circuitpython/main.c
Scott Shawcroft 66edcf5d03
Add PicoDVI support
PicoDVI in CP support 640x480 and 800x480 on Feather DVI, Pico and
Pico W. 1 and 2 bit grayscale are full resolution. 8 and 16 bit
color are half resolution.

Memory layout is modified to give the top most 4k of ram to the
second core. Its MPU is used to prevent flash access after startup.

The port saved word is moved to a watchdog scratch register so that
it doesn't get overwritten by other things in RAM.

Right align status bar and scroll area. This normally gives a few
pixels of padding on the left hand side and improves the odds it is
readable in a case. Fixes #7562

Fixes c stack checking. The length was correct but the top was being
set to the current stack pointer instead of the correct top.
Fixes #7643

This makes Bitmap subscr raise IndexError instead of ValueError
when the index arguments are wrong.
2023-04-19 15:14:02 -07:00

1174 lines
41 KiB
C

/*
* This file is part of the MicroPython project, http://micropython.org/
*
* The MIT License (MIT)
*
* Copyright (c) 2016-2017 Scott Shawcroft for Adafruit Industries
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include <stdint.h>
#include <string.h>
#include "extmod/vfs.h"
#include "extmod/vfs_fat.h"
#include "genhdr/mpversion.h"
#include "py/nlr.h"
#include "py/compile.h"
#include "py/frozenmod.h"
#include "py/mphal.h"
#include "py/runtime.h"
#include "py/repl.h"
#include "py/gc.h"
#include "py/stackctrl.h"
#include "shared/readline/readline.h"
#include "shared/runtime/pyexec.h"
#include "background.h"
#include "mpconfigboard.h"
#include "supervisor/background_callback.h"
#include "supervisor/board.h"
#include "supervisor/cpu.h"
#include "supervisor/filesystem.h"
#include "supervisor/memory.h"
#include "supervisor/port.h"
#include "supervisor/serial.h"
#include "supervisor/shared/reload.h"
#include "supervisor/shared/safe_mode.h"
#include "supervisor/shared/stack.h"
#include "supervisor/shared/status_leds.h"
#include "supervisor/shared/tick.h"
#include "supervisor/shared/traceback.h"
#include "supervisor/shared/translate/translate.h"
#include "supervisor/shared/workflow.h"
#include "supervisor/usb.h"
#include "supervisor/workflow.h"
#include "supervisor/shared/external_flash/external_flash.h"
#include "shared-bindings/microcontroller/__init__.h"
#include "shared-bindings/microcontroller/Processor.h"
#include "shared-bindings/supervisor/Runtime.h"
#if CIRCUITPY_ALARM
#include "shared-bindings/alarm/__init__.h"
#endif
#if CIRCUITPY_ATEXIT
#include "shared-module/atexit/__init__.h"
#endif
#if CIRCUITPY_BLEIO
#include "shared-bindings/_bleio/__init__.h"
#include "supervisor/shared/bluetooth/bluetooth.h"
#endif
#if CIRCUITPY_BOARD
#include "shared-module/board/__init__.h"
#endif
#if CIRCUITPY_CANIO
#include "common-hal/canio/CAN.h"
#endif
#if CIRCUITPY_DISPLAYIO
#include "shared-module/displayio/__init__.h"
#endif
#if CIRCUITPY_KEYPAD
#include "shared-module/keypad/__init__.h"
#endif
#if CIRCUITPY_MEMORYMONITOR
#include "shared-module/memorymonitor/__init__.h"
#endif
#if CIRCUITPY_SOCKETPOOL
#include "shared-bindings/socketpool/__init__.h"
#endif
#if CIRCUITPY_STATUS_BAR
#include "supervisor/shared/status_bar.h"
#endif
#if CIRCUITPY_USB_HID
#include "shared-module/usb_hid/__init__.h"
#endif
#if CIRCUITPY_WIFI
#include "shared-bindings/wifi/__init__.h"
#endif
#if CIRCUITPY_BOOT_COUNTER
#include "shared-bindings/nvm/ByteArray.h"
uint8_t value_out = 0;
#endif
#if MICROPY_ENABLE_PYSTACK && CIRCUITPY_OS_GETENV
#include "shared-module/os/__init__.h"
#endif
static void reset_devices(void) {
#if CIRCUITPY_BLEIO_HCI
bleio_reset();
#endif
}
#if MICROPY_ENABLE_PYSTACK
STATIC supervisor_allocation *allocate_pystack(safe_mode_t safe_mode) {
#if CIRCUITPY_OS_GETENV && CIRCUITPY_SETTABLE_PYSTACK
if (safe_mode == SAFE_MODE_NONE) {
mp_int_t pystack_size = CIRCUITPY_PYSTACK_SIZE;
(void)common_hal_os_getenv_int("CIRCUITPY_PYSTACK_SIZE", &pystack_size);
supervisor_allocation *pystack = allocate_memory(pystack_size >= 384 ? pystack_size : 0, false, false);
if (pystack) {
return pystack;
}
serial_write_compressed(translate("Invalid CIRCUITPY_PYSTACK_SIZE\n"));
}
#endif
return allocate_memory(CIRCUITPY_PYSTACK_SIZE, false, false);
}
#endif
STATIC void start_mp(supervisor_allocation *heap, supervisor_allocation *pystack) {
supervisor_workflow_reset();
// Stack limit should be less than real stack size, so we have a chance
// to recover from limit hit. (Limit is measured in bytes.) The top of the
// stack is set to our current state. Not the actual top.
