Here is a list of all modules:
[detail level 123456]
 Applications | Contiki provides a set of apps that provide functionalities such as a web server |
  An implementation of IPSO Objects | This application is an implementation of IPSO Objects for OMA Lightweight M2M |
| An implementation of MQTT v3.1 | This application is an engine for MQTT v3.1 |
| An implementation of OMA LWM2M | This application is an implementation of OMA Lightweight M2M |
| A service registration and diseemination hack | This application is a quick'n'dirty hack for registering, disseminating, and looking up services |
 The Contiki shell | The Contiki shell provides both interactive and batch processing for Contiki |
| CTK graphical user interface | The Contiki Toolkit (CTK) provides the graphical user interface for the Contiki system |
| CTK device driver functions | The CTK device driver functions are divided into two modules, the ctk-draw module and the ctk-arch module |
| CTK events | |
| CTK application functions | The CTK functions used by an application program |
| Kl25z | |
| MKL25Z GPIO and Port | Driver for the MKL25Z GPIO controller |
| Contiki platforms | |
| TI cc2538-powered platforms | Documentation for all platforms powered by the TI cc2538 System-on-Chip |
| The TI cc2538 System-on-Chip | CPU-Specific functionality - available to all cc2538-based platforms |
| cc2538 Coffee port module | Module for the cc2538 Coffee port |
| cc2538 Clock | Implementation of the clock module for the cc2538 |
| cc2538 CPU | CPU-specific functions for the cc2538 core |
| cc2538 Character I/O | CPU-specific functions for debugging and SLIP I/O |
| cc2538 IEEE Address Control | Driver for the retrieval of an IEEE address from flash |
| cc2538 Low Power Modes | Driver for the cc2538 power modes |
| cc2538 Register Manipulation | Macros for hardware access, both direct and via the bit-band region |
| cc2538 rtimer | Implementation of the rtimer module for the cc2538 |
| cc2538 SoC | Driver for the cc2538 SoC |
| cc2538 ADC | Driver for the cc2538 ADC controller |
| cc2538 family of devices | Definitions for the cc2538 family of devices |
| cc2538 RF Driver | Driver implementation for the cc2538 RF transceiver |
| CC2538 Built-In Sensors | Module controlling sensors on the CC2538 SoC (Tmp and VDD3) |
| CC2538 on-chip temperature Sensor | Driver for the CC2538 on-chip temperature sensor |
| CC2538 VDD3 Sensor | Driver for the CC2538 VDD3 sensor |
| cc2538 AES/SHA cryptoprocessor | Driver for the cc2538 AES/SHA cryptoprocessor |
| cc2538 AES | Driver for the cc2538 AES modes of the security core |
| cc2538 AES-CBC-MAC | Driver for the cc2538 AES-CBC-MAC mode of the security core |
| cc2538 AES-CBC | Driver for the cc2538 AES-CBC mode of the security core |
| CC2538 AES-128 | AES-128 driver for the CC2538 SoC |
| CC2538 AES-CCM | AES-CCM* driver for the CC2538 SoC |
| cc2538 AES-CCM | Driver for the cc2538 AES-CCM mode of the security core |
| cc2538 AES-CTR | Driver for the cc2538 AES-CTR mode of the security core |
| cc2538 AES-ECB | Driver for the cc2538 AES-ECB mode of the security core |
| cc2538 AES-GCM | Driver for the cc2538 AES-GCM mode of the security core |
| cc2538 SHA-256 | Driver for the cc2538 SHA-256 mode of the security core |
| cc2538 flash memory | Definitions for the cc2538 flash memory |
| cc2538 General-Purpose I/O | Driver for the cc2538 GPIO controller |
| cc2538 General-Purpose Timers | Driver for the cc2538 General Purpose Timers |
| cc2538 I2C Control | Cc2538 I2C Control Module |
| cc2538 I/O Control | Driver for the cc2538 I/O Control Module |
| cc2538 Memory Protection Unit | Driver for the cc2538 Memory Protection Unit |
| cc2538 Nested Vectored Interrupt Controller | Driver for the cc2538 NVIC controller |
| cc2538 PKA engine | Driver for the cc2538 PKA engine |
| cc2538 BigNum math function driver | Driver for the cc2538 BigNum math functions of the PKC engine |
 cc2538 ECC driver | Driver for the cc2538 ECC mode of the PKC engine |
 cc2538 ECC Algorithms | This is a implementation of ECDH, ECDSA sign and ECDSA verify |
