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docs: Add reference for Thumb2 inline assembler. 

Thanks to Peter Hinch for contributing this.
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docs/pyboard/tutorial/assembler.rst
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.. _pyboard_tutorial_assembler:
Inline assembler
================

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Arithmetic instructions
=======================
Document conventions
--------------------
Notation: ``Rd, Rm, Rn`` denote ARM registers R0-R7. ``immN`` denotes an immediate
value having a width of N bits e.g. ``imm8``, ``imm3``. ``carry`` denotes
the carry condition flag, ``not(carry)`` denotes its complement. In the case of instructions
with more than one register argument, it is permissible for some to be identical. For example
the following will add the contents of R0 to itself, placing the result in R0:
* add(r0, r0, r0)
Arithmetic instructions affect the condition flags except where stated.
Addition
--------
* add(Rdn, imm8) ``Rdn = Rdn + imm8``
* add(Rd, Rn, imm3) ``Rd = Rn + imm3``
* add(Rd, Rn, Rm) ``Rd = Rn +Rm``
* adc(Rd, Rn) ``Rd = Rd + Rn + carry``
Subtraction
-----------
* sub(Rdn, imm8) ``Rdn = Rdn - imm8``
* sub(Rd, Rn, imm3) ``Rd = Rn - imm3``
* sub(Rd, Rn, Rm) ``Rd = Rn - Rm``
* sbc(Rd, Rn) ``Rd = Rd - Rn - not(carry)``
Negation
--------
* neg(Rd, Rn) ``Rd = -Rn``
Multiplication and division
---------------------------
* mul(Rd, Rn) ``Rd = Rd * Rn``
This produces a 32 bit result with overflow lost. The result may be treated as
signed or unsigned according to the definition of the operands.
* sdiv(Rd, Rn, Rm) ``Rd = Rn / Rm``
* udiv(Rd, Rn, Rm) ``Rd = Rn / Rm``
These functions perform signed and unsigned division respectively. Condition flags
are not affected.

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Comparison instructions
=======================
These perform an arithmetic or logical instruction on two arguments, discarding the result
but setting the condition flags. Typically these are used to test data values without changing
them prior to executing a conditional branch.
Document conventions
--------------------
Notation: ``Rd, Rm, Rn`` denote ARM registers R0-R7. ``imm8`` denotes an immediate
value having a width of 8 bits.
The Application Program Status Register (APSR)
----------------------------------------------
This contains four bits which are tested by the conditional branch instructions. Typically a
conditional branch will test multiple bits, for example ``bge(LABEL)``. The meaning of
condition codes can depend on whether the operands of an arithmetic instruction are viewed as
signed or unsigned integers. Thus ``bhi(LABEL)`` assumes unsigned numbers were processed while
``bgt(LABEL)`` assumes signed operands.
APSR Bits
---------
* Z (zero)
This is set if the result of an operation is zero or the operands of a comparison are equal.
* N (negative)
Set if the result is negative.
* C (carry)
An addition sets the carry flag when the result overflows out of the MSB, for example adding
0x80000000 and 0x80000000. By the nature of two's complement arithmetic this behaviour is reversed
on subtraction, with a borrow indicated by the carry bit being clear. Thus 0x10 - 0x01 is executed
as 0x10 + 0xffffffff which will set the carry bit.
* V (overflow)
The overflow flag is set if the result, viewed as a two's compliment number, has the "wrong" sign
in relation to the operands. For example adding 1 to 0x7fffffff will set the overflow bit because
the result (0x8000000), viewed as a two's complement integer, is negative. Note that in this instance
the carry bit is not set.
Comparison instructions
-----------------------
These set the APSR (Application Program Status Register) N (negative), Z (zero), C (carry) and V
(overflow) flags.
* cmp(Rn, imm8) ``Rn - imm8``
* cmp(Rn, Rm) ``Rn - Rm``
* cmn(Rn, Rm) ``Rn + Rm``
* tst(Rn, Rm) ``Rn & Rm``
Conditional execution
---------------------
The ``it`` and ``ite`` instructions provide a means of conditionally executing from one to four subsequent
instructions without the need for a label.
* it(<condition>) If then
Execute the next instruction if <condition> is true:
::
cmp(r0, r1)
it(eq)
mov(r0, 100) # runs if r0 == r1
# execution continues here
* ite(<condition>) If then else
If <condtion> is true, execute the next instruction, otherwise execute the
subsequent one. Thus:
::
cmp(r0, r1)
ite(eq)
mov(r0, 100) # runs if r0 == r1
mov(r0, 200) # runs if r0 != r1
# execution continues here
This may be extended to control the execution of upto four subsequent instructions: it[x[y[z]]]
where x,y,z=t/e; e.g. itt, itee, itete, ittte, itttt, iteee, etc.

