WIP: complete manual inspection of all significant changes

This commit is contained in:
Dan Halbert 2018-07-23 21:34:25 -04:00
parent 2809b4f9dd
commit bc760dd341
32 changed files with 153 additions and 530 deletions

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@ -16,14 +16,14 @@ Classes
.. class:: array.array(typecode, [iterable])
Create array with elements of given type. Initial contents of the
array are given by *iterable*. If it is not provided, an empty
array are given by an `iterable`. If it is not provided, an empty
array is created.
.. method:: append(val)
Append new element *val* to the end of array, growing it.
Append new element ``val`` to the end of array, growing it.
.. method:: extend(iterable)
Append new elements as contained in *iterable* to the end of
Append new elements as contained in `iterable` to the end of
array, growing it.

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@ -16,20 +16,20 @@ Functions
.. function:: dump(obj, stream)
Serialise *obj* to a JSON string, writing it to the given *stream*.
Serialise ``obj`` to a JSON string, writing it to the given *stream*.
.. function:: dumps(obj)
Return *obj* represented as a JSON string.
Return ``obj`` represented as a JSON string.
.. function:: load(stream)
Parse the given *stream*, interpreting it as a JSON string and
Parse the given ``stream``, interpreting it as a JSON string and
deserialising the data to a Python object. The resulting object is
returned.
Parsing continues until end-of-file is encountered.
A :exc:`ValueError` is raised if the data in *stream* is not correctly formed.
A :exc:`ValueError` is raised if the data in ``stream`` is not correctly formed.
.. function:: loads(str)

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@ -69,7 +69,6 @@ Functions
.. data:: DEBUG
Flag value, display debug information about compiled expression.
(Availability depends on `MicroPython port`.)
.. _regex:

