Last edited 2 months ago

Serial TTY overview

Applicable for STM32MP13x lines, STM32MP15x lines, STM32MP21x lines, STM32MP23x lines, STM32MP25x lines


This article gives information about the Linux® TTY framework. It explains how to activate the UART interface, and how to access it from user and kernel spaces.

1. Framework purpose[edit | edit source]

The TTY subsytem controls the communication between UART devices and the programs using these devices.
The TTY subsystem is responsible for:

  • controlling the physical flow of data on asynchronous lines (including the transmission speed, character size, and line availability).
  • interpreting the data by recognizing special characters and adapting to national languages.
  • controlling jobs and terminal access by using the concept of controlling terminal.


The synchronous mode of the STM32 USART peripheral is not supported by the TTY subsystem.
A controlling terminal manages the input and output operations of a group of processes. The TTY special file (ttyX filesystem entry) supports the controlling terminal interface.
To perform its tasks, the TTY subsystem is composed of modules, also called disciplines. A module is a set of processing rules that govern the interface for communication between the computer and an asynchronous device. Modules can be added and removed dynamically for each TTY.

The TTY subsystem supports three main types of modules:

  • TTY drivers: TTY drivers, or hardware disciplines, directly control the hardware (TTY devices) or pseudo-hardware (PTY devices). They perform the actual input and output to the adapter by providing services to the modules above it. The services are flow control and special semantics when a port is being opened.
  • Line disciplines: the line disciplines provide editing, job control, and special character interpretation. They perform all the transformations that occur on the inbound and outbound data streams. The line disciplines also perform most of the error handling and status monitoring for the TTY drivers.
  • Converter modules: the converter modules, or mapping disciplines, translate, or map, input and output characters.


Since kernel 4.12 version, the serial device bus (also called Serdev) has been introduced in the TTY framework to improve the interface offered to devices attached to a serial port (ex: Bluetooth, NFC, FM Radio and GPS devices), as the line disciplines "drivers" have some known limitations:

  • the devices are encoded in the user space rather than in the firmware (Device Tree of ACPI)
  • "drivers" are not kernel drivers but user space daemons
  • the associated ressources (GPIOs and interrupts, regulators, clocks, audio interface) are not described in the kernel space, which impacts power management
  • "drivers" are registered when a port is opened

The Serdev allows a device to be attached on UART without known the line disciplines limitations:

  • New bus type: serial
  • Serdev controllers
  • Serdev devices (clients or slaves)
  • Serdev TTY-port controller
    • Only in-kernel controller implementation
    • Registered by TTY driver when client is defined
    • clients are described by firmware (Device Tree or ACPI)


The USART low-level driver provided by STMicroelectronics, (drivers/tty/serial/stm32-usart.c) supports RS-232 standard (for serial communication transmission of data), and RS-485 standard (for modbus protocol applications as example).
The Synchronous mode of USART is not supported by Linux® low-level driver .

The TTY framework is used to access the serial device in the following use cases:

  • tty virtual console during Linux boot sequence
  • pts pseudo-terminal to access over a terminal
  • user space application

2. System overview[edit | edit source]

How to use TTY from a user terminalExample: Bluetooth_overviewtermiostty char driverserdev frameworktty frameworkserial_core frameworkstm32-usart driverUSART internal peripheral
Serial TTY architecture overview


Note: during boot, while a serial device is probed, the serial framework instantiates an associated tty terminal as a virtual device. Then the system sees this tty virtual device as a child of the associated serial device.

2.1. Components description[edit | edit source]

From client application to hardware

  • Application: customer application to read/write data from the peripheral connected on the serial port.
  • TTY tools: tools provided by Linux community, such as stty, ldattach, inputattach, tty, ttys, agetty, mingetty, kermit and minicom.
  • Termios: API which offers an interface to develop an application using serial drivers.
  • USART driver: stm32-usart low-level serial driver for all STM32 family devices.
  • STM32 USART: STM32 frontend IP connected to the external devices through a serial port.