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Assembler Directives
====================
Labels
------
* label(INNER1)
This defines a label for use in a branch instruction. Thus elsewhere in the code a ``b(INNER1)``
will cause execution to continue with the instruction after the label directive.
Defining inline data
--------------------
The following assembler directives facilitate embedding data in an assembler code block.
* data(size, d0, d1 .. dn)
The data directive creates n array of data values in memory. The first argument specifies the
size in bytes of the subsequent arguments. Hence the first statement below will cause the
assembler to put three bytes (with values 2, 3 and 4) into consecutive memory locations
while the second will cause it to emit two four byte words.
::
data(1, 2, 3, 4)
data(4, 2, 100000)
Data values longer than a single byte are stored in memory in little-endian format.
* align(nBytes)
Align the following instruction to an nBytes value. ARM Thumb-2 instructions must be two
byte aligned, hence it's advisable to issue ``align(2)`` after ``data`` directives and
prior to any subsequent code. This ensures that the code will run irrespective of the
size of the data array.

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Floating Point instructions
==============================
These instructions support the use of the ARM floating point coprocessor
(on platforms such as the Pyboard which are equipped with one). The FPU
has 32 registers known as ``s0-s31`` each of which can hold a single
precision float. Data can be passed between the FPU registers and the
ARM core registers with the ``vmov`` instruction.
Note that MicroPython doesn't support passing floats to
assembler functions, nor can you put a float into ``r0`` and expect a
reasonable result. There are two ways to overcome this. The first is to
use arrays, and the second is to pass and/or return integers and convert
to and from floats in code.
Document conventions
--------------------
Notation: ``Sd, Sm, Sn`` denote FPU registers, ``Rd, Rm, Rn`` denote ARM core
registers. The latter can be any ARM core register although registers
``R13-R15`` are unlikely to be appropriate in this context.
Arithmetic
----------
* vadd(Sd, Sn, Sm) ``Sd = Sn + Sm``
* vsub(Sd, Sn, Sm) ``Sd = Sn - Sm``
* vneg(Sd, Sm) ``Sd = -Sm``
* vmul(Sd, Sn, Sm) ``Sd = Sn * Sm``
* vdiv(Sd, Sn, Sm) ``Sd = Sn / Sm``
* vsqrt(Sd, Sm) ``Sd = sqrt(Sm)``
Registers may be identical: ``vmul(S0, S0, S0)`` will execute ``S0 = S0*S0``
Move between ARM core and FPU registers
---------------------------------------
* vmov(Sd, Rm) ``Sd = Rm``
* vmov(Rd, Sm) ``Rd = Sm``
The FPU has a register known as FPSCR, similar to the ARM core's APSR, which stores condition
codes plus other data. The following instructions provide access to this.
* vmrs(APSR\_nzcv, FPSCR)
Move the floating-point N, Z, C, and V flags to the APSR N, Z, C, and V flags.
This is done after an instruction such as an FPU
comparison to enable the condition codes to be tested by the assembler
code. The following is a more general form of the instruction.
* vmrs(Rd, FPSCR) ``Rd = FPSCR``
Move between FPU register and memory
------------------------------------
* vldr(Sd, [Rn, offset]) ``Sd = [Rn + offset]``
* vstr(Sd, [Rn, offset]) ``[Rn + offset] = Sd``
Where ``[Rn + offset]`` denotes the memory address obtained by adding Rn to the offset. This
is specified in bytes. Since each float value occupies a 32 bit word, when accessing arrays of
floats the offset must always be a multiple of four bytes.
Data Comparison
---------------
* vcmp(Sd, Sm)
Compare the values in Sd and Sm and set the FPU N, Z,
C, and V flags. This would normally be followed by ``vmrs(APSR_nzcv, FPSCR)``
to enable the results to be tested.
Convert between integer and float
---------------------------------
* vcvt\_f32\_s32(Sd, Sm) ``Sd = float(Sm)``
* vcvt\_s32\_f32(Sd, Sm) ``Sd = int(Sm)``