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@ -1,312 +0,0 @@
Distribution packages, package management, and deploying applications
=====================================================================
Just as the "big" Python, MicroPython supports creation of "third party"
packages, distributing them, and easily installing them in each user's
environment. This chapter discusses how these actions are achieved.
Some familiarity with Python packaging is recommended.
Overview
--------
Steps below represent a high-level workflow when creating and consuming
packages:
1. Python modules and packages are turned into distribution package
archives, and published at the Python Package Index (PyPI).
2. `upip` package manager can be used to install a distribution package
on a `MicroPython port` with networking capabilities (for example,
on the Unix port).
3. For ports without networking capabilities, an "installation image"
can be prepared on the Unix port, and transferred to a device by
suitable means.
4. For low-memory ports, the installation image can be frozen as the
bytecode into MicroPython executable, thus minimizing the memory
storage overheads.
The sections below describe this process in details.
Distribution packages
---------------------
Python modules and packages can be packaged into archives suitable for
transfer between systems, storing at the well-known location (PyPI),
and downloading on demand for deployment. These archives are known as
*distribution packages* (to differentiate them from Python packages
(means to organize Python source code)).
The MicroPython distribution package format is a well-known tar.gz
format, with some adaptations however. The Gzip compressor, used as
an external wrapper for TAR archives, by default uses 32KB dictionary
size, which means that to uncompress a compressed stream, 32KB of
contguous memory needs to be allocated. This requirement may be not
satisfiable on low-memory devices, which may have total memory available
less than that amount, and even if not, a contiguous block like that
may be hard to allocate due to memory fragmentation. To accommodate
these constraints, MicroPython distribution packages use Gzip compression
with the dictionary size of 4K, which should be a suitable compromise
with still achieving some compression while being able to uncompressed
even by the smallest devices.
Besides the small compression dictionary size, MicroPython distribution
packages also have other optimizations, like removing any files from
the archive which aren't used by the installation process. In particular,
`upip` package manager doesn't execute ``setup.py`` during installation
(see below), and thus that file is not included in the archive.
At the same time, these optimizations make MicroPython distribution
packages not compatible with `CPython`'s package manager, ``pip``.
This isn't considered a big problem, because:
1. Packages can be installed with `upip`, and then can be used with
CPython (if they are compatible with it).
2. In the other direction, majority of CPython packages would be
incompatible with MicroPython by various reasons, first of all,
the reliance on features not implemented by MicroPython.
Summing up, the MicroPython distribution package archives are highly
optimized for MicroPython's target environments, which are highly
resource constrained devices.
``upip`` package manager
------------------------
MicroPython distribution packages are intended to be installed using
the `upip` package manager. `upip` is a Python application which is
usually distributed (as frozen bytecode) with network-enabled
`MicroPython ports <MicroPython port>`. At the very least,
`upip` is available in the `MicroPython Unix port`.
On any `MicroPython port` providing `upip`, it can be accessed as
following::
import upip
upip.help()
upip.install(package_or_package_list, [path])
Where *package_or_package_list* is the name of a distribution
package to install, or a list of such names to install multiple
packages. Optional *path* parameter specifies filesystem
location to install under and defaults to the standard library
location (see below).
An example of installing a specific package and then using it::
>>> import upip
>>> upip.install("micropython-pystone_lowmem")
[...]
>>> import pystone_lowmem
>>> pystone_lowmem.main()
Note that the name of Python package and the name of distribution
package for it in general don't have to match, and oftentimes they
don't. This is because PyPI provides a central package repository
for all different Python implementations and versions, and thus
distribution package names may need to be namespaced for a particular
implementation. For example, all packages from `micropython-lib`
follow this naming convention: for a Python module or package named
``foo``, the distribution package name is ``micropython-foo``.
For the ports which run MicroPython executable from the OS command
prompts (like the Unix port), `upip` can be (and indeed, usually is)
run from the command line instead of MicroPython's own REPL. The
commands which corresponds to the example above are::
micropython -m upip -h
micropython -m upip install [-p <path>] <packages>...
micropython -m upip install micropython-pystone_lowmem
[TODO: Describe installation path.]
Cross-installing packages
-------------------------
For `MicroPython ports <MicroPython port>` without native networking
capabilities, the recommend process is "cross-installing" them into a
"directory image" using the `MicroPython Unix port`, and then
transferring this image to a device by suitable means.
Installing to a directory image involves using ``-p`` switch to `upip`::
micropython -m upip install -p install_dir micropython-pystone_lowmem
After this command, the package content (and contents of every depenency
packages) will be available in the ``install_dir/`` subdirectory. You
would need to transfer contents of this directory (without the
``install_dir/`` prefix) to the device, at the suitable location, where
it can be found by the Python ``import`` statement (see discussion of
the `upip` installation path above).
Cross-installing packages with freezing
---------------------------------------
For the low-memory `MicroPython ports <MicroPython port>`, the process
described in the previous section does not provide the most efficient
resource usage,because the packages are installed in the source form,
so need to be compiled to the bytecome on each import. This compilation
requires RAM, and the resulting bytecode is also stored in RAM, reducing
its amount available for storing application data. Moreover, the process
above requires presence of the filesystem on a device, and the most
resource-constrained devices may not even have it.
The bytecode freezing is a process which resolves all the issues
mentioned above:
* The source code is pre-compiled into bytecode and store as such.
* The bytecode is stored in ROM, not RAM.
* Filesystem is not required for frozen packages.
Using frozen bytecode requires building the executable (firmware)
for a given `MicroPython port` from the C source code. Consequently,
the process is:
1. Follow the instructions for a particular port on setting up a
toolchain and building the port. For example, for ESP8266 port,
study instructions in ``ports/esp8266/README.md`` and follow them.
Make sure you can build the port and deploy the resulting
executable/firmware successfully before proceeding to the next steps.
2. Build `MicroPython Unix port` and make sure it is in your PATH and
you can execute ``micropython``.
3. Change to port's directory (e.g. ``ports/esp8266/`` for ESP8266).
4. Run ``make clean-frozen``. This step cleans up any previous
modules which were installed for freezing (consequently, you need
to skip this step to add additional modules, instead of starting
from scratch).
5. Run ``micropython -m upip install -p modules <packages>...`` to
install packages you want to freeze.
6. Run ``make clean``.
7. Run ``make``.
After this, you should have the executable/firmware with modules as
the bytecode inside, which you can deploy the usual way.
Few notes:
1. Step 5 in the sequence above assumes that the distribution package
is available from PyPI. If that is not the case, you would need
to copy Python source files manually to ``modules/`` subdirectory
of the port port directory. (Note that upip does not support
installing from e.g. version control repositories).
2. The firmware for baremetal devices usually has size restrictions,
so adding too many frozen modules may overflow it. Usually, you
would get a linking error if this happens. However, in some cases,
an image may be produced, which is not runnable on a device. Such
cases are in general bugs, and should be reported and further
investigated. If you face such a situation, as an initial step,
you may want to decrease the amount of frozen modules included.
Creating distribution packages
------------------------------
Distribution packages for MicroPython are created in the same manner
as for CPython or any other Python implementation, see references at
the end of chapter. Setuptools (instead of distutils) should be used,
because distutils do not support dependencies and other features. "Source
distribution" (``sdist``) format is used for packaging. The post-processing
discussed above, (and pre-processing discussed in the following section)
is achieved by using custom ``sdist`` command for setuptools. Thus, packaging
steps remain the same as for the standard setuptools, the user just
needs to override ``sdist`` command implementation by passing the
appropriate argument to ``setup()`` call::
from setuptools import setup
import sdist_upip
setup(
...,
cmdclass={'sdist': sdist_upip.sdist}
)
The sdist_upip.py module as referenced above can be found in
`micropython-lib`:
https://github.com/micropython/micropython-lib/blob/master/sdist_upip.py
Application resources
---------------------
A complete application, besides the source code, oftentimes also consists
of data files, e.g. web page templates, game images, etc. It's clear how
to deal with those when application is installed manually - you just put
those data files in the filesystem at some location and use the normal
file access functions.
The situation is different when deploying applications from packages - this
is more advanced, streamlined and flexible way, but also requires more
advanced approach to accessing data files. This approach is treating
the data files as "resources", and abstracting away access to them.
Python supports resource access using its "setuptools" library, using
``pkg_resources`` module. MicroPython, following its usual approach,
implements subset of the functionality of that module, specifically
``pkg_resources.resource_stream(package, resource)`` function.
The idea is that an application calls this function, passing a
resource identifier, which is a relative path to data file within
the specified package (usually top-level application package). It
returns a stream object which can be used to access resource contents.
Thus, the ``resource_stream()`` emulates interface of the standard
`open()` function.
Implementation-wise, ``resource_stream()`` uses file operations
underlyingly, if distribution package is install in the filesystem.
However, it also supports functioning without the underlying filesystem,
e.g. if the package is frozen as the bytecode. This however requires
an extra intermediate step when packaging application - creation of
"Python resource module".
The idea of this module is to convert binary data to a Python bytes
object, and put it into the dictionary, indexed by the resource name.
This conversion is done automatically using overridden ``sdist`` command
described in the previous section.
Let's trace the complete process using the following example. Suppose
your application has the following structure::
my_app/
__main__.py
utils.py
data/
page.html
image.png
``__main__.py`` and ``utils.py`` should access resources using the
following calls::
import pkg_resources
pkg_resources.resource_stream(__name__, "data/page.html")
pkg_resources.resource_stream(__name__, "data/image.png")
You can develop and debug using the `MicroPython Unix port` as usual.
When time comes to make a distribution package out of it, just use
overridden "sdist" command from sdist_upip.py module as described in
the previous section.
This will create a Python resource module named ``R.py``, based on the
files declared in ``MANIFEST`` or ``MANIFEST.in`` files (any non-``.py``
file will be considered a resource and added to ``R.py``) - before
proceeding with the normal packaging steps.
Prepared like this, your application will work both when deployed to
filesystem and as frozen bytecode.
If you would like to debug ``R.py`` creation, you can run::
python3 setup.py sdist --manifest-only
Alternatively, you can use tools/mpy_bin2res.py script from the
MicroPython distribution, in which can you will need to pass paths
to all resource files::
mpy_bin2res.py data/page.html data/image.png
References
----------
* Python Packaging User Guide: https://packaging.python.org/
* Setuptools documentation: https://setuptools.readthedocs.io/
* Distutils documentation: https://docs.python.org/3/library/distutils.html