mp_stack_ctrl_init();
uint32_t *stack_bottom = stack_get_bottom();
if (stack_bottom != NULL) {
size_t stack_length = stack_get_length();
mp_stack_set_top(stack_bottom + (stack_length / sizeof(uint32_t)));
mp_stack_set_limit(stack_length - 1024);
}
#if MICROPY_MAX_STACK_USAGE
// _ezero (same as _ebss) is an int, so start 4 bytes above it.
if (stack_get_bottom() != NULL) {
mp_stack_set_bottom(stack_get_bottom());
mp_stack_fill_with_sentinel();
}
#endif
// Sync the file systems in case any used RAM from the GC to cache. As soon
// as we re-init the GC all bets are off on the cache.
filesystem_flush();
// Clear the readline history. It references the heap we're about to destroy.
readline_init0();
#if MICROPY_ENABLE_PYSTACK
mp_pystack_init(pystack->ptr, pystack->ptr + get_allocation_length(pystack) / sizeof(size_t));
#endif
#if MICROPY_ENABLE_GC
gc_init(heap->ptr, heap->ptr + get_allocation_length(heap) / 4);
#endif
mp_init();
mp_obj_list_init((mp_obj_list_t *)mp_sys_path, 0);
mp_obj_list_append(mp_sys_path, MP_OBJ_NEW_QSTR(MP_QSTR_)); // current dir (or base dir of the script)
mp_obj_list_append(mp_sys_path, MP_OBJ_NEW_QSTR(MP_QSTR__slash_));
#if MICROPY_MODULE_FROZEN
mp_obj_list_append(mp_sys_path, MP_OBJ_NEW_QSTR(MP_QSTR__dot_frozen));
#endif
mp_obj_list_append(mp_sys_path, MP_OBJ_NEW_QSTR(MP_QSTR__slash_lib));
mp_obj_list_init((mp_obj_list_t *)mp_sys_argv, 0);
}
STATIC void stop_mp(void) {
#if MICROPY_VFS
mp_vfs_mount_t *vfs = MP_STATE_VM(vfs_mount_table);
// Unmount all heap allocated vfs mounts.
while (gc_nbytes(vfs) > 0) {
vfs = vfs->next;
}
MP_STATE_VM(vfs_mount_table) = vfs;
MP_STATE_VM(vfs_cur) = vfs;
#endif
background_callback_reset();
#if CIRCUITPY_USB
usb_background();
#endif
gc_deinit();
}
STATIC const char *_current_executing_filename = NULL;
STATIC pyexec_result_t _exec_result = {0, MP_OBJ_NULL, 0};
#if CIRCUITPY_STATUS_BAR
void supervisor_execution_status(void) {
mp_obj_exception_t *exception = MP_OBJ_TO_PTR(_exec_result.exception);
if (_current_executing_filename != NULL) {
serial_write(_current_executing_filename);
} else if ((_exec_result.return_code & PYEXEC_EXCEPTION) != 0 &&
_exec_result.exception_line > 0 &&
exception != NULL) {
mp_printf(&mp_plat_print, "%d@%s %q", _exec_result.exception_line, _exec_result.exception_filename, exception->base.type->name);
} else {
serial_write_compressed(translate("Done"));
}
}
#endif
// Look for the first file that exists in the list of filenames, using mp_import_stat().
// Return its index. If no file found, return -1.
STATIC const char *first_existing_file_in_list(const char *const *filenames, size_t n_filenames) {
for (size_t i = 0; i < n_filenames; i++) {
mp_import_stat_t stat = mp_import_stat(filenames[i]);
if (stat == MP_IMPORT_STAT_FILE) {
return filenames[i];
}
}
return NULL;
}
STATIC bool maybe_run_list(const char *const *filenames, size_t n_filenames) {
_exec_result.return_code = 0;
_exec_result.exception = MP_OBJ_NULL;
_exec_result.exception_line = 0;
_current_executing_filename = first_existing_file_in_list(filenames, n_filenames);
if (_current_executing_filename == NULL) {
return false;
}
mp_hal_stdout_tx_str(_current_executing_filename);
serial_write_compressed(translate(" output:\n"));
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_update();
#endif
pyexec_file(_current_executing_filename, &_exec_result);
#if CIRCUITPY_ATEXIT
shared_module_atexit_execute(&_exec_result);
#endif
_current_executing_filename = NULL;
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_update();
#endif
return true;
}
STATIC void count_strn(void *data, const char *str, size_t len) {
*(size_t *)data += len;
}
STATIC void cleanup_after_vm(supervisor_allocation *heap, supervisor_allocation *pystack, mp_obj_t exception) {
// Get the traceback of any exception from this run off the heap.