2.2. APIs description[edit | edit source]

The TTY provides only character device interface (named /dev/ttyX) to the user space. The main API for user space TTY client applications is provided by the portable POSIX terminal interface termios, which relies on /dev/ttyX interface for TTY link configuration.

The termios API [1] is a user land API, and its functions describe a general terminal interface that is provided to control asynchronous communications ports.

The POSIX termios API abstracts the low-level details of the hardware, and provides a simple, yet complete, programming interface that can be used for advanced projects. It is a wrapper on character device API [2] ioctl operations.

Note: If a serial interface is needed at kernel level (to control an external device through U(S)ART by a kernel driver for example), the customer can use a line discipline or a Serdev client.

  • The line discipline will be responsible for:
    • creating this new kernel API
    • routing data flow between the serial core and the new kernel API
  • The Serdev provides an interface to kernel drivers.
    • This interface resembles line-discipline operations: open and close, terminal settings, write, modem control, read (callback), and write wakeup (callback)

3. Configuration[edit | edit source]

This section describes how to configure a device on a serial port.

3.1. Kernel Configuration[edit | edit source]

The serial driver, serial framework, and TTY framework are activated by default in ST deliveries. Nevertheless, if a specific configuration is needed, this section indicates how IIO can be activated/deactivated in the kernel.

Activate the device TTY in kernel configuration with Linux Menuconfig tool.

For TTY, select:

Device Drivers  --->
   Character devices  --->
     [*]   Enable TTY                           

Allows to remove the TTY support which can save space, and blocks features that require TTY from inclusion in the kernel.
The TTY is required for any text terminals or serial port communication. Most users should leave this enabled.

For the STM32 serial driver, select:

Device Drivers  --->
   Character devices  --->
      Serial drivers  --->
         <*> STMicroelectronics STM32 serial port support
         [*]   Support for console on STM32

This driver is for the on-chip serial controller on STMicroelectronics STM32 MCUs. 
The USART supports Rx and Tx functionality. It supports all industry standard baud rates.

3.2. Device tree configuration[edit | edit source]

The UART configuration thanks to the device tree is described in the dedicated article Serial TTY device tree configuration.

4. How to use TTY[edit | edit source]

This section describes how to use TTY from the user land (from a terminal or an application) and from the kernel space, based on the two following use cases:

  • How to configure the serial port by using the termios structure
  • How to send/receive data

The termios structure allows to configure communication ports with many settings, such as :

  • Baud rate
  • Character size mask
  • Parity bit enabling
  • Parity and framing errors detection settings
  • Start/stop input and output control
  • RTS/CTS (hardware) flow control
  • ...

As the USART internal peripheral supports 7, 8 and 9 word length data, the following termios character size and parity bit configurations are supported:

  • CS6 with parity bit
  • CS7 with or without parity bit
  • CS8 with or without parity bit

Tips to use TTY:


5. How to trace and debug the framework[edit | edit source]

5.1. How to monitor[edit | edit source]

As Debugfs does not propose any information about serial or TTY frameworks, the way to monitor Serial and TTY frameworks is to use the linux kernel log method (based on printk) described in Dmesg_and_Linux_kernel_log article.

5.2. How to trace[edit | edit source]

5.2.1. Kernel boot log[edit | edit source]

The following extract of kernel boot log shows a serial driver properly probed:

[    0.793340] STM32 USART driver initialized
[    0.798779] 4000f000.serial: ttySTM1 at MMIO 0x4000f000 (irq = 25, base_baud = 4000000) is a stm32-usart
[    0.808875] stm32-usart 4000f000.serial: interrupt mode used for rx (no dma)
[    0.816106] stm32-usart 4000f000.serial: interrupt mode used for tx (no dma)
[    0.824253] 40010000.serial: ttySTM0 at MMIO 0x40010000 (irq = 27, base_baud = 4000000) is a stm32-usart
[    0.833796] console [ttySTM0] enabled
[    0.833796] console [ttySTM0] enabled
[    0.840862] bootconsole [earlycon0] disabled
[    0.840862] bootconsole [earlycon0] disabled
[    0.850132] stm32-usart 40010000.serial: interrupt mode used for rx (no dma)
[    0.855755] stm32-usart 40010000.serial: interrupt mode used for tx (no dma)