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@ -23,7 +23,7 @@ typedef uint32_t sys_prot_t;
#define LWIP_NETCONN 0
#define LWIP_SOCKET 0
#ifdef MICROPY_PY_LWIP_SLIP
#if MICROPY_PY_LWIP_SLIP
#define LWIP_HAVE_SLIPIF 1
#endif

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@ -69,12 +69,12 @@
#define ip_reset_option(pcb, opt) ((pcb)->so_options &= ~(opt))
#endif
#ifdef MICROPY_PY_LWIP_SLIP
#if MICROPY_PY_LWIP_SLIP
#include "netif/slipif.h"
#include "lwip/sio.h"
#endif
#ifdef MICROPY_PY_LWIP_SLIP
#if MICROPY_PY_LWIP_SLIP
/******************************************************************************/
// Slip object for modlwip. Requires a serial driver for the port that supports
// the lwip serial callback functions.
@ -1419,7 +1419,7 @@ STATIC mp_obj_t lwip_print_pcbs() {
}
MP_DEFINE_CONST_FUN_OBJ_0(lwip_print_pcbs_obj, lwip_print_pcbs);
#ifdef MICROPY_PY_LWIP
#if MICROPY_PY_LWIP
STATIC const mp_rom_map_elem_t mp_module_lwip_globals_table[] = {
{ MP_ROM_QSTR(MP_QSTR___name__), MP_ROM_QSTR(MP_QSTR_lwip) },
@ -1429,7 +1429,7 @@ STATIC const mp_rom_map_elem_t mp_module_lwip_globals_table[] = {
{ MP_ROM_QSTR(MP_QSTR_print_pcbs), MP_ROM_PTR(&lwip_print_pcbs_obj) },
// objects
{ MP_ROM_QSTR(MP_QSTR_socket), MP_ROM_PTR(&lwip_socket_type) },
#ifdef MICROPY_PY_LWIP_SLIP
#if MICROPY_PY_LWIP_SLIP
{ MP_ROM_QSTR(MP_QSTR_slip), MP_ROM_PTR(&lwip_slip_type) },
#endif
// class constants

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@ -29,6 +29,14 @@
#include "py/runtime.h"
static void check_not_unicode(const mp_obj_t arg) {
#if MICROPY_CPYTHON_COMPAT
if (MP_OBJ_IS_STR(arg)) {
mp_raise_TypeError("a bytes-like object is required");
}
#endif
}
#if MICROPY_PY_UHASHLIB
#if MICROPY_PY_UHASHLIB_SHA256
@ -47,20 +55,12 @@
#include "lib/axtls/crypto/crypto.h"
#endif
static void check_not_unicode(const mp_obj_t arg) {
#if MICROPY_CPYTHON_COMPAT
if (MP_OBJ_IS_STR(arg)) {
mp_raise_TypeError("a bytes-like object is required");
}
#endif
#if MICROPY_SSL_MBEDTLS
#include "mbedtls/sha1.h"
#endif
#endif
}
typedef struct _mp_obj_hash_t {
mp_obj_base_t base;