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Hints and tips
==============
The following are some examples of the use of the inline assembler and some
information on how to work around its limitations. In this document the term
"assembler function" refers to a function declared in Python with the
``@micropython.asm_thumb`` decorator, whereas "subroutine" refers to assembler
code called from within an assembler function.
Code branches and subroutines
-----------------------------
It is important to appreciate that labels are local to an assembler function.
There is currently no way for a subroutine defined in one function to be called
from another.
To call a subroutine the instruction ``bl(LABEL)`` is issued. This transfers
control to the instruction following the ``label(LABEL)`` directive and stores
the return address in the link register (``lr`` or ``r14``). To return the
instruction ``bx(lr)`` is issued which causes execution to continue with
the instruction following the subroutine call. This mechanism implies that, if
a subroutine is to call another, it must save the link register prior to
the call and restore it before terminating.
The following rather contrived example illustrates a function call. Note that
it's necessary at the start to branch around all subroutine calls: subroutines
end execution with ``bx(lr)`` while the outer function simply "drops off the end"
in the style of Python functions.
::
@micropython.asm_thumb
def quad(r0):
b(START)
label(DOUBLE)
add(r0, r0, r0)
bx(lr)
label(START)
bl(DOUBLE)
bl(DOUBLE)
print(quad(10))
The following code example demonstrates a nested (recursive) call: the classic
Fibonacci sequence. Here, prior to a recursive call, the link register is saved
along with other registers which the program logic requires to be preserved.
::
@micropython.asm_thumb
def fib(r0):
b(START)
label(DOFIB)
push({r1, r2, lr})
cmp(r0, 1)
ble(FIBDONE)
sub(r0, 1)
mov(r2, r0) # r2 = n -1
bl(DOFIB)
mov(r1, r0) # r1 = fib(n -1)
sub(r0, r2, 1)
bl(DOFIB) # r0 = fib(n -2)
add(r0, r0, r1)
label(FIBDONE)
pop({r1, r2, lr})
bx(lr)
label(START)
bl(DOFIB)
for n in range(10):
print(fib(n))
Argument passing and return
---------------------------
The tutorial details the fact that assembler functions can support from zero to
three arguments, which must (if used) be named ``r0``, ``r1`` and ``r2``. When
the code executes the registers will be initialised to those values.
The data types which can be passed in this way are integers and memory
addresses. Further, integers are restricted in that the top two bits
must be identical, limiting the range to -2**30 to 2**30 -1. Return
values are similarly limited. These limitations can be overcome by means
of the ``array`` module to allow any number of values of any type to
be accessed.
Multiple arguments
~~~~~~~~~~~~~~~~~~
If a Python array of integers is passed as an argument to an assembler
function, the function will receive the address of a contiguous set of integers.
Thus multiple arguments can be passed as elements of a single array. Similarly a
function can return multiple values by assigning them to array elements.
Assembler functions have no means of determining the length of an array:
this will need to be passed to the function.
This use of arrays can be extended to enable more than three arrays to be used.
This is done using indirection: the ``uctypes`` module supports ``addressof()``
which will return the address of an array passed as its argument. Thus you can
populate an integer array with the addresses of other arrays:
::
from uctypes import addressof
@micropython.asm_thumb
def getindirect(r0):
ldr(r0, [r0, 0]) # Address of array loaded from passed array
ldr(r0, [r0, 4]) # Return element 1 of indirect array (24)
def testindirect():
a = array.array('i',[23, 24])
b = array.array('i',[0,0])
b[0] = addressof(a)
print(getindirect(b))
Non-integer data types
~~~~~~~~~~~~~~~~~~~~~~
These may be handled by means of arrays of the appropriate data type. For
example, single precison floating point data may be processed as follows.
This code example takes an array of floats and replaces its contents with
their squares.
::
from array import array
@micropython.asm_thumb
def square(r0, r1):
label(LOOP)
vldr(s0, [r0, 0])
vmul(s0, s0, s0)
vstr(s0, [r0, 0])
add(r0, 4)
sub(r1, 1)
bgt(LOOP)
a = array('f', (x for x in range(10)))
square(a, len(a))
print(a)
The uctypes module supports the use of data structures beyond simple
arrays. It enables a Python data structure to be mapped onto a bytearray
instance which may then be passed to the assembler function.
Named constants
---------------
Assembler code may be made more readable and maintainable by using named
constants rather than littering code with numbers. This may be achieved
thus:
::
MYDATA = const(33)
@micropython.asm_thumb
def foo():
mov(r0, MYDATA)
The const() construct causes MicroPython to replace the variable name
with its value at compile time. If constants are declared in an outer
Python scope they can be shared between mutiple assembler functions and
with Python code.
Assembler code as class methods
-------------------------------
MicroPython passes the address of the object instance as the first argument
to class methods. This is normally of little use to an assembler function.
It can be avoided by declaring the function as a static method thus:
::
class foo:
@staticmethod
@micropython.asm_thumb
def bar(r0):
add(r0, r0, r0)
Use of unsupported instructions
-------------------------------
These can be coded using the data statement as shown below. While
``push()`` and ``pop()`` are supported the example below illustrates the
principle. The necessary machine code may be found in the ARM v7-M
Architecture Reference Manual. Note that the first argument of data
calls such as
::
data(2, 0xe92d, 0x0f00) # push r8,r9,r10,r11
indicates that each subsequent argument is a two byte quantity.
Overcoming MicroPython's integer restriction
--------------------------------------------
The Pyboard chip includes a CRC generator. Its use presents a problem in
MicroPython because the returned values cover the full gamut of 32 bit
quantities whereas small integers in MicroPython cannot have differing values
in bits 30 and 31. This limitation is overcome with the following code, which
uses assembler to put the result into an array and Python code to
coerce the result into an arbitrary precision unsigned integer.
::
from array import array
import stm
def enable_crc():
stm.mem32[stm.RCC + stm.RCC_AHB1ENR] |= 0x1000
def reset_crc():
stm.mem32[stm.CRC+stm.CRC_CR] = 1
@micropython.asm_thumb
def getval(r0, r1):
movwt(r3, stm.CRC + stm.CRC_DR)
str(r1, [r3, 0])
ldr(r2, [r3, 0])
str(r2, [r0, 0])
def getcrc(value):
a = array('i', [0])
getval(a, value)
return a[0] & 0xffffffff # coerce to arbitrary precision
enable_crc()
reset_crc()
for x in range(20):
print(hex(getcrc(0)))