5.2.2. dmesg output information[edit | edit source]

The system log shows the UART devices and associated TTY terminals registered during the probe.

dmesg | grep ttySTM*
[    0.000000] Kernel command line: root=/dev/mmcblk0p5 rootwait rw earlyprintk console=ttySTM1,115200
# ttySTM1 terminal is associated with usart3 (4000f000.serial) # 
[    0.798779] 4000f000.serial: ttySTM1 at MMIO 0x4000f000 (irq = 25, base_baud = 4000000) is a stm32-usart
# ttySTM0 terminal is associated with uart4 (40010000.serial) for console#
[    0.824253] 40010000.serial: ttySTM0 at MMIO 0x40010000 (irq = 27, base_baud = 4000000) is a stm32-usart      
# ttySTM0 terminal is activated by default for console #
[    0.833796] console [ttySTM0] enabled

5.2.3. Dynamic trace[edit | edit source]

A detailed dynamic trace is available in How to use the kernel dynamic debug

 echo  "file drivers/tty/* +p" > /sys/kernel/debug/dynamic_debug/control

This command enables all the traces related to the TTY core and drivers at runtime.
A finer selection can be made by choosing only the files to trace.

Info white.png Information
Reminder: loglevel needs to be increased to 8 by using either boot arguments or the dmesg -n 8 command through the console

5.3. How to debug[edit | edit source]

While a TTY serial port is instantiated, the TTY core exports different files through devfs, sysfs and procfs.

5.3.1. devfs[edit | edit source]

  • The repository /dev contains all the probed TTY serial devices.
STM32MP $> ls /dev/ttySTM*
/dev/ttySTM1  /dev/ttySTM0  # ttySTM1 and ttySTM0 terminals are probed

5.3.2. sysfs[edit | edit source]

  • /sys/class/tty/ lists all TTY devices which ttySx correspond to serial port devices.
STM32MP $> ls -al /sys/class/tty/*/device/driver
/sys/class/tty/ttySTM1/device/driver -> ../../../../bus/platform/drivers/stm32-usart
/sys/class/tty/ttySTM0/device/driver -> ../../../../bus/platform/drivers/stm32-usart
  • /sys/devices/platform/soc/ lists all the usart devices probed
STM32MP1 $> ls -ad /sys/devices/platform/soc/5c007000.etzpc/*serial
/sys/devices/platform/soc/5c007000.etzpc/4000e000.serial
/sys/devices/platform/soc/5c007000.etzpc/4000f000.serial

STM32MP2 $> ls -ad /sys/devices/platform/soc@0/42080000.rifsc/*.serial
/sys/devices/platform/soc@0/42080000.rifsc/400e0000.serial
/sys/devices/platform/soc@0/42080000.rifsc/40110000.serial
  • /sys/devices/platform/soc/device.serial/tty lists the TTY terminal associated to a serial device
STM32MP $> ls /sys/devices/platform/soc/5c007000.etzpc/4000f000.serial/tty/   
ttySTM1

5.3.3. procfs[edit | edit source]

  • /proc/device-tree lists all the usart devices declared in the device-tree, including the disabled ones.
STM32MP1 $> ls -d /proc/device-tree/soc/etzpc@5c007000/serial@*
/proc/device-tree/soc/etzpc@5c007000/serial@4000e000 
/proc/device-tree/soc/etzpc@5c007000/serial@4000f000
/proc/device-tree/soc/etzpc@5c007000/serial@40010000 
/proc/device-tree/soc/etzpc@5c007000/serial@40011000
/proc/device-tree/soc/etzpc@5c007000/serial@40018000
/proc/device-tree/soc/etzpc@5c007000/serial@40019000
/proc/device-tree/soc/etzpc@5c007000/serial@44003000
/proc/device-tree/soc/etzpc@5c007000/serial@5c000000
STM32MP2 $> ls -d /proc/device-tree/soc@0/rifsc@42080000/serial@*
/proc/device-tree/soc@0/rifsc@42080000/serial@400e0000
/proc/device-tree/soc@0/rifsc@42080000/serial@400f0000
/proc/device-tree/soc@0/rifsc@42080000/serial@40100000
/proc/device-tree/soc@0/rifsc@42080000/serial@40110000
/proc/device-tree/soc@0/rifsc@42080000/serial@40220000
/proc/device-tree/soc@0/rifsc@42080000/serial@402c0000
/proc/device-tree/soc@0/rifsc@42080000/serial@40330000
/proc/device-tree/soc@0/rifsc@42080000/serial@40370000
/proc/device-tree/soc@0/rifsc@42080000/serial@40380000