| cc2538 NIST curves | NIST curves for various key sizes |
| CC2538 PWM driver | Driver for the CC2538 PWM on GPTIMER |
| cc2538 Random Number Generator | Driver for the cc2538 Hardware Random Number Generator |
| cc2538 RF Core | Declarations of RF Core registers |
| cc2538 ROM utility function library | Driver for the cc2538 ROM utility function library |
| cc2538 System Control Block (SCB) | Offsets and bit definitions for SCB registers |
| cc2538 Sleep Timer and Watchdog | Register declarations for the cc2538 Sleep Timer and Watchdog |
| cc2538 ADC and RNG | Register declarations for the cc2538 ADC and H/W RNG |
| cc2538 Synchronous Serial Interface | Driver for the cc2538 SPI peripheral |
| cc2538 System Control (SysCtrl) | Driver for the cc2538 System Control Module |
| cc2538 UART | Driver for the cc2538 UART controller |
| cc2538 micro-DMA | Driver for the cc2538 uDMA controller |
| cc2538 USB controller | Driver for the cc2538 USB controller |
| cc2538 watchdog timer driver | Driver for the cc2538 Watchdog Timer |
| The cc2538 Development Kit platform | The cc2538DK is a platform by Texas Instruments, based on the cc2538 SoC with an ARM Cortex-M3 core |
| SmartRF06EB Peripherals | Defines related to the SmartRF06EB |
| SmartRF06EB LED driver | LED driver implementation for the TI SmartRF06EB + cc2538EM |
| SmartRF06EB Sensors | Generic module controlling sensors on the SmartRF06EB |
| cc2538dk ALS Driver | Driver for the SmartRF06EB ALS sensor |
| cc2538dk Button Driver | Driver for the SmartRF06EB buttons |
| TI CC26xx-powered Platforms | |
| SmartRF+CC13xx/CC26xx EM, CC2650 SensorTag and LaunchPads | This platform supports a number of different boards: |
| CC13xx/CC26xx peripheral driver pool | Drivers for peripherals present on more than one CC13xx/CC26xx board |
| SensorTag/LaunchPad SPI functions | |
| SensorTag/LaunchPad External Flash | |
| LaunchPad peripherals | Defines related to LaunchPad peripherals |
| LaunchPad Button Driver | One of the buttons can be configured as general purpose or as an on/off key |
| CC1310 LaunchPad Peripherals | Defines related to the CC1310 LaunchPad |
| CC2650 LaunchPad Peripherals | Defines related to the CC2650 LaunchPad |
| Sensortag Peripherals | Defines related to the CC2650 Sensortag |
| SensorTag 2.0 Pressure Sensor | Due to the time required for the sensor to startup, this driver is meant to be used in an asynchronous fashion |
| SensorTag 2.0 I2C functions | |
| SensorTag 2.0 Button Sensor | One of the buttons can be configured as general purpose or as an on/off key |
| SensorTag 2.0 Buzzer | |
| SensorTag 2.0 TI HDC1000 Sensor | Due to the time required for the sensor to startup, this driver is meant to be used in an asynchronous fashion |
| SensorTag 2.0 Motion Processing Unit | Driver for the Invensense MPU9250 Motion Processing Unit |
| SensorTag 2.0 Light Sensor | Due to the time required for the sensor to startup, this driver is meant to be used in an asynchronous fashion |
| SensorTag 2.0 Reed Relay | The reed relay acts like a button without a button |
| SensorTag 2.0 Sensors | |
| SensorTag 2.0 IR thermophile sensor | Due to the time required for the sensor to startup, this driver is meant to be used in an asynchronous fashion |
| SmartRF06EB + CC13xx/CC26xx common | Defines related to the SmartRF06 Evaluation Board irrespective of the EM mounted on it |
| Peripherals for the SmartRF06EB + CC1310EM | Defines related to the SmartRF06 Evaluation Board with a CC1310EM |
| Peripherals for the SmartRF06EB + CC26xxEM | Defines related to the SmartRF06 Evaluation Board with a CC26xxEM |
| The TI CC26xx and CC13xx CPUs | This group documents the TI CC26xx and CC13xx CPUs |
| CC13xx/CC26xx clock and timer subsystem | For the CC13xx/CC26xx cpu we use the AON RTC as the basis for all clocks and timers |
| Software Clock | Implementation of the clock module for the CC26xx and CC13xx |
| CC13xx/CC26xx rtimer | Implementation of the rtimer module for the CC13xx/CC26xx |