// MP_OBJ_SENTINEL means "this run does not contribute to traceback storage, don't touch it"
// MP_OBJ_NULL (=0) means "this run completed successfully, clear any stored traceback"
if (exception != MP_OBJ_SENTINEL) {
free_memory(prev_traceback_allocation);
// ReloadException is exempt from traceback printing in pyexec_file(), so treat it as "no
// traceback" here too.
if (exception && exception != MP_OBJ_FROM_PTR(&MP_STATE_VM(mp_reload_exception))) {
size_t traceback_len = 0;
mp_print_t print_count = {&traceback_len, count_strn};
mp_obj_print_exception(&print_count, exception);
prev_traceback_allocation = allocate_memory(align32_size(traceback_len + 1), false, true);
// Empirically, this never fails in practice - even when the heap is totally filled up
// with single-block-sized objects referenced by a root pointer, exiting the VM frees
// up several hundred bytes, sufficient for the traceback (which tends to be shortened
// because there wasn't memory for the full one). There may be convoluted ways of
// making it fail, but at this point I believe they are not worth spending code on.
if (prev_traceback_allocation != NULL) {
vstr_t vstr;
vstr_init_fixed_buf(&vstr, traceback_len, (char *)prev_traceback_allocation->ptr);
mp_print_t print = {&vstr, (mp_print_strn_t)vstr_add_strn};
mp_obj_print_exception(&print, exception);
((char *)prev_traceback_allocation->ptr)[traceback_len] = '\0';
}
} else {
prev_traceback_allocation = NULL;
}
}
// Reset port-independent devices, like CIRCUITPY_BLEIO_HCI.
reset_devices();
#if CIRCUITPY_ATEXIT
atexit_reset();
#endif
// Turn off the display and flush the filesystem before the heap disappears.
#if CIRCUITPY_DISPLAYIO
reset_displays();
#endif
#if CIRCUITPY_MEMORYMONITOR
memorymonitor_reset();
#endif
// Disable user related BLE state that uses the micropython heap.
#if CIRCUITPY_BLEIO
bleio_user_reset();
#endif
#if CIRCUITPY_CANIO
common_hal_canio_reset();
#endif
#if CIRCUITPY_KEYPAD
keypad_reset();
#endif
// Close user-initiated sockets.
#if CIRCUITPY_SOCKETPOOL
socketpool_user_reset();
#endif
// Turn off user initiated WiFi connections.
#if CIRCUITPY_WIFI
wifi_user_reset();
#endif
// reset_board_buses() first because it may release pins from the never_reset state, so that
// reset_port() can reset them.
#if CIRCUITPY_BOARD
reset_board_buses();
#endif
reset_port();
reset_board();
// Free the heap last because other modules may reference heap memory and need to shut down.
filesystem_flush();
stop_mp();
free_memory(heap);
#if MICROPY_ENABLE_PYSTACK
free_memory(pystack);
#endif
supervisor_move_memory();
// Let the workflows know we've reset in case they want to restart.
supervisor_workflow_reset();
}
STATIC void print_code_py_status_message(safe_mode_t safe_mode) {
if (autoreload_is_enabled()) {
serial_write_compressed(
translate("Auto-reload is on. Simply save files over USB to run them or enter REPL to disable.\n"));
} else {
serial_write_compressed(translate("Auto-reload is off.\n"));
}
if (safe_mode != SAFE_MODE_NONE) {
serial_write_compressed(translate("Running in safe mode! Not running saved code.\n"));
}
}
STATIC bool run_code_py(safe_mode_t safe_mode, bool *simulate_reset) {
bool serial_connected_at_start = serial_connected();
bool printed_safe_mode_message = false;
#if CIRCUITPY_AUTORELOAD_DELAY_MS > 0
if (serial_connected_at_start) {
serial_write("\r\n");
print_code_py_status_message(safe_mode);
print_safe_mode_message(safe_mode);
printed_safe_mode_message = true;
}
#endif
bool skip_repl = false;
bool skip_wait = false;
bool found_main = false;
uint8_t next_code_options = 0;
// Collects stickiness bits that apply in the current situation.
uint8_t next_code_stickiness_situation = SUPERVISOR_NEXT_CODE_OPT_NEWLY_SET;
// Do the filesystem flush check before reload in case another write comes
// in while we're doing the flush.