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.. _asm_thumb2_index:
Inline Assembler for Thumb2 architectures
=========================================
This document assumes some familiarity with assembly language programming and should be read after studying
the :ref:`tutorial <pyboard_tutorial_assembler>`. For a detailed description of the instruction set consult the
Architecture Reference Manual detailed below.
The inline assembler supports a subset of the ARM Thumb-2 instruction set described here. The syntax tries
to be as close as possible to that defined in the above ARM manual, converted to Python function calls.
Instructions operate on 32 bit signed integer data except where stated otherwise. Most supported instructions
operate on registers ``R0-R7`` only: where ``R8-R15`` are supported this is stated. Registers ``R8-R12`` must be
restored to their initial value before return from a function. Registers ``R13-R15`` constitute the Link Register,
Stack Pointer and Program Counter respectively.
Document conventions
--------------------
Where possible the behaviour of each instruction is described in Python, for example
* add(Rd, Rn, Rm) ``Rd = Rn + Rm``
This enables the effect of instructions to be demonstrated in Python. In certain case this is impossible
because Python doesn't support concepts such as indirection. The pseudocode employed in such cases is
described on the relevant page.
Instruction Categories
----------------------
The following sections details the subset of the ARM Thumb-2 instruction set supported by MicroPython.
.. toctree::
:maxdepth: 1
:numbered:
asm_thumb2_mov.rst
asm_thumb2_ldr.rst
asm_thumb2_str.rst
asm_thumb2_logical_bit.rst
asm_thumb2_arith.rst
asm_thumb2_compare.rst
asm_thumb2_label_branch.rst
asm_thumb2_stack.rst
asm_thumb2_misc.rst
asm_thumb2_float.rst
asm_thumb2_directives.rst
Usage examples
--------------
These sections provide further code examples and hints on the use of the assembler.
.. toctree::
:maxdepth: 1
:numbered:
asm_thumb2_hints_tips.rst
References
----------
- :ref:`Assembler Tutorial <pyboard_tutorial_assembler>`
- `Wiki hints and tips
<http://wiki.micropython.org/platforms/boards/pyboard/assembler>`__
- `uPy Inline Assembler source-code,
emitinlinethumb.c <https://github.com/micropython/micropython/blob/master/py/emitinlinethumb.c>`__
- `ARM Thumb2 Instruction Set Quick Reference
Card <http://infocenter.arm.com/help/topic/com.arm.doc.qrc0001l/QRC0001_UAL.pdf>`__
- `RM0090 Reference
Manual <http://www.google.ae/url?sa=t&rct=j&q=&esrc=s&source=web&cd=1&cad=rja&uact=8&sqi=2&ved=0CBoQFjAA&url=http%3A%2F%2Fwww.st.com%2Fst-web-ui%2Fstatic%2Factive%2Fen%2Fresource%2Ftechnical%2Fdocument%2Freference_manual%2FDM00031020.pdf&ei=G0rSU66xFeuW0QWYwoD4CQ&usg=AFQjCNFuW6TgzE4QpahO_U7g3f3wdwecAg&sig2=iET-R0y9on_Pbflzf9aYDw&bvm=bv.71778758,bs.1,d.bGQ>`__
- ARM v7-M Architecture Reference Manual (Available on the
ARM site after a simple registration procedure. Also available on academic sites but beware of out of date versions.)