| CC13xx/CC26xx watchdog timer driver | Driver for the CC13xx/CC26xx Watchdog Timer |
| CC13xx/CC26xx AON RTC driver | Underpins the platform's software clocks and timers |
| CC13xx/CC26xx Character I/O | CC13xx/CC26xx CPU-specific functions for debugging and SLIP I/O |
| CC13xx/CC26xx IEEE Address Control | Driver for the retrieval of an IEEE address from flash |
| CC13xx/CC26xx Low-Power management | CC13xx/CC26xx low-power operation |
| TI CC26xxware/CC13xxware Glue | Glue file which renames TI CC26xxware functions |
| CC13xx/CC26xx ADC Sensor | |
| CC13xx/CC26xx AUX domain controller | CC13xx/CC26xx AUX domain power management controller |
| CC13xx/CC26xx BatMon sensor driver | Driver for the on-chip battery voltage and chip temperature sensor |
| CC13xx/CC26xx UARTs | Driver for the CC13xx/CC26xx UART controller |
| CC13xx/CC26xx GPIO interrupt handling | The CC13xx/CC26xx GPIO interrupt handler and an API which can be used by other parts of the code when they wish to be notified of a GPIO interrupt |
| CC13xx/CC26xx oscillator control | Wrapper around CC26xxware/CC13xxware OSC functions that we need in Contiki |
| CC13xx/CC26xx RF core | Different flavours of chips of the CC13xx/CC26xx family have different radio capability |
| IEEE 802.15.4g Frequency Bands and Modes | |
| CC13xx/CC26xx IEEE mode driver | |
| CC13xx Prop mode driver | |
| CC13xx/CC26xx BLE driver | |
| RZRAVEN LCD 3290p | |
| LCD Functions and data | |
| The STM32W MBXXX platform | The STM32W MBXXX platform |
| Board | ST board abstraction layer |
| Native platform | Platform running in the host (Windows or Linux) environment |
| Beeper interface | |
| OpenMote-CC2538 platform | The OpenMote-CC2538 is based on the CC2538, the new platform by Texas Instruments based on an ARM Cortex-M3 core and a IEEE 802.15.4 radio |
| OpenMote-CC2538 platform | The OpenMote-CC2538 platform was designed at UC Berkeley in 2013 and is comercialized by OpenMote Technologies since 2014 |
| OpenMote-CC2538 antenna switch | Driver for the OpenMote-CC2538 antenna switch |
| OpenMote-CC2538 user button driver | The user button will generate a sensors_changed event on press as well as on release |
| OpenMote-CC2538 LED driver | |
| OpenMote-CC2538 sensors | Generic module controlling sensors on the OpenMote-CC2538 platform |
| ADXL346 acceleration sensor | |
| MAX4009 light sensor | |
| SHT21 sensor | |
| TPS62730 voltage regulator | Driver for the TPS62730 voltage regulator, to enable power from the battery voltage (bypass, Vout=Vin, Iq < 1uA) or through the buck regulator (on, Vout=2.1V, Iq = 30uA) |
| Contiki SEEDEYE Platform | |
| MRF24J40 Driver | |
| The Tmote Sky Board | The Tmote Sky platform is a wireless sensor board from Moteiv |
| Zolertia Zoul core module | The Zoul comprises the CC2538SF53 and CC1200 in a single module format, which allows a fast reuse of its core components in different formats and form-factors |
| Zolertia platforms based on the Zoul core module | The Zoul allows a fast reuse and easy integration to most applications and products |
| Firefly platform | The Zolertia Firefly is the most down-to-core development platform, exposing the Zoul core functionalities and features, with a slick design to allow a flexible and easier user experience |
| Muntjac platform | The Muntjac is a platform similar to the Zolertia RE-Mote (CC2538 & CC1200/CC1120) that is pin-compatible with the Zolertia Z1 |
| RE-Mote platform | The RE-Mote was designed jointly with universities and industry partners in RERUM European project, to ease the development of private and secure applications for IoT and Smart City applications |
| RE-Mote Antenna switch | Driver for the RE-Mote RF antenna switch, to enable either the internal ceramic antenna or an external one connected to the uFL connector |
| RE-Mote power management driver | The power management module is composed by a nano-watt (gating) timer and an ultra-low power MCU, driving the RE-Mote power supply when connected to an external battery, and allowing an application to enter a so-called "shutdown mode" |