if (safe_mode == SAFE_MODE_NONE) {
stack_resize();
filesystem_flush();
}
if (safe_mode == SAFE_MODE_NONE && !autoreload_pending()) {
static const char *const supported_filenames[] = {
"code.txt", "code.py", "main.py", "main.txt"
};
#if CIRCUITPY_FULL_BUILD
static const char *const double_extension_filenames[] = {
"code.txt.py", "code.py.txt", "code.txt.txt","code.py.py",
"main.txt.py", "main.py.txt", "main.txt.txt","main.py.py"
};
#endif
supervisor_allocation *pystack = NULL;
#if MICROPY_ENABLE_PYSTACK
pystack = allocate_pystack(safe_mode);
#endif
supervisor_allocation *heap = allocate_remaining_memory();
start_mp(heap, pystack);
#if CIRCUITPY_USB
usb_setup_with_vm();
#endif
// Check if a different run file has been allocated
if (next_code_allocation) {
next_code_info_t *info = ((next_code_info_t *)next_code_allocation->ptr);
info->options &= ~SUPERVISOR_NEXT_CODE_OPT_NEWLY_SET;
next_code_options = info->options;
if (info->filename[0] != '\0') {
// This is where the user's python code is actually executed:
const char *const filenames[] = { info->filename };
found_main = maybe_run_list(filenames, MP_ARRAY_SIZE(filenames));
if (!found_main) {
serial_write(info->filename);
serial_write_compressed(translate(" not found.\n"));
}
}
}
// Otherwise, default to the standard list of filenames
if (!found_main) {
// This is where the user's python code is actually executed:
found_main = maybe_run_list(supported_filenames, MP_ARRAY_SIZE(supported_filenames));
// If that didn't work, double check the extensions
#if CIRCUITPY_FULL_BUILD
if (!found_main) {
found_main = maybe_run_list(double_extension_filenames, MP_ARRAY_SIZE(double_extension_filenames));
if (found_main) {
serial_write_compressed(translate("WARNING: Your code filename has two extensions\n"));
}
}
#else
(void)found_main;
#endif
}
// Print done before resetting everything so that we get the message over
// BLE before it is reset and we have a delay before reconnect.
if ((_exec_result.return_code & PYEXEC_RELOAD) && supervisor_get_run_reason() == RUN_REASON_AUTO_RELOAD) {
serial_write_compressed(translate("\nCode stopped by auto-reload. Reloading soon.\n"));
} else {
serial_write_compressed(translate("\nCode done running.\n"));
}
// Finished executing python code. Cleanup includes filesystem flush and a board reset.
cleanup_after_vm(heap, pystack, _exec_result.exception);
_exec_result.exception = NULL;
// If a new next code file was set, that is a reason to keep it (obviously). Stuff this into
// the options because it can be treated like any other reason-for-stickiness bit. The
// source is different though: it comes from the options that will apply to the next run,
// while the rest of next_code_options is what applied to this run.
if (next_code_allocation != NULL &&
(((next_code_info_t *)next_code_allocation->ptr)->options & SUPERVISOR_NEXT_CODE_OPT_NEWLY_SET)) {
next_code_options |= SUPERVISOR_NEXT_CODE_OPT_NEWLY_SET;
}
if (_exec_result.return_code & PYEXEC_RELOAD) {
next_code_stickiness_situation |= SUPERVISOR_NEXT_CODE_OPT_STICKY_ON_RELOAD;
// Reload immediately unless the reload is due to autoreload. In that
// case, we wait below to see if any other writes occur.
if (supervisor_get_run_reason() != RUN_REASON_AUTO_RELOAD) {
skip_repl = true;
skip_wait = true;
}
} else if (_exec_result.return_code == 0) {
next_code_stickiness_situation |= SUPERVISOR_NEXT_CODE_OPT_STICKY_ON_SUCCESS;
if (next_code_options & SUPERVISOR_NEXT_CODE_OPT_RELOAD_ON_SUCCESS) {
skip_repl = true;
skip_wait = true;
}
} else {
next_code_stickiness_situation |= SUPERVISOR_NEXT_CODE_OPT_STICKY_ON_ERROR;
// Deep sleep cannot be skipped
// TODO: settings in deep sleep should persist, using a new sleep memory API
if (next_code_options & SUPERVISOR_NEXT_CODE_OPT_RELOAD_ON_ERROR
&& !(_exec_result.return_code & PYEXEC_DEEP_SLEEP)) {
skip_repl = true;
skip_wait = true;
}
}
if (_exec_result.return_code & PYEXEC_FORCED_EXIT) {
skip_repl = false;
skip_wait = true;
}
}
// Program has finished running.
bool printed_press_any_key = false;
#if CIRCUITPY_DISPLAYIO
size_t time_to_epaper_refresh = 1;
#endif
// Setup LED blinks.
#if CIRCUITPY_STATUS_LED
uint32_t color;
uint8_t blink_count;
bool led_active = false;
#if CIRCUITPY_ALARM
if (_exec_result.return_code & PYEXEC_DEEP_SLEEP) {
color = BLACK;
blink_count = 0;
} else
#endif
if (_exec_result.return_code != PYEXEC_EXCEPTION) {
if (safe_mode == SAFE_MODE_NONE) {
color = ALL_DONE;
blink_count = ALL_DONE_BLINKS;
} else {
color = SAFE_MODE;
blink_count = SAFE_MODE_BLINKS;
}
} else {
color = EXCEPTION;
blink_count = EXCEPTION_BLINKS;
}
size_t pattern_start = supervisor_ticks_ms32();
size_t single_blink_time = (OFF_ON_RATIO + 1) * BLINK_TIME_MS;
size_t blink_time = single_blink_time * blink_count;
size_t total_time = blink_time + LED_SLEEP_TIME_MS;
#endif
// This loop is waits after code completes. It waits for fake sleeps to
// finish, user input or autoreloads.