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@ -63,11 +63,11 @@ typedef struct _pyb_file_obj_t {
// These should be general types (mpy TOOD says so). In micropython, these are defined in
// mpconfigport.h.
#define mp_type_fileio mp_type_vfs_fat_fileio
#define mp_type_textio mp_type_vfs_fat_textio
////////////#define mp_type_fileio mp_type_vfs_fat_fileio
////////////#define mp_type_textio mp_type_vfs_fat_textio
extern const mp_obj_type_t mp_type_fileio;
extern const mp_obj_type_t mp_type_textio;
////////////extern const mp_obj_type_t mp_type_fileio;
////////////extern const mp_obj_type_t mp_type_textio;
extern const byte fresult_to_errno_table[20];
extern const mp_obj_type_t mp_fat_vfs_type;

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@ -36,6 +36,8 @@
#include "py/mphal.h"
#include "py/runtime.h"
#include "py/binary.h"
#include "py/objarray.h"
#include "lib/oofatfs/ff.h"
#include "lib/oofatfs/diskio.h"
#include "extmod/vfs_fat.h"
@ -51,62 +53,6 @@ STATIC fs_user_mount_t *disk_get_device(void *bdev) {
return (fs_user_mount_t*)bdev;
}
/*-----------------------------------------------------------------------*/
/* Initialize a Drive */
/*-----------------------------------------------------------------------*/
STATIC
DSTATUS disk_initialize (
bdev_t pdrv /* Physical drive number (0..) */
)
{
fs_user_mount_t *vfs = disk_get_device(pdrv);
if (vfs == NULL) {
return STA_NOINIT;
}
if (vfs->flags & FSUSER_HAVE_IOCTL) {
// new protocol with ioctl; call ioctl(INIT, 0)
vfs->u.ioctl[2] = MP_OBJ_NEW_SMALL_INT(BP_IOCTL_INIT);
vfs->u.ioctl[3] = MP_OBJ_NEW_SMALL_INT(0); // unused
mp_obj_t ret = mp_call_method_n_kw(2, 0, vfs->u.ioctl);
if (ret != mp_const_none && MP_OBJ_SMALL_INT_VALUE(ret) != 0) {
// error initialising
return STA_NOINIT;
}
}
if (vfs->writeblocks[0] == MP_OBJ_NULL) {
return STA_PROTECT;
} else {
return 0;
}
}
/*-----------------------------------------------------------------------*/
/* Get Disk Status */
/*-----------------------------------------------------------------------*/
STATIC
DSTATUS disk_status (
bdev_t pdrv /* Physical drive nmuber (0..) */
)
{
fs_user_mount_t *vfs = disk_get_device(pdrv);
if (vfs == NULL) {
return STA_NOINIT;
}
// This is used to determine the writeability of the disk from MicroPython.
// So, if its USB writable we make it read-only from MicroPython.
if (vfs->writeblocks[0] == MP_OBJ_NULL ||
(vfs->flags & FSUSER_USB_WRITABLE) != 0) {
return STA_PROTECT;
} else {
return 0;
}
}
/*-----------------------------------------------------------------------*/
/* Read Sector(s) */
/*-----------------------------------------------------------------------*/
@ -208,27 +154,56 @@ DRESULT disk_ioctl (
return RES_PARERR;
}
// First part: call the relevant method of the underlying block device
mp_obj_t ret = mp_const_none;
if (vfs->flags & FSUSER_HAVE_IOCTL) {
// new protocol with ioctl
static const uint8_t op_map[8] = {
[CTRL_SYNC] = BP_IOCTL_SYNC,
[GET_SECTOR_COUNT] = BP_IOCTL_SEC_COUNT,
[GET_SECTOR_SIZE] = BP_IOCTL_SEC_SIZE,
[IOCTL_INIT] = BP_IOCTL_INIT,
};
uint8_t bp_op = op_map[cmd & 7];
if (bp_op != 0) {
vfs->u.ioctl[2] = MP_OBJ_NEW_SMALL_INT(bp_op);
vfs->u.ioctl[3] = MP_OBJ_NEW_SMALL_INT(0); // unused
ret = mp_call_method_n_kw(2, 0, vfs->u.ioctl);
}
} else {
// old protocol with sync and count
switch (cmd) {
case CTRL_SYNC:
if (vfs->u.old.sync[0] != MP_OBJ_NULL) {
mp_call_method_n_kw(0, 0, vfs->u.old.sync);
}
break;
case GET_SECTOR_COUNT:
ret = mp_call_method_n_kw(0, 0, vfs->u.old.count);
break;
case GET_SECTOR_SIZE:
// old protocol has fixed sector size of 512 bytes
break;
case IOCTL_INIT:
// old protocol doesn't have init
break;
}
}
// Second part: convert the result for return
switch (cmd) {
case CTRL_SYNC:
vfs->u.ioctl[2] = MP_OBJ_NEW_SMALL_INT(BP_IOCTL_SYNC);
vfs->u.ioctl[3] = MP_OBJ_NEW_SMALL_INT(0); // unused
mp_call_method_n_kw(2, 0, vfs->u.ioctl);
return RES_OK;
case GET_SECTOR_COUNT: {
vfs->u.ioctl[2] = MP_OBJ_NEW_SMALL_INT(BP_IOCTL_SEC_COUNT);
vfs->u.ioctl[3] = MP_OBJ_NEW_SMALL_INT(0); // unused
mp_obj_t ret = mp_call_method_n_kw(2, 0, vfs->u.ioctl);
*((DWORD*)buff) = mp_obj_get_int(ret);
return RES_OK;
}
case GET_SECTOR_SIZE: {
vfs->u.ioctl[2] = MP_OBJ_NEW_SMALL_INT(BP_IOCTL_SEC_SIZE);
vfs->u.ioctl[3] = MP_OBJ_NEW_SMALL_INT(0); // unused
mp_obj_t ret = mp_call_method_n_kw(2, 0, vfs->u.ioctl);
if (ret == mp_const_none) {
// Default sector size
*((WORD*)buff) = 512;
@ -247,55 +222,23 @@ DRESULT disk_ioctl (
return RES_OK;
case IOCTL_INIT:
*((DSTATUS*)buff) = disk_initialize(pdrv);
return RES_OK;
case IOCTL_STATUS:
*((DSTATUS*)buff) = disk_status(pdrv);
return RES_OK;
default:
return RES_PARERR;
}
case IOCTL_STATUS: {
DSTATUS stat;
if (ret != mp_const_none && MP_OBJ_SMALL_INT_VALUE(ret) != 0) {
// error initialising
stat = STA_NOINIT;
} else if (vfs->writeblocks[0] == MP_OBJ_NULL) {
stat = STA_PROTECT;
} else {
// old protocol with sync and count
switch (cmd) {
case CTRL_SYNC:
if (vfs->u.old.sync[0] != MP_OBJ_NULL) {
mp_call_method_n_kw(0, 0, vfs->u.old.sync);
stat = 0;
}
return RES_OK;
case GET_SECTOR_COUNT: {
mp_obj_t ret = mp_call_method_n_kw(0, 0, vfs->u.old.count);
*((DWORD*)buff) = mp_obj_get_int(ret);
*((DSTATUS*)buff) = stat;
return RES_OK;
}
case GET_SECTOR_SIZE:
*((WORD*)buff) = 512; // old protocol had fixed sector size
#if _MAX_SS != _MIN_SS
// need to store ssize because we use it in disk_read/disk_write
vfs->fatfs.ssize = 512;
#endif
return RES_OK;
case GET_BLOCK_SIZE:
*((DWORD*)buff) = 1; // erase block size in units of sector size
return RES_OK;
case IOCTL_INIT:
*((DSTATUS*)buff) = disk_initialize(pdrv);
return RES_OK;
case IOCTL_STATUS:
*((DSTATUS*)buff) = disk_status(pdrv);
return RES_OK;
default:
return RES_PARERR;
}
}
}
#endif // MICROPY_VFS && MICROPY_VFS_FAT