| RE-Mote Real Time Clock Calendar | Driver for the RE-Mote on-board ultra-low power RTCC (Real Time Clock Calendar) |
| Zoul CC1200 arch | CC1200 Zoul arch specifics |
| Zoul LED driver | LED driver implementation for the Zoul-based platforms |
| Zoul Sensors | Generic module controlling sensors on the Zoul platform |
| Zoul adc wrapper to use analogue sensors | The ADC wrapper implement analogue sensors on top of the ADC interface, obscuring the ADC configuration and required calculations to obtain actual sensor values |
| Zoul Generic ADC interface | Driver for the Zoul ADC interface |
| BMP085/BMP180 Sensor | Driver for the BMP085/BMP180 sensor |
| Zoul User Button Driver | Driver for the Zoul user button |
| Grove 3-axis gyroscope based on ITG-3200 | |
| IAQ driver (Indoor Air Quality) Sensor Module | IAQ driver RE-Mote Indoor Air Quality Sensor Module Driver for the RE-Mote Sensor pack: Air Quality Sensor Module (IAQ) |
| LED strip compatible with Zoul-based platforms | Driver to control a bright LED strip powered at 3VDC, drawing power directly from the battery power supply |
| Digital motion sensor | |
| MP3 WTV020SD driver compatible with Zoul-based | Platforms |
| Analog PM10 sensor | |
| Grove LCD with RGB backlight | |
| SHT25 digital temperature sensor | |
| TMP102 Sensor | Driver for the TMP102 sensor |
| TSL2563 Sensor | Driver for the TSL2563 sensor |
| Sparkfun's weather meter | The Sparkfun's weather meter comprises an anemometer, wind vane and rain gauge, see https://www.sparkfun.com/products/8942 |
| Zonik sound sensor | Driver for the RE-Mote Zonik sonometer board |
| RZRAVEN USB Stick (Jackdaw) | |
| USB Configuration | |
| USB operating modes configuration | Defines to enable device or host usb operating modes supported by the application |
| USB regulator configuration | |
| USB device operating mode configuration | |
| USB device custom actions | |
| USB device custom actions | |
| PLL Macros | These functions allow to control the PLL |
| USB Contiki Task | |
| USB Driver | |
| Configuration macros for endpoints | List of the standard macro used to configure pipes and endpoints |
| USB Pads Regulator drivers | Turns ON/OFF USB pads regulator |
| USB common management drivers | These macros manage the USB controller |
| USB device controller drivers | These macros manage the USB Device controller |
| USB endpoint drivers | These macros manage the common features of the endpoints |
| USB host controller drivers | These macros manage the USB Host controller |
| USB pipe drivers | These macros manage the common features of the pipes |
| RNDIS Support | |
| USB Mass Storage Task | |
| CDC Task | |
| 6LowPan Ethernet Interop | |
| nRF52 Development Kit | |
| nRF52 SDK configuration | |
| Contiki configuration | |
| Platform configuration | |
| Debug IO over UART | |
| Device drivers | |
| Buttons driver | |
| LED driver | |
| Sensors | The nRF52 DK exports 4 button sensors and an internal temperature sensor |
| Temperature sensor driver | This is a driver for nRF52832 hardware sensor |
| Enhanced Apple IIe | |
| Atari XL | |
| AVR-ATMEGA128RFA1 platform | |
| Serial interface between Raven processors | This module contains code to interface a Contiki-based project on the AVR Raven platform's ATMega1284P chip to the LCD driver chip (ATMega3290P) on the Raven |
| Atmel AVR Raven | |
| Serial interface between Raven processors | This module contains code to interface a Contiki-based project on the AVR Raven platform's ATMega1284P chip to the LCD driver chip (ATMega3290P) on the Raven |
| Atmel Radio Controller Board (RZ200) | |
| ZigBit | |
| Commodore 128 | |
| Commodore 64 | |
| CC2530 Development Kit | |
| COOJA network simulator node | |
| Redbee Econtag | |
| EV-ADuCRF101MKxZ Board | |
| EVAL-ADF7xxxMB4Z Board | |
| MSP430F5438 Experimenter Board | |
| MICAz | |
| Minimal-net native platform | |
| Generic STM32F103 platform | |
| Win32 | |
| WiSMote | |
| Zolertia Z1 | |
| Zoul-examples | |
| RE-Mote CC1200 nothing | Demonstrates the use