#if CIRCUITPY_ALARM
bool fake_sleeping = false;
#endif
while (!skip_wait) {
RUN_BACKGROUND_TASKS;
// If a reload was requested by the supervisor or autoreload, return.
if (autoreload_ready()) {
next_code_stickiness_situation |= SUPERVISOR_NEXT_CODE_OPT_STICKY_ON_RELOAD;
// Should the STICKY_ON_SUCCESS and STICKY_ON_ERROR bits be cleared in
// next_code_stickiness_situation? I can see arguments either way, but I'm deciding
// "no" for now, mainly because it's a bit less code. At this point, we have both a
// success or error and a reload, so let's have both of the respective options take
// effect (in OR combination).
skip_repl = true;
// We're kicking off the autoreload process so reset now. If any
// other reloads trigger after this, then we'll want another wait
// period.
autoreload_reset();
break;
}
// If interrupted by keyboard, return
if (serial_connected() && serial_bytes_available() && !autoreload_pending()) {
// Skip REPL if reload was requested.
skip_repl = serial_read() == CHAR_CTRL_D;
if (skip_repl) {
supervisor_set_run_reason(RUN_REASON_REPL_RELOAD);
}
break;
}
// Check for a deep sleep alarm and restart the VM. This can happen if
// an alarm alerts faster than our USB delay or if we pretended to deep
// sleep.
#if CIRCUITPY_ALARM
if (fake_sleeping && common_hal_alarm_woken_from_sleep()) {
serial_write_compressed(translate("Woken up by alarm.\n"));
supervisor_set_run_reason(RUN_REASON_STARTUP);
skip_repl = true;
break;
}
#endif
// If messages haven't been printed yet, print them
if (!printed_press_any_key && serial_connected() && !autoreload_pending()) {
if (!serial_connected_at_start) {
print_code_py_status_message(safe_mode);
}
if (!printed_safe_mode_message) {
print_safe_mode_message(safe_mode);
printed_safe_mode_message = true;
}
serial_write("\r\n");
serial_write_compressed(translate("Press any key to enter the REPL. Use CTRL-D to reload.\n"));
printed_press_any_key = true;
}
if (!serial_connected()) {
serial_connected_at_start = false;
printed_press_any_key = false;
}
// Sleep until our next interrupt.
#if CIRCUITPY_ALARM
if (_exec_result.return_code & PYEXEC_DEEP_SLEEP) {
const bool awoke_from_true_deep_sleep =
common_hal_mcu_processor_get_reset_reason() == RESET_REASON_DEEP_SLEEP_ALARM;
if (fake_sleeping) {
// This waits until a pretend deep sleep alarm occurs. They are set
// during common_hal_alarm_set_deep_sleep_alarms. On some platforms
// it may also return due to another interrupt, that's why we check
// for deep sleep alarms above. If it wasn't a deep sleep alarm,
// then we'll idle here again.
common_hal_alarm_pretending_deep_sleep();
}
// The first time we go into a deep sleep, make sure we have been awake long enough
// for USB to connect (enumeration delay), or for the BLE workflow to start.
// We wait CIRCUITPY_WORKFLOW_CONNECTION_SLEEP_DELAY seconds after a restart.
// But if we woke up from a real deep sleep, don't wait for connection. The user will need to
// do a hard reset to get out of the real deep sleep.
else if (awoke_from_true_deep_sleep ||
port_get_raw_ticks(NULL) > CIRCUITPY_WORKFLOW_CONNECTION_SLEEP_DELAY * 1024) {
// OK to start sleeping, real or fake.
#if CIRCUITPY_DISPLAYIO
common_hal_displayio_release_displays();
#endif
status_led_deinit();
deinit_rxtx_leds();
board_deinit();
// Continue with true deep sleep even if workflow is available.
if (awoke_from_true_deep_sleep || !supervisor_workflow_active()) {
// Enter true deep sleep. When we wake up we'll be back at the
// top of main(), not in this loop.
common_hal_alarm_enter_deep_sleep();
// Does not return.
} else {
serial_write_compressed(
translate("Pretending to deep sleep until alarm, CTRL-C or file write.\n"));
fake_sleeping = true;
}
} else {
// Loop while checking the time. We can't idle because we don't want to override a
// time alarm set for the deep sleep.
}
} else
#endif
{
// Refresh the ePaper display if we have one. That way it'll show an error message.
#if CIRCUITPY_DISPLAYIO
if (time_to_epaper_refresh > 0) {
time_to_epaper_refresh = maybe_refresh_epaperdisplay();
}
#if !CIRCUITPY_STATUS_LED
port_interrupt_after_ticks(time_to_epaper_refresh);
#endif
#endif
#if CIRCUITPY_STATUS_LED
uint32_t tick_diff = supervisor_ticks_ms32() - pattern_start;
// By default, don't sleep.
size_t time_to_next_change = 0;
if (tick_diff < blink_time) {
uint32_t blink_diff = tick_diff % (single_blink_time);
if (blink_diff >= BLINK_TIME_MS) {
if (led_active) {
new_status_color(BLACK);
status_led_deinit();
led_active = false;
}
time_to_next_change = single_blink_time - blink_diff;
} else {
if (!led_active) {
status_led_init();
new_status_color(color);
led_active = true;
}
time_to_next_change = BLINK_TIME_MS - blink_diff;
}
} else if (tick_diff > total_time) {
pattern_start = supervisor_ticks_ms32();
} else {
if (led_active) {
new_status_color(BLACK);
status_led_deinit();
led_active = false;
}
time_to_next_change = total_time - tick_diff;
}
#if CIRCUITPY_DISPLAYIO
if (time_to_epaper_refresh > 0 && time_to_next_change > 0) {
time_to_next_change = MIN(time_to_next_change, time_to_epaper_refresh);
}
#endif
// time_to_next_change is in ms and ticks are slightly shorter so
// we'll undersleep just a little. It shouldn't matter.
port_interrupt_after_ticks(time_to_next_change);
#endif
port_idle_until_interrupt();
}
}
// Done waiting, start the board back up.