@ -1 +1 @@
Subproject commit dac9176cac58cc5e49669a9a4d404a6f6dd7cc10
Subproject commit 43a6e6bd3bbc03dc501e16b89fba0ef042ed3ea0

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@ -26,8 +26,6 @@
#ifndef MICROPY_INCLUDED_LIB_MP_READLINE_READLINE_H
#define MICROPY_INCLUDED_LIB_MP_READLINE_READLINE_H
#include "py/misc.h"
#define CHAR_CTRL_A (1)
#define CHAR_CTRL_B (2)
#define CHAR_CTRL_C (3)

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@ -77,7 +77,7 @@ SRC_C = \
esp_init_data.c \
gccollect.c \
lexerstr32.c \
espuart.c \
uart.c \
esppwm.c \
espneopixel.c \
intr.c \
@ -193,7 +193,10 @@ LIB_SRC_C += \
lib/oofatfs/option/unicode.c
endif
DRIVERS_SRC_C = $(addprefix drivers/,\
bus/softspi.c \
)
SRC_S = \
gchelper.s \
@ -206,6 +209,7 @@ OBJ += $(addprefix $(BUILD)/, $(SRC_SHARED_MODULE_EXPANDED:.c=.o))
OBJ += $(addprefix $(BUILD)/, $(STM_SRC_C:.c=.o))
OBJ += $(addprefix $(BUILD)/, $(EXTMOD_SRC_C:.c=.o))
OBJ += $(addprefix $(BUILD)/, $(LIB_SRC_C:.c=.o))
OBJ += $(addprefix $(BUILD)/, $(DRIVERS_SRC_C:.c=.o))
# List of sources for qstr extraction
SRC_QSTR += $(SRC_C) $(SRC_COMMON_HAL_EXPANDED) $(SRC_SHARED_MODULE_EXPANDED) $(STM_SRC_C) $(EXTMOD_SRC_C) $(DRIVERS_SRC_C)