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Branch instructions
===================
These cause execution to jump to a target location usually specified by a label (see the ``label``
assembler directive). Conditional branches and the ``it`` and ``ite`` instructions test
the Application Program Status Register (APSR) N (negative), Z (zero), C (carry) and V
(overflow) flags to determine whether the branch should be executed.
Most of the exposed assembler instructions (including move operations) set the flags but
there are explicit comparison instructions to enable values to be tested.
Further detail on the meaning of the condition flags is provided in the section
describing comparison functions.
Document conventions
--------------------
Notation: ``Rm`` denotes ARM registers R0-R15. ``LABEL`` denotes a label defined with the
``label()`` assembler directive. ``<condition>`` indicates one of the following condition
specifiers:
* eq Equal to (result was zero)
* ne Not equal
* cs Carry set
* cc Carry clear
* mi Minus (negaive)
* pl Plus (positive)
* vs Overflow set
* vc Overflow clear
* hi > (unsigned comparison)
* ls <= (unsigned comparison)
* ge >= (signed comparison)
* lt < (signed comparison)
* gt > (signed comparison)
* le <= (signed comparison)
Branch to label
---------------
* b(LABEL) Unconditional branch
* beq(LABEL) branch if equal
* bne(LABEL) branch if not equal
* bge(LABEL) branch if greater than or equal
* bgt(LABEL) branch if greater than
* blt(LABEL) branch if less than (<) (signed)
* ble(LABEL) branch if less than or equal to (<=) (signed)
* bcs(LABEL) branch if carry flag is set
* bcc(LABEL) branch if carry flag is clear
* bmi(LABEL) branch if negative
* bpl(LABEL) branch if positive
* bvs(LABEL) branch if overflow flag set
* bvc(LABEL) branch if overflow flag is clear
* bhi(LABEL) branch if higher (unsigned)
* bls(LABEL) branch if lower or equal (unsigned)
Long branches
-------------
The code produced by the branch instructions listed above uses a fixed bit width to specify the
branch destination, which is PC relative. Consequently in long programs where the
branch instruction is remote from its destination the assembler will produce a "branch not in
range" error. This can be overcome with the "wide" variants such as
* beq\_w(LABEL) long branch if equal
Wide branches use 4 bytes to encode the instruction (compared with 2 bytes for standard branch instructions).
Subroutines (functions)
-----------------------
When entering a subroutine the processor stores the return address in register r14, also
known as the link register (lr). Return to the instruction after the subroutine call is
performed by updating the program counter (r15 or pc) from the link register, This
process is handled by the following instructions.
* bl(LABEL)
Transfer execution to the instruction after ``LABEL`` storing the return address in
the link register (r14).
* bx(Rm) Branch to address specified by Rm.
Typically ``bx(lr)`` is issued to return from a subroutine. For nested subroutines the
link register of outer scopes must be saved (usually on the stack) before performing
inner subroutine calls.