// We delay resetting BLE until after the wait in case we're transferring
// more files over.
#if CIRCUITPY_BLEIO
bleio_reset();
#endif
// free code allocation if unused
if ((next_code_options & next_code_stickiness_situation) == 0) {
free_memory(next_code_allocation);
next_code_allocation = NULL;
}
#if CIRCUITPY_STATUS_LED
if (led_active) {
new_status_color(BLACK);
status_led_deinit();
}
#endif
#if CIRCUITPY_ALARM
if (fake_sleeping) {
board_init();
// Pretend that the next run is the first run, as if we were reset.
*simulate_reset = true;
}
#endif
return skip_repl;
}
vstr_t *boot_output;
#if CIRCUITPY_SAFEMODE_PY
STATIC void __attribute__ ((noinline)) run_safemode_py(safe_mode_t safe_mode) {
// Don't run if we aren't in safe mode or we won't be able to find safemode.py.
// Also don't run if it's a user-initiated safemode (pressing button(s) during boot),
// since that's deliberate.
if (safe_mode == SAFE_MODE_NONE || safe_mode == SAFE_MODE_USER || !filesystem_present()) {
return;
}
supervisor_allocation *pystack = NULL;
#if MICROPY_ENABLE_PYSTACK
pystack = allocate_pystack(safe_mode);
#endif
supervisor_allocation *heap = allocate_remaining_memory();
start_mp(heap, pystack);
static const char *const safemode_py_filenames[] = {"safemode.py", "safemode.txt"};
maybe_run_list(safemode_py_filenames, MP_ARRAY_SIZE(safemode_py_filenames));
// If safemode.py itself caused an error, change the safe_mode state to indicate that.
if (_exec_result.exception != MP_OBJ_NULL &&
_exec_result.exception != MP_OBJ_SENTINEL) {
set_safe_mode(SAFE_MODE_SAFEMODE_PY_ERROR);
}
cleanup_after_vm(heap, pystack, _exec_result.exception);
_exec_result.exception = NULL;
}
#endif
STATIC void __attribute__ ((noinline)) run_boot_py(safe_mode_t safe_mode) {
if (safe_mode == SAFE_MODE_NO_HEAP) {
return;
}
// If not in safe mode, run boot before initing USB and capture output in a file.
// There is USB setup to do even if boot.py is not actually run.
const bool ok_to_run = filesystem_present()
&& safe_mode == SAFE_MODE_NONE
&& MP_STATE_VM(vfs_mount_table) != NULL;
static const char *const boot_py_filenames[] = {"boot.py", "boot.txt"};
// Do USB setup even if boot.py is not run.
supervisor_allocation *pystack = NULL;
#if MICROPY_ENABLE_PYSTACK
pystack = allocate_pystack(safe_mode);
#endif
supervisor_allocation *heap = allocate_remaining_memory();
start_mp(heap, pystack);
#if CIRCUITPY_USB
// Set up default USB values after boot.py VM starts but before running boot.py.
usb_set_defaults();
#endif
if (ok_to_run) {
#ifdef CIRCUITPY_BOOT_OUTPUT_FILE
#if CIRCUITPY_STATUS_BAR
// Turn off status bar updates when writing out to boot_out.txt.
supervisor_status_bar_suspend();
#endif
vstr_t boot_text;
vstr_init(&boot_text, 512);
boot_output = &boot_text;
#endif
// Write version info
mp_printf(&mp_plat_print, "%s\nBoard ID:%s\n", MICROPY_FULL_VERSION_INFO, CIRCUITPY_BOARD_ID);
#if CIRCUITPY_MICROCONTROLLER && COMMON_HAL_MCU_PROCESSOR_UID_LENGTH > 0
uint8_t raw_id[COMMON_HAL_MCU_PROCESSOR_UID_LENGTH];
common_hal_mcu_processor_get_uid(raw_id);
mp_cprintf(&mp_plat_print, translate("UID:"));
for (size_t i = 0; i < COMMON_HAL_MCU_PROCESSOR_UID_LENGTH; i++) {
mp_cprintf(&mp_plat_print, translate("%02X"), raw_id[i]);
}
mp_printf(&mp_plat_print, "\n");
port_boot_info();
#endif
bool found_boot = maybe_run_list(boot_py_filenames, MP_ARRAY_SIZE(boot_py_filenames));
(void)found_boot;
#ifdef CIRCUITPY_BOOT_OUTPUT_FILE
// Get the base filesystem.