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@ -29,7 +29,7 @@
#include "shared-bindings/busio/UART.h"
#include "ets_sys.h"
#include "espuart.h"
#include "uart.h"
#include "py/nlr.h"

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@ -27,9 +27,11 @@
#include <string.h>
#include "esp_mphal.h"
#include "etshal.h"
#include "py/objtuple.h"
#include "py/objstr.h"
#include "extmod/misc.h"
#include "genhdr/mpversion.h"
#include "user_interface.h"
@ -75,19 +77,6 @@ bool common_hal_os_urandom(uint8_t* buffer, uint32_t length) {
i++;
new_random >>= 8;
}
// We wrap the mp_uos_dupterm function to detect if a UART is attached or not
mp_obj_t os_dupterm(size_t n_args, const mp_obj_t *args) {
mp_obj_t prev_obj = mp_uos_dupterm_obj.fun.var(n_args, args);
if (mp_obj_get_type(args[0]) == &pyb_uart_type) {
++uart_attached_to_dupterm;
}
if (mp_obj_get_type(prev_obj) == &pyb_uart_type) {
--uart_attached_to_dupterm;
}
return prev_obj;
}
STATIC MP_DEFINE_CONST_FUN_OBJ_VAR_BETWEEN(os_dupterm_obj, 1, 2, os_dupterm);
}
return true;
}

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@ -27,7 +27,7 @@
#include <stdio.h>
#include "ets_sys.h"
#include "etshal.h"
#include "espuart.h"
#include "uart.h"
#include "esp_mphal.h"
#include "user_interface.h"
#include "ets_alt_task.h"

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@ -16,7 +16,7 @@
#define NEO_KHZ400 (1)
void /*ICACHE_RAM_ATTR*/ esp_neopixel_write(uint8_t pin, uint8_t *pixels, uint32_t numBytes) {
void /*ICACHE_RAM_ATTR*/ esp_neopixel_write(uint8_t pin, uint8_t *pixels, uint32_t numBytes, bool is800KHz) {
uint8_t *p, *end, pix, mask;
uint32_t t, time0, time1, period, c, startTime, pinMask;
@ -30,10 +30,19 @@ void /*ICACHE_RAM_ATTR*/ esp_neopixel_write(uint8_t pin, uint8_t *pixels, uint32
uint32_t fcpu = system_get_cpu_freq() * 1000000;
#ifdef NEO_KHZ400
if(is800KHz) {
#endif
time0 = fcpu / 2857143; // 0.35us
time1 = fcpu / 1250000; // 0.8us
period = fcpu / 800000; // 1.25us per bit
#ifdef NEO_KHZ400
} else { // 400 KHz bitstream
time0 = fcpu / 2000000; // 0.5uS
time1 = fcpu / 833333; // 1.2us
period = fcpu / 400000; // 2.5us per bit
}
#endif
uint32_t irq_state = mp_hal_quiet_timing_enter();
for(t = time0;; t = time0) {

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@ -1,6 +1,6 @@
#ifndef MICROPY_INCLUDED_ESP8266_ESPNEOPIXEL_H
#define MICROPY_INCLUDED_ESP8266_ESPNEOPIXEL_H
void esp_neopixel_write(uint8_t pin, uint8_t *pixels, uint32_t numBytes);
void esp_neopixel_write(uint8_t pin, uint8_t *pixels, uint32_t numBytes, bool is800KHz);
#endif // MICROPY_INCLUDED_ESP8266_ESPNEOPIXEL_H

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@ -6,12 +6,14 @@
// see http://esp8266-re.foogod.com/wiki/Random_Number_Generator
#define WDEV_HWRNG ((volatile uint32_t*)0x3ff20e44)
void ets_delay_us(uint16_t us);
void ets_intr_lock(void);
void ets_intr_unlock(void);
void ets_isr_mask(uint32_t mask);
void ets_isr_unmask(uint32_t mask);
void ets_isr_attach(int irq_no, void (*handler)(void *), void *arg);
void ets_install_putc1();
void uart_div_modify(uint8_t uart, uint32_t divisor);
void ets_set_idle_cb(void (*handler)(void *), void *arg);
void ets_timer_arm_new(os_timer_t *tim, uint32_t millis, bool repeat, bool is_milli_timer);
@ -30,6 +32,12 @@ void MD5Init(MD5_CTX *context);
void MD5Update(MD5_CTX *context, const void *data, unsigned int len);
void MD5Final(unsigned char digest[16], MD5_CTX *context);
// These prototypes are for recent SDKs with "malloc tracking"
void *pvPortMalloc(size_t sz, const char *fname, unsigned line);
void *pvPortZalloc(size_t sz, const char *fname, unsigned line);
void *pvPortRealloc(void *p, unsigned sz, const char *fname, unsigned line);
void vPortFree(void *p, const char *fname, unsigned line);
uint32_t SPIRead(uint32_t offset, void *buf, uint32_t len);
uint32_t SPIWrite(uint32_t offset, const void *buf, uint32_t len);
uint32_t SPIEraseSector(int sector);