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Load register from memory
=========================
Document conventions
--------------------
Notation: ``Rt, Rn`` denote ARM registers R0-R7 except where stated. ``immN`` represents an immediate
value having a width of N bits hence ``imm5`` is constrained to the range 0-31. ``[Rn + immN]`` is the contents
of the memory address obtained by adding Rn and the offset ``immN``. Offsets are measured in
bytes. These instructions affect the condition flags.
Register Load
-------------
* ldr(Rt, [Rn, imm7]) ``Rt = [Rn + imm7]`` Load a 32 bit word
* ldrb(Rt, [Rn, imm5]) ``Rt = [Rn + imm5]`` Load a byte
* ldrh(Rt, [Rn, imm6]) ``Rt = [Rn + imm6]`` Load a 16 bit half word
Where a byte or half word is loaded, it is zero-extended to 32 bits.
The specified immediate offsets are measured in bytes. Hence in the case of ``ldr`` the 7 bit value
enables 32 bit word aligned values to be accessed with a maximum offset of 31 words. In the case of ``ldrh`` the
6 bit value enables 16 bit half-word aligned values to be accessed with a maximum offset of 31 half-words.

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Logical & Bitwise instructions
==============================
Document conventions
--------------------
Notation: ``Rd, Rn`` denote ARM registers R0-R7 except in the case of the
special instructions where R0-R15 may be used. ``Rn<a-b>`` denotes an ARM register
whose contents must lie in range ``a <= contents <= b``. In the case of instructions
with two register arguments, it is permissible for them to be identical. For example
the following will zero R0 (Python ``R0 ^= R0``) regardless of its initial contents.
* eor(r0, r0)
These instructions affect the condition flags except where stated.
Logical instructions
--------------------
* and\_(Rd, Rn) ``Rd &= Rn``
* orr(Rd, Rn) ``Rd |= Rn``
* eor(Rd, Rn) ``Rd ^= Rn``
* mvn(Rd, Rn) ``Rd = Rn ^ 0xffffffff`` i.e. Rd = 1's complement of Rn
* bic(Rd, Rn) ``Rd &= ~Rn`` bit clear Rd using mask in Rn
Note the use of "and\_" instead of "and", because "and" is a reserved keyword in Python.
Shift and rotation instructions
-------------------------------
* lsl(Rd, Rn<0-31>) ``Rd <<= Rn``
* lsr(Rd, Rn<1-32>) ``Rd = (Rd & 0xffffffff) >> Rn`` Logical shift right
* asr(Rd, Rn<1-32>) ``Rd >>= Rn`` arithmetic shift right
* ror(Rd, Rn<1-31>) ``Rd = rotate_right(Rd, Rn)`` Rd is rotated right Rn bits.
A rotation by (for example) three bits works as follows. If Rd initially
contains bits ``b31 b30..b0`` after rotation it will contain ``b2 b1 b0 b31 b30..b3``
Special instructions
--------------------
Condition codes are unaffected by these instructions.
* clz(Rd, Rn) ``Rd = count_leading_zeros(Rn)``
count_leading_zeros(Rn) returns the number of binary zero bits before the first binary one bit in Rn.
* rbit(Rd, Rn) ``Rd = bit_reverse(Rn)``
bit_reverse(Rn) returns the bit-reversed contents of Rn. If Rn contains bits ``b31 b30..b0`` Rd will be set
to ``b0 b1 b2..b31``
Trailing zeros may be counted by performing a bit reverse prior to executing clz.