fs_user_mount_t *vfs = (fs_user_mount_t *)MP_STATE_VM(vfs_mount_table)->obj;
FATFS *fs = &vfs->fatfs;
boot_output = NULL;
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_resume();
#endif
bool write_boot_output = true;
FIL boot_output_file;
if (f_open(fs, &boot_output_file, CIRCUITPY_BOOT_OUTPUT_FILE, FA_READ) == FR_OK) {
char *file_contents = m_new(char, boot_text.alloc);
UINT chars_read;
if (f_read(&boot_output_file, file_contents, 1 + boot_text.len, &chars_read) == FR_OK) {
write_boot_output =
(chars_read != boot_text.len) || (memcmp(boot_text.buf, file_contents, chars_read) != 0);
}
// no need to f_close the file
}
if (write_boot_output) {
// Wait 1 second before opening CIRCUITPY_BOOT_OUTPUT_FILE for write,
// in case power is momentary or will fail shortly due to, say a low, battery.
mp_hal_delay_ms(1000);
// USB isn't up, so we can write the file.
// operating at the oofatfs (f_open) layer means the usb concurrent write permission
// is not even checked!
f_open(fs, &boot_output_file, CIRCUITPY_BOOT_OUTPUT_FILE, FA_WRITE | FA_CREATE_ALWAYS);
UINT chars_written;
f_write(&boot_output_file, boot_text.buf, boot_text.len, &chars_written);
f_close(&boot_output_file);
filesystem_flush();
}
#endif
}
#if CIRCUITPY_USB
// Some data needs to be carried over from the USB settings in boot.py
// to the next VM, while the heap is still available.
// Its size can vary, so save it temporarily on the stack,
// and then when the heap goes away, copy it in into a
// storage_allocation.
size_t size = usb_boot_py_data_size();
uint8_t usb_boot_py_data[size];
usb_get_boot_py_data(usb_boot_py_data, size);
#endif
port_post_boot_py(true);
cleanup_after_vm(heap, pystack, _exec_result.exception);
_exec_result.exception = NULL;
port_post_boot_py(false);
#if CIRCUITPY_USB
// Now give back the data we saved from the heap going away.
usb_return_boot_py_data(usb_boot_py_data, size);
#endif
}
STATIC int run_repl(safe_mode_t safe_mode) {
int exit_code = PYEXEC_FORCED_EXIT;
stack_resize();
filesystem_flush();
supervisor_allocation *pystack = NULL;
#if MICROPY_ENABLE_PYSTACK
pystack = allocate_pystack(safe_mode);
#endif
supervisor_allocation *heap = allocate_remaining_memory();
start_mp(heap, pystack);
#if CIRCUITPY_USB
usb_setup_with_vm();
#endif
autoreload_suspend(AUTORELOAD_SUSPEND_REPL);
// Set the status LED to the REPL color before running the REPL. For
// NeoPixels and DotStars this will be sticky but for PWM or single LED it
// won't. This simplifies pin sharing because they won't be in use when
// actually in the REPL.
#if CIRCUITPY_STATUS_LED
status_led_init();
new_status_color(REPL_RUNNING);
status_led_deinit();
#endif
if (pyexec_mode_kind == PYEXEC_MODE_RAW_REPL) {
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_suspend();
#endif
exit_code = pyexec_raw_repl();
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_resume();
#endif
} else {
_current_executing_filename = "REPL";
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_update();
#endif
exit_code = pyexec_friendly_repl();
_current_executing_filename = NULL;
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_update();
#endif
}
#if CIRCUITPY_ATEXIT
pyexec_result_t result;
shared_module_atexit_execute(&result);
if (result.return_code == PYEXEC_DEEP_SLEEP) {
exit_code = PYEXEC_DEEP_SLEEP;
}
#endif
cleanup_after_vm(heap, pystack, MP_OBJ_SENTINEL);
// Also reset bleio. The above call omits it in case workflows should continue. In this case,
// we're switching straight to another VM so we want to reset.
#if CIRCUITPY_BLEIO
bleio_reset();
#endif
#if CIRCUITPY_STATUS_LED
status_led_init();
new_status_color(BLACK);
status_led_deinit();
#endif
autoreload_resume(AUTORELOAD_SUSPEND_REPL);
return exit_code;
}
int __attribute__((used)) main(void) {
// initialise the cpu and peripherals
set_safe_mode(port_init());
// Turn on RX and TX LEDs if we have them.
init_rxtx_leds();
#if CIRCUITPY_BOOT_COUNTER
// Increment counter before possibly entering safe mode
common_hal_nvm_bytearray_get_bytes(&common_hal_mcu_nvm_obj,0,1,&value_out);
++value_out;
common_hal_nvm_bytearray_set_bytes(&common_hal_mcu_nvm_obj,0,&value_out,1);
#endif
// Start the debug serial
serial_early_init();
// Wait briefly to give a reset window where we'll enter safe mode after the reset.
if (get_safe_mode() == SAFE_MODE_NONE) {
set_safe_mode(wait_for_safe_mode_reset());
}
stack_init();
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_init();
#endif
#if CIRCUITPY_BLEIO
// Early init so that a reset press can cause BLE public advertising.
supervisor_bluetooth_init();
#endif
#if !INTERNAL_FLASH_FILESYSTEM
// Set up anything that might need to get done before we try to use SPI flash
// This is needed for some boards where flash relies on GPIO setup to work
external_flash_setup();
#endif
// Create a new filesystem only if we're not in a safe mode.