Then for each device listed, device-tree properties are available.

STM32MP1 $> ls /proc/device-tree/soc/etzpc@5c007000/serial@40010000/
clocks      access-controllers   name     pinctrl-0  pinctrl-2      power-domains  status
compatible  interrupts-extended  phandle  pinctrl-1  pinctrl-names  reg            wakeup-source

As an example, the status entry provides the status of the device in the device tree node.

STM32MP1 $> cat /proc/device-tree/soc/etzpc@5c007000/serial@40010000/status
okay # status of device serial@40010000 (uart4) is set to "okay" in the device tree
  • /proc/interrupts lists the interrupts for active serial ports.
STM32MP1 $> cat /proc/interrupts | grep serial
 51:      16173          0  stm32-exti-h-direct  30 Level     40010000.serial
STM32MP2 $> cat /proc/interrupts | grep serial
 58:      3897           0  GIC-0               147 Level     400e0000.serial

  • /proc/tty/driver/stm32-usart lists serial core counters and modem information for each serial instance.
STM32MP1 $> cat /proc/tty/driver/stm32-usart 
serinfo:1.0 driver revision:
0: uart:stm32-usart mmio:0x40010000 irq:29 tx:22722 rx:2276 RTS|CTS|DTR|DSR|CD
1: uart:stm32-usart mmio:0x4000F000 irq:27 tx:0 rx:1149 fe:121 oe:2 pe:296 brk:3 RTS|CTS|DTR|DSR|CD
3: uart:stm32-usart mmio:0x4000E000 irq:25 tx:0 rx:0 CTS|DSR|CD

Driver information:

  • serial driver name
  • serial device start address
  • irq number

Counters:

  • tx: Number of bytes sent
  • rx: Number of bytes received
  • fe: Number of framing errors received
  • pe: Number of parity errors received
  • brk: Number of break signals received
  • oe: Number of overrun errors received
  • bo: Number of framework buffer overrun errors received

Modem information:

  • RTS: Request To Send
  • CTS: Clear To Send
  • DTR: Data Terminal Ready
  • DSR: Data Set Ready
  • CD: Carrier Detect
  • RI: Ring Indicator

6. How to go further[edit | edit source]

The Linux community provides many detailed documentation about Linux serial/TTY. Please find below a selection of the most relevant ones:

  • Linux Serial-HOWTO [3] describes how to set up serial ports from both hardware and software perspectives.
  • Serial Programming Guide for POSIX Compliant Operating Systems, by Michael Sweet.


More information can be found in the following web articles in order to get a good understanding of the Linux TTY framework:

  • TTY Subsystem [4], by IBM
  • The TTY demystified [5], by Linus Akesson
  • Serial drivers training [6], by Bootlin
  • Linux Serial drivers [7], by Alessandro Rubini
  • Serial Device Bus [8], by Johan Hovold

7. References[edit | edit source]

  1. termios API, Linux Programmer's Manual termios API Documentation (user land API with serial devices)
  2. Character device API overview, Accessing hardware from userspace training, Bootlin documentation
  3. Linux Serial-HOWTO, tdlp.org training document, describes how to set up serial ports from both hardware and software perspectives
  4. TTY Subsystem, by IBM
  5. The TTY demystified TTY subsystem presentation article, by Linus Akesson
  6. Linux serial drivers training Linux Serial Drivers training, by Bootlin
  7. Linux Serial Drivers Serial drivers article describing data flows, by Alessandro Rubini
  8. The Serial Device Bus Serdev framework presentation, by Johan Hovold