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:mod:`uctypes` -- access binary data in a structured way
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========================================================
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.. module:: uctypes
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:synopsis: access binary data in a structured way
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This module implements "foreign data interface" for MicroPython. The idea
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behind it is similar to CPython's ``ctypes`` modules, but the actual API is
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different, streamlined and optimized for small size. The basic idea of the
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module is to define data structure layout with about the same power as the
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C language allows, and the access it using familiar dot-syntax to reference
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sub-fields.
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.. seealso::
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Module :mod:`ustruct`
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Standard Python way to access binary data structures (doesn't scale
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well to large and complex structures).
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Defining structure layout
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-------------------------
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Structure layout is defined by a "descriptor" - a Python dictionary which
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encodes field names as keys and other properties required to access them as
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associated values. Currently, uctypes requires explicit specification of
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offsets for each field. Offset are given in bytes from a structure start.
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Following are encoding examples for various field types:
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* Scalar types::
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"field_name": uctypes.UINT32 | 0
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in other words, value is scalar type identifier ORed with field offset
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(in bytes) from the start of the structure.
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* Recursive structures::
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"sub": (2, {
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"b0": uctypes.UINT8 | 0,
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"b1": uctypes.UINT8 | 1,
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})
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i.e. value is a 2-tuple, first element of which is offset, and second is
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a structure descriptor dictionary (note: offsets in recursive descriptors
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are relative to a structure it defines).
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* Arrays of primitive types::
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"arr": (uctypes.ARRAY | 0, uctypes.UINT8 | 2),
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i.e. value is a 2-tuple, first element of which is ARRAY flag ORed
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with offset, and second is scalar element type ORed number of elements
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in array.
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* Arrays of aggregate types::
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"arr2": (uctypes.ARRAY | 0, 2, {"b": uctypes.UINT8 | 0}),
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i.e. value is a 3-tuple, first element of which is ARRAY flag ORed
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with offset, second is a number of elements in array, and third is
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descriptor of element type.
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* Pointer to a primitive type::
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"ptr": (uctypes.PTR | 0, uctypes.UINT8),
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i.e. value is a 2-tuple, first element of which is PTR flag ORed
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with offset, and second is scalar element type.
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* Pointer to an aggregate type::
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"ptr2": (uctypes.PTR | 0, {"b": uctypes.UINT8 | 0}),
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i.e. value is a 2-tuple, first element of which is PTR flag ORed
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with offset, second is descriptor of type pointed to.
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* Bitfields::
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"bitf0": uctypes.BFUINT16 | 0 | 0 << uctypes.BF_POS | 8 << uctypes.BF_LEN,
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i.e. value is type of scalar value containing given bitfield (typenames are
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similar to scalar types, but prefixes with "BF"), ORed with offset for
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scalar value containing the bitfield, and further ORed with values for
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bit offset and bit length of the bitfield within scalar value, shifted by
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BF_POS and BF_LEN positions, respectively. Bitfield position is counted
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from the least significant bit, and is the number of right-most bit of a
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field (in other words, it's a number of bits a scalar needs to be shifted
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right to extra the bitfield).
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In the example above, first UINT16 value will be extracted at offset 0
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(this detail may be important when accessing hardware registers, where
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particular access size and alignment are required), and then bitfield
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whose rightmost bit is least-significant bit of this UINT16, and length
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is 8 bits, will be extracted - effectively, this will access
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least-significant byte of UINT16.
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Note that bitfield operations are independent of target byte endianness,
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in particular, example above will access least-significant byte of UINT16
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in both little- and big-endian structures. But it depends on the least
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significant bit being numbered 0. Some targets may use different
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numbering in their native ABI, but ``uctypes`` always uses normalized
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numbering described above.
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Module contents
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---------------
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.. class:: struct(addr, descriptor, layout_type=NATIVE)
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Instantiate a "foreign data structure" object based on structure address in
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memory, descriptor (encoded as a dictionary), and layout type (see below).
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.. data:: LITTLE_ENDIAN
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Layout type for a little-endian packed structure. (Packed means that every
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field occupies exactly as many bytes as defined in the descriptor, i.e.
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the alignment is 1).
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.. data:: BIG_ENDIAN
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Layour type for a big-endian packed structure.
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.. data:: NATIVE
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Layout type for a native structure - with data endianness and alignment
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conforming to the ABI of the system on which MicroPython runs.
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.. function:: sizeof(struct)
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Return size of data structure in bytes. Argument can be either structure
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class or specific instantiated structure object (or its aggregate field).
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.. function:: addressof(obj)
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Return address of an object. Argument should be bytes, bytearray or
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other object supporting buffer protocol (and address of this buffer
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is what actually returned).
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.. function:: bytes_at(addr, size)
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Capture memory at the given address and size as bytes object. As bytes
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object is immutable, memory is actually duplicated and copied into
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bytes object, so if memory contents change later, created object
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retains original value.
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.. function:: bytearray_at(addr, size)
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Capture memory at the given address and size as bytearray object.
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Unlike bytes_at() function above, memory is captured by reference,
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so it can be both written too, and you will access current value
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at the given memory address.
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Structure descriptors and instantiating structure objects
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---------------------------------------------------------
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Given a structure descriptor dictionary and its layout type, you can
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instantiate a specific structure instance at a given memory address
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using :class:`uctypes.struct()` constructor. Memory address usually comes from
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following sources:
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* Predefined address, when accessing hardware registers on a baremetal
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system. Lookup these addresses in datasheet for a particular MCU/SoC.
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* As a return value from a call to some FFI (Foreign Function Interface)
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function.
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* From uctypes.addressof(), when you want to pass arguments to an FFI
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function, or alternatively, to access some data for I/O (for example,
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data read from a file or network socket).
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Structure objects
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-----------------
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Structure objects allow accessing individual fields using standard dot
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notation: ``my_struct.substruct1.field1``. If a field is of scalar type,
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getting it will produce a primitive value (Python integer or float)
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corresponding to the value contained in a field. A scalar field can also
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be assigned to.
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If a field is an array, its individual elements can be accessed with
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the standard subscript operator ``[]`` - both read and assigned to.
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If a field is a pointer, it can be dereferenced using ``[0]`` syntax
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(corresponding to C ``*`` operator, though ``[0]`` works in C too).
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Subscripting a pointer with other integer values but 0 are supported too,
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with the same semantics as in C.
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Summing up, accessing structure fields generally follows C syntax,
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except for pointer derefence, when you need to use ``[0]`` operator
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instead of ``*``.
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Limitations
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-----------
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Accessing non-scalar fields leads to allocation of intermediate objects
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to represent them. This means that special care should be taken to
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layout a structure which needs to be accessed when memory allocation
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is disabled (e.g. from an interrupt). The recommendations are:
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* Avoid nested structures. For example, instead of
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``mcu_registers.peripheral_a.register1``, define separate layout
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descriptors for each peripheral, to be accessed as
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``peripheral_a.register1``.
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* Avoid other non-scalar data, like array. For example, instead of
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``peripheral_a.register[0]`` use ``peripheral_a.register0``.
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Note that these recommendations will lead to decreased readability
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and conciseness of layouts, so they should be used only if the need
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to access structure fields without allocation is anticipated (it's
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even possible to define 2 parallel layouts - one for normal usage,
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and a restricted one to use when memory allocation is prohibited).
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