// A power brownout here could make it appear as if there's
// no SPI flash filesystem, and we might erase the existing one.
// Check whether CIRCUITPY is available. No need to reset to get safe mode
// since we haven't run user code yet.
if (!filesystem_init(get_safe_mode() == SAFE_MODE_NONE, false)) {
set_safe_mode(SAFE_MODE_NO_CIRCUITPY);
}
#if CIRCUITPY_ALARM
// Record which alarm woke us up, if any.
// common_hal_alarm_record_wake_alarm() should return a static, non-heap object
shared_alarm_save_wake_alarm(common_hal_alarm_record_wake_alarm());
// Then reset the alarm system. It's not reset in reset_port(), because that's also called
// on VM teardown, which would clear any alarm setup.
alarm_reset();
#endif
// Reset everything and prep MicroPython to run boot.py.
reset_port();
// Port-independent devices, like CIRCUITPY_BLEIO_HCI.
reset_devices();
reset_board();
// displays init after filesystem, since they could share the flash SPI
board_init();
// This is first time we are running CircuitPython after a reset or power-up.
supervisor_set_run_reason(RUN_REASON_STARTUP);
// If not in safe mode turn on autoreload by default but before boot.py in case it wants to change it.
if (get_safe_mode() == SAFE_MODE_NONE) {
autoreload_enable();
}
// By default our internal flash is readonly to local python code and
// writable over USB. Set it here so that safemode.py or boot.py can change it.
filesystem_set_internal_concurrent_write_protection(true);
filesystem_set_internal_writable_by_usb(CIRCUITPY_USB == 1);
#if CIRCUITPY_SAFEMODE_PY
// Run safemode.py if we ARE in safe mode.
// If safemode.py does not do a hard reset, and exits normally, we will continue on
// and report the safe mode as usual.
run_safemode_py(get_safe_mode());
#endif
run_boot_py(get_safe_mode());
supervisor_workflow_start();
#if CIRCUITPY_STATUS_BAR
supervisor_status_bar_request_update(true);
#endif
// Boot script is finished, so now go into REPL or run code.py.
int exit_code = PYEXEC_FORCED_EXIT;
bool skip_repl = true;
bool simulate_reset = true;
for (;;) {
if (!skip_repl) {
exit_code = run_repl(get_safe_mode());
supervisor_set_run_reason(RUN_REASON_REPL_RELOAD);
}
if (exit_code == PYEXEC_FORCED_EXIT) {
if (!simulate_reset) {
serial_write_compressed(translate("soft reboot\n"));
}
simulate_reset = false;
if (pyexec_mode_kind == PYEXEC_MODE_FRIENDLY_REPL) {
// If code.py did a fake deep sleep, pretend that we
// are running code.py for the first time after a hard
// reset. This will preserve any alarm information.
skip_repl = run_code_py(get_safe_mode(), &simulate_reset);
} else {
skip_repl = false;
}
} else if (exit_code != 0) {
break;
}
#if CIRCUITPY_ALARM
shared_alarm_save_wake_alarm(simulate_reset ? common_hal_alarm_record_wake_alarm() : mp_const_none);
alarm_reset();
#endif
}
mp_deinit();
return 0;
}
void gc_collect(void) {
gc_collect_start();
mp_uint_t regs[10];
mp_uint_t sp = cpu_get_regs_and_sp(regs);
// This collects root pointers from the VFS mount table. Some of them may
// have lost their references in the VM even though they are mounted.
gc_collect_root((void **)&MP_STATE_VM(vfs_mount_table), sizeof(mp_vfs_mount_t) / sizeof(mp_uint_t));
port_gc_collect();
background_callback_gc_collect();
#if CIRCUITPY_ALARM
common_hal_alarm_gc_collect();
#endif
#if CIRCUITPY_ATEXIT
atexit_gc_collect();
#endif
#if CIRCUITPY_DISPLAYIO
displayio_gc_collect();
#endif
#if CIRCUITPY_BLEIO
common_hal_bleio_gc_collect();
#endif
#if CIRCUITPY_USB_HID
usb_hid_gc_collect();
#endif
#if CIRCUITPY_WIFI
common_hal_wifi_gc_collect();
#endif
// This naively collects all object references from an approximate stack
// range.
gc_collect_root((void **)sp, ((mp_uint_t)port_stack_get_top() - sp) / sizeof(mp_uint_t));
gc_collect_end();
}
// Ports may provide an implementation of this function if it is needed
MP_WEAK void port_gc_collect() {
}
void NORETURN nlr_jump_fail(void *val) {
reset_into_safe_mode(SAFE_MODE_NLR_JUMP_FAIL);
while (true) {
}
}
#ifndef NDEBUG
static void NORETURN __fatal_error(const char *msg) {
reset_into_safe_mode(SAFE_MODE_HARD_FAULT);
while (true) {
}
}
void MP_WEAK __assert_func(const char *file, int line, const char *func, const char *expr) {
mp_printf(&mp_plat_print, "Assertion '%s' failed, at file %s:%d\n", expr, file, line);
__fatal_error("Assertion failed");
}
#endif