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@ -29,7 +29,7 @@
#include <string.h>
#include "ets_sys.h"
#include "espuart.h"
#include "uart.h"
#include "py/runtime.h"
#include "py/stream.h"

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@ -111,25 +111,6 @@ STATIC void mp_reset(void) {
readline_init0();
dupterm_task_init();
pwmout_reset();
// Check if there are any dupterm objects registered and if not then
// activate UART(0), or else there will never be any chance to get a REPL
size_t idx;
for (idx = 0; idx < MICROPY_PY_OS_DUPTERM; ++idx) {
if (MP_STATE_VM(dupterm_objs[idx]) != MP_OBJ_NULL) {
break;
}
}
if (idx == MICROPY_PY_OS_DUPTERM) {
mp_obj_t args[2];
args[0] = MP_OBJ_NEW_SMALL_INT(0);
args[1] = MP_OBJ_NEW_SMALL_INT(115200);
args[0] = pyb_uart_type.make_new(&pyb_uart_type, 2, 0, args);
args[1] = MP_OBJ_NEW_SMALL_INT(1);
extern mp_obj_t os_dupterm(size_t n_args, const mp_obj_t *args);
os_dupterm(2, args);
mp_hal_stdout_tx_str("Activated UART(0) for REPL\r\n");
}
}
bool soft_reset(void) {

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@ -30,7 +30,7 @@
#include "py/runtime.h"
#include "py/mperrno.h"
#include "py/mphal.h"
#include "espuart.h"
#include "uart.h"
#include "user_interface.h"
#include "mem.h"
#include "modmachine.h"

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@ -426,9 +426,9 @@ STATIC mp_obj_t esp_config(size_t n_args, const mp_obj_t *args, mp_map_t *kwargs
}
case MP_QSTR_essid:
if (self->if_id == STATION_IF) {
val = mp_obj_new_str((char*)cfg.sta.ssid, strlen((char*)cfg.sta.ssid), false);
val = mp_obj_new_str((char*)cfg.sta.ssid, strlen((char*)cfg.sta.ssid));
} else {
val = mp_obj_new_str((char*)cfg.ap.ssid, cfg.ap.ssid_len, false);
val = mp_obj_new_str((char*)cfg.ap.ssid, cfg.ap.ssid_len);
}
break;
case MP_QSTR_hidden:

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@ -48,8 +48,6 @@ def setup():
# This file is executed on every boot (including wake-boot from deepsleep)
#import esp
#esp.osdebug(None)
import uos, machine
uos.dupterm(machine.UART(0, 115200), 1)
import gc
#import webrepl
#webrepl.start()

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@ -34,6 +34,12 @@ def exists(fname):
except OSError:
return False
def copy_stream(s_in, s_out):
buf = bytearray(64)
while 1:
sz = s_in.readinto(buf)
s_out.write(buf, sz)
def get_daemon_status():
with open(RC) as f:
@ -44,6 +50,10 @@ def get_daemon_status():
return True
return None
def add_daemon():
with open(RC) as old_f, open(RC + ".tmp", "w") as new_f:
new_f.write("import webrepl\nwebrepl.start()\n")
copy_stream(old_f, new_f)
def change_daemon(action):
LINES = ("import webrepl", "webrepl.start()")