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Miscellaneous instructions
==========================
* nop() ``pass`` no operation.
* wfi() Suspend execution in a low power state until an interrupt occurs.
* cpsid(flags) set the Priority Mask Register - disable interrupts.
* cpsie(flags) clear the Priority Mask Register - enable interrupts.
Currently the ``cpsie()`` and ``cpsid()`` functions are partially implemented.
They require but ignore the flags argument and serve as a means of enabling and disabling interrupts.

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Register move instructions
==========================
Document conventions
--------------------
Notation: ``Rd, Rn`` denote ARM registers R0-R15. ``immN`` denotes an immediate
value having a width of N bits. These instructions affect the condition flags.
Register moves
--------------
Where immediate values are used, these are zero-extended to 32 bits. Thus
``mov(R0, 0xff)`` will set R0 to 255.
* mov(Rd, imm8) ``Rd = imm8``
* mov(Rd, Rn) ``Rd = Rn``
* movw(Rd, imm16) ``Rd = imm16``
* movt(Rd, imm16) ``Rd = (Rd & 0xffff) | (imm16 << 16)``
movt writes an immediate value to the top halfword of the destination register.
It does not affect the contents of the bottom halfword.
* movwt(Rd, imm30) ``Rd = imm30``
movwt is a pseudo-instruction: the MicroPython assembler emits a ``movw`` and a ``movt``
to move a zero extended 30 bit value into Rd. Where the full 32 bits are required a
workround is to use the movw and movt operations.

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Stack push and pop
==================
Document conventions
--------------------
The ``push()`` and ``pop()`` instructions accept as their argument a register set containing
a subset, or possibly all, of the general-purpose registers R0-R12 and the link register (lr or R14).
As with any Python set the order in which the registers are specified is immaterial. Thus the
in the following example the pop() instruction would restore R1, R7 and R8 to their contents prior
to the push():
* push({r1, r8, r7}) Save three registers on the stack.
* pop({r7, r1, r8}) Restore them
Stack operations
----------------
* push({regset}) Push a set of registers onto the stack
* pop({regset}) Restore a set of registers from the stack

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Store register to memory
========================
Document conventions
--------------------
Notation: ``Rt, Rn`` denote ARM registers R0-R7 except where stated. ``immN`` represents an immediate
value having a width of N bits hence ``imm5`` is constrained to the range 0-31. ``[Rn + imm5]`` is the
contents of the memory address obtained by adding Rn and the offset ``imm5``. Offsets are measured in
bytes. These instructions do not affect the condition flags.
Register Store
--------------
* str(Rt, [Rn, imm7]) ``[Rn + imm7] = Rt`` Store a 32 bit word
* strb(Rt, [Rn, imm5]) ``[Rn + imm5] = Rt`` Store a byte (b0-b7)
* strh(Rt, [Rn, imm6]) ``[Rn + imm6] = Rt`` Store a 16 bit half word (b0-b15)
The specified immediate offsets are measured in bytes. Hence in the case of ``str`` the 7 bit value
enables 32 bit word aligned values to be accessed with a maximum offset of 31 words. In the case of ``strh`` the
6 bit value enables 16 bit half-word aligned values to be accessed with a maximum offset of 31 half-words.