULL)
tasks.delayed = task;
else if((int32_t)(task->time - tasks.delayed->time) <= 0) {
task->next = tasks.delayed;
tasks.delayed = task;
} else {
core_task_t *t = tasks.delayed;
while(t) {
if(t->next == NULL || (int32_t)(task->time - t->next->time) < 0) {
task->next = t->next;
t->next = task;
break;
}
t = t->next;
}
}
}
hal.irq_enable();
return task != NULL;
}
ISR_CODE void task_delete (foreground_task_ptr fn, void *data)
{
core_task_t *task, *prev = NULL;
hal.irq_disable();
if((task = tasks.delayed)) do {
if(fn == task->fn && (data == NULL || data == task->data)) {
if(prev)
prev->next = task->next;
else
tasks.delayed = task->next;
task_free(task);
break;
}
prev = task;
} while((task = task->next));
hal.irq_enable();
}
ISR_CODE bool ISR_FUNC(task_add_systick)(foreground_task_ptr fn, void *data)
{
core_task_t *task = NULL;
hal.irq_disable();
if(fn && (task = task_alloc())) {
task->fn = fn;
task->data = data;
task->next = NULL;
if(tasks.systick == NULL)
tasks.systick = task;
else {
core_task_t *t = tasks.systick;
while(t->next)
t = t->next;
t->next = task;
}
}
hal.irq_enable();
return task != NULL;
}
FLASHMEM void task_delete_systick (foreground_task_ptr fn, void *data)
{
core_task_t *task, *prev = NULL;
hal.irq_disable();
if((task = tasks.systick)) do {
if(fn == task->fn && data == task->data) {
if(prev)
prev->next = task->next;
else
tasks.systick = task->next;
task_free(task);
break;
}
prev = task;
} while((task = task->next));
hal.irq_enable();
}
/*! \brief Enqueue a function to be called once by the foreground process.
\param fn pointer to a \a foreground_task_ptr type of function.
\param data pointer to data to be passed to the callee.
\returns true if successful, false otherwise.
*/
ISR_CODE bool ISR_FUNC(task_add_immediate)(foreground_task_ptr fn, void *data)
{
core_task_t *task = NULL;
hal.irq_disable();
if(fn && (task = task_alloc())) {
task->fn = fn;
task->data = data;
task->next = NULL;
if(tasks.immediate == NULL)
tasks.immediate = task;
else {
core_task_t *t = tasks.immediate;
while(t->next)
t = t->next;
t->next = task;
}
}
hal.irq_enable();
return task != NULL;
}
/*! \brief Enqueue a function to be called once by the foreground process after the reset sequence is completed.
\param fn pointer to a \a foreground_task_ptr type of function.
\param data pointer to data to be passed to the callee.
\returns true if successful, false otherwise.
*/
ISR_CODE bool ISR_FUNC(task_run_on_reset)(foreground_task_ptr fn, void *data)
{
core_task_t *task = NULL;
if(!sys.cold_start) {
hal.irq_disable();
if(fn && (task = task_alloc())) {
task->fn = fn;
task->data = data;
task->next = NULL;
if(tasks.on_reset == NULL)
tasks.on_reset = task;
else {
core_task_t *t = tasks.on_reset;
while(t->next)
t = t->next;
t->next = task;
}
}
hal.irq_enable();
}
return task != NULL;
}
/*! \brief Enqueue a function to be called once by the foreground process after the boot sequence is completed.
\param fn pointer to a \a foreground_task_ptr type of function.
\param data pointer to data to be passed to the callee.
\returns true if successful, false otherwise.
*/
ISR_CODE bool ISR_FUNC(task_run_on_startup)(foreground_task_ptr fn, void *data)
{
if(sys.cold_start) {
core_task_t *task = NULL;
hal.irq_disable();
if(fn && (task = task_alloc())) {
task->fn = fn;
task->data = data;
task->next = NULL;
if(tasks.on_booted == NULL)
tasks.on_booted = task;
else {
core_task_t *t = tasks.on_booted;
while(t->next)
t = t->next;
t->next = task;
}
}
hal.irq_enable();
return task != NULL;
} else
return task_add_immediate(fn, data); // TODO: for now, to be removed...
}
// for core use only, called once from protocol.c on cold start
FLASHMEM void task_execute_on_startup (void)
{
if(!sys.driver_started) {
// Clear task queues except startup warnings.
core_task_t *task, *prev = NULL;
if((task = tasks.on_booted)) do {
if(!(task->fn == report_warning)) {
if(prev)
prev->next = task->next;
else {
prev = NULL;
tasks.on_booted = task->next;
}
task_free(task);
} else
prev = task;
} while((task = prev ? prev->next : tasks.on_booted));
while(tasks.delayed)
task_delete(tasks.delayed->fn, NULL);
while(tasks.systick)
task_delete_systick(tasks.systick->fn, NULL);
}
if(tasks.on_booted && (sys.driver_started || !hal.stream.state.linestate_event)) do {
} while((tasks.on_booted = task_run(tasks.on_booted)));
if(tasks.on_reset) do {
} while((tasks.on_reset = task_run(tasks.on_reset)));
if(!sys.driver_started) {
if(hal.stream.state.linestate_event)
hal.stream.on_linestate_changed = onPosFailure;
while(true)
grbl.on_execute_realtime(state_get());
}
}
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif
FLASHMEM void task_raise_alarm (void *data)
{
system_raise_alarm((alarm_code_t)data);
}