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@ -75,7 +75,7 @@ STATIC mp_obj_t time_localtime(size_t n_args, const mp_obj_t *args) {
};
return mp_obj_new_tuple(8, tuple);
}
MP_DEFINE_CONST_FUN_OBJ_VAR_BETWEEN(utime_localtime_obj, 0, 1, time_localtime);
MP_DEFINE_CONST_FUN_OBJ_VAR_BETWEEN(time_localtime_obj, 0, 1, time_localtime);
/// \function mktime()
/// This is inverse function of localtime. It's argument is a full 8-tuple
@ -95,7 +95,7 @@ STATIC mp_obj_t time_mktime(mp_obj_t tuple) {
mp_obj_get_int(elem[1]), mp_obj_get_int(elem[2]), mp_obj_get_int(elem[3]),
mp_obj_get_int(elem[4]), mp_obj_get_int(elem[5])));
}
MP_DEFINE_CONST_FUN_OBJ_1(utime_mktime_obj, time_mktime);
MP_DEFINE_CONST_FUN_OBJ_1(time_mktime_obj, time_mktime);
/// \function time()
/// Returns the number of seconds, as an integer, since 1/1/2000.
@ -103,13 +103,13 @@ STATIC mp_obj_t time_time(void) {
// get date and time
return mp_obj_new_int(pyb_rtc_get_us_since_2000() / 1000 / 1000);
}
MP_DEFINE_CONST_FUN_OBJ_0(utime_time_obj, time_time);
MP_DEFINE_CONST_FUN_OBJ_0(time_time_obj, time_time);
STATIC const mp_rom_map_elem_t time_module_globals_table[] = {
{ MP_ROM_QSTR(MP_QSTR___name__), MP_ROM_QSTR(MP_QSTR_utime) },
{ MP_ROM_QSTR(MP_QSTR_localtime), MP_ROM_PTR(&utime_localtime_obj) },
{ MP_ROM_QSTR(MP_QSTR_mktime), MP_ROM_PTR(&utime_mktime_obj) },
{ MP_ROM_QSTR(MP_QSTR_localtime), MP_ROM_PTR(&time_localtime_obj) },
{ MP_ROM_QSTR(MP_QSTR_mktime), MP_ROM_PTR(&time_mktime_obj) },
{ MP_ROM_QSTR(MP_QSTR_sleep), MP_ROM_PTR(&mp_utime_sleep_obj) },
{ MP_ROM_QSTR(MP_QSTR_sleep_ms), MP_ROM_PTR(&mp_utime_sleep_ms_obj) },
{ MP_ROM_QSTR(MP_QSTR_sleep_us), MP_ROM_PTR(&mp_utime_sleep_us_obj) },
@ -118,7 +118,7 @@ STATIC const mp_rom_map_elem_t time_module_globals_table[] = {
{ MP_ROM_QSTR(MP_QSTR_ticks_cpu), MP_ROM_PTR(&mp_utime_ticks_cpu_obj) },
{ MP_ROM_QSTR(MP_QSTR_ticks_add), MP_ROM_PTR(&mp_utime_ticks_add_obj) },
{ MP_ROM_QSTR(MP_QSTR_ticks_diff), MP_ROM_PTR(&mp_utime_ticks_diff_obj) },
{ MP_ROM_QSTR(MP_QSTR_time), MP_ROM_PTR(&utime_time_obj) },
{ MP_ROM_QSTR(MP_QSTR_time), MP_ROM_PTR(&time_time_obj) },
};
STATIC MP_DEFINE_CONST_DICT(time_module_globals, time_module_globals_table);

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@ -91,7 +91,7 @@
#define MICROPY_PY_FRAMEBUF (1)
#define MICROPY_PY_MICROPYTHON_MEM_INFO (1)
#define MICROPY_PY_OS_DUPTERM (2)
#define MICROPY_CPYTHON_COMPAT (0)
#define MICROPY_CPYTHON_COMPAT (1)
#define MICROPY_LONGINT_IMPL (MICROPY_LONGINT_IMPL_MPZ)
#define MICROPY_FLOAT_IMPL (MICROPY_FLOAT_IMPL_FLOAT)
#define MICROPY_FLOAT_HIGH_QUALITY_HASH (1)

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@ -11,7 +11,7 @@
*******************************************************************************/
#include "ets_sys.h"
#include "osapi.h"
#include "espuart.h"
#include "uart.h"
#include "osapi.h"
#include "uart_register.h"
#include "etshal.h"

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@ -67,10 +67,6 @@
#define MICROPY_VFS (1)
#define MICROPY_VFS_FAT (MICROPY_VFS)
// TODO these should be generic, not bound to fatfs
#define mp_type_fileio fatfs_type_fileio
#define mp_type_textio fatfs_type_textio
// use vfs's functions for import stat and builtin open
#if MICROPY_VFS
#define mp_import_stat mp_vfs_import_stat

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@ -112,7 +112,7 @@ void asm_x86_mov_r32_to_local(asm_x86_t* as, int src_r32, int dest_local_num);
void asm_x86_mov_local_addr_to_r32(asm_x86_t* as, int local_num, int dest_r32);
void asm_x86_call_ind(asm_x86_t* as, void* ptr, mp_uint_t n_args, int temp_r32);
#ifdef GENERIC_ASM_API
#if defined(GENERIC_ASM_API) && GENERIC_ASM_API
// The following macros provide a (mostly) arch-independent API to
// generate native code, and are used by the native emitter.

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@ -110,6 +110,7 @@ qstr mp_errno_to_str(mp_obj_t errno_val) {
case EEXIST: return MP_QSTR_File_space_exists;
case ENODEV: return MP_QSTR_Unsupported_space_operation;
case EINVAL: return MP_QSTR_Invalid_space_argument;
case EROFS: return MP_QSTR_Read_hyphen_only_space_filesystem;
}
}

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@ -112,9 +112,8 @@ mp_obj_t common_hal_os_listdir(const char* path) {
mp_obj_t dir_list = mp_obj_new_list(0, NULL);
mp_obj_t next;
while ((next = mp_iternext(iter_obj)) != MP_OBJ_STOP_ITERATION) {
mp_obj_t *items;
mp_obj_get_array_fixed_n(next, 3, &items);
mp_obj_list_append(dir_list, items[0]);
// next[0] is the filename.
mp_obj_list_append(dir_list, mp_obj_subscr(next, MP_OBJ_NEW_SMALL_INT(0), MP_OBJ_SENTINEL));
}
return dir_list;
}