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machine — functions related to the hardware

The machine module contains specific functions related to the hardware on a particular board. Most functions in this module allow to achieve direct and unrestricted access to and control of hardware blocks on a system (like CPU, timers, buses, etc.). Used incorrectly, this can lead to malfunction, lockups, crashes of your board, and in extreme cases, hardware damage.

Memory access

The module exposes three objects used for raw memory access.

machine.mem8

Read/write 8 bits of memory.

machine.mem16

Read/write 16 bits of memory.

machine.mem32

Read/write 32 bits of memory.

Use subscript notation [...] to index these objects with the address of interest. Note that the address is the byte address, regardless of the size of memory being accessed.

Example use (registers are specific to an stm32 microcontroller):

import machine
from micropython import const

GPIOA = const(0x48000000)
GPIO_BSRR = const(0x18)
GPIO_IDR = const(0x10)

# set PA2 high
machine.mem32[GPIOA + GPIO_BSRR] = 1 << 2

# read PA3
value = (machine.mem32[GPIOA + GPIO_IDR] >> 3) & 1

Note: the returned values are signed integers. Example: reading the cpuid register on esp8266

value = mem32[0x40001000]

will return a negative value, that could be counter-intuitive.

To always read a positive integer

value = mem32[0x40001000] & 0xffffffff
machine.mem_backup(region=0)

Return a writable memoryview over a persistent hardware memory region that survives at least Soft Reset on all ports; battery-backed ports also survive power-off. Per-port persistence guarantees vary, see the table below.

region selects which backup region to access (default 0, the primary region). Pass -1 to get a tuple of all available regions instead.

The element type depends on the port’s hardware alignment requirements: 'B' (unsigned byte) on ports with byte-addressable backup memory, 'I' (unsigned 32-bit) on ports backed by word-sized registers. Use mem.itemsize to discover the access granularity at runtime.

The total size in bytes is len(mem) * mem.itemsize, where len(mem) is the number of elements and mem.itemsize is the size of each element. For example, on a port with 4 word-sized registers, len(mem) is 4 and mem.itemsize is 4, giving 16 bytes total. On a port with 4096 bytes of byte-addressable backup SRAM, len(mem) is 4096 and mem.itemsize is 1.

Cross-port guarantees for portable code: mem.itemsize is either 1 or 4; valid indices are 0..len(mem)-1; out-of-range access raises IndexError; values are stored in host-native byte order. Region index semantics are not portable, see notes below for stm32 in particular.

Usage:

import machine

mem = machine.mem_backup()
mem[0] = 0x12345678                # write element 0
print(hex(mem[0]))                 # read element 0
print(len(mem))                    # number of elements
print(mem.itemsize)                # bytes per element
print(len(mem) * mem.itemsize)     # total bytes available

# Discover all available regions
for i, r in enumerate(machine.mem_backup(-1)):
    print(i, len(r), r.itemsize)

The total byte size and backing hardware vary by port:

Port

Backing storage

Total bytes

Battery-backed

alif

Backup SRAM

4096

yes

esp32

RTC slow memory

2048

no

mimxrt

SNVS LPGPR registers (4 per chip)

12-16

yes

nrf

POWER GPREGRET registers

1-2

no

rp2

Watchdog scratch registers

28-60

no

samd

Backup RAM (SAMD51 only)

8192

yes

stm32

Backup SRAM + BKP registers (F4/F7/H5/H7/U5/N6)

2048-8192

yes

stm32

RTC BKP registers (other families)

20-128

yes

Note

On esp32 and rp2, data persists across Soft Reset, machine.reset() and machine.deepsleep() wake but is lost on power-off and on poweron-style resets. On esp32 in particular this includes pressing the EN/RESET button on most dev boards, which the chip reports as a power-on reset.

Some ports split backup storage across multiple regions, or exclude registers reserved by the bootloader or system firmware:

Port

Register(s)

Note

mimxrt

LPGPR[3]

Excluded; used by TinyUF2 (when used)

rp2

scratch[4]

Excluded; used by pico-sdk on reset

rp2

powman scratch[0..7]

Region 2 on RP2350 only

stm32

BKP registers

Region 1 on BKPSRAM families (F4/F7/H5/H7/U5/N6)

Use machine.mem_backup(-1) to discover available regions and their sizes.

On stm32 the region index does not have a uniform meaning across boards: region 0 is BKPSRAM (itemsize=1) on BKPSRAM families and BKP registers (itemsize=4) on others. Portable code should branch on mem.itemsize before structuring data.

Some registers within a region are accessible but reserved by convention and should not be overwritten. The BKP register file is region 1 on BKPSRAM families and region 0 on the others:

Port

Register(s)

Used by

stm32

BKP0R

Arduino bootloader (Portenta H7, Giga, Opta, Nicla)

stm32

BKP16R-BKP18R

rfcore_firmware.py on STM32WB

stm32

last BKP reg

clock frequency (MICROPY_HW_CLK_LAST_FREQ)

stm32

BKP31R (N6)

mboot bootloader entry

The buffer allows direct register access and can be combined with uctypes for structured layouts:

import machine, uctypes

mem = machine.mem_backup()

# Structured access via uctypes (check len(mem) for your board)
layout = {
    "flags": (0 * 4, uctypes.UINT32),    # register 0
    "counter": (1 * 4, uctypes.UINT32),  # register 1
}
regs = uctypes.struct(uctypes.addressof(mem), layout)
regs.flags = 0x01
print(regs.counter)

Availability: alif, esp32, mimxrt, nrf, rp2, samd, stm32 ports.

Miscellaneous functions

machine.unique_id()

Returns a byte string with a unique identifier of a board/SoC. It will vary from a board/SoC instance to another, if underlying hardware allows. Length varies by hardware (so use substring of a full value if you expect a short ID). In some MicroPython ports, ID corresponds to the network MAC address.

machine.time_pulse_us(pin, pulse_level, timeout_us=1000000, /)

Time a pulse on the given pin, and return the duration of the pulse in microseconds. The pulse_level argument should be 0 to time a low pulse or 1 to time a high pulse.

If the current input value of the pin is different to pulse_level, the function first (*) waits until the pin input becomes equal to pulse_level, then (**) times the duration that the pin is equal to pulse_level. If the pin is already equal to pulse_level then timing starts straight away.

The function will return -2 if there was timeout waiting for condition marked (*) above, and -1 if there was timeout during the main measurement, marked (**) above. The timeout is the same for both cases and given by timeout_us (which is in microseconds).

machine.bitstream(pin, encoding, timing, data, /)

Transmits data by bit-banging the specified pin. The encoding argument specifies how the bits are encoded, and timing is an encoding-specific timing specification.

The supported encodings are:

  • 0 for “high low” pulse duration modulation. This will transmit 0 and 1 bits as timed pulses, starting with the most significant bit. The timing must be a four-tuple of nanoseconds in the format (high_time_0, low_time_0, high_time_1, low_time_1). For example, (400, 850, 800, 450) is the timing specification for WS2812 RGB LEDs at 800kHz.

The accuracy of the timing varies between ports. On Cortex M0 at 48MHz, it is at best +/- 120ns, however on faster MCUs (ESP8266, ESP32, STM32, Pyboard), it will be closer to +/-30ns.

Note

For controlling WS2812 / NeoPixel strips, see the neopixel module for a higher-level API.

machine.rng()

Return a 24-bit software generated random number.

Availability: WiPy.

Constants

machine.IDLE
machine.SLEEP
machine.DEEPSLEEP

IRQ wake values.

machine.PWRON_RESET
machine.HARD_RESET
machine.WDT_RESET
machine.DEEPSLEEP_RESET
machine.SOFT_RESET

Reset causes.

machine.WLAN_WAKE
machine.PIN_WAKE
machine.RTC_WAKE

Wake-up reasons.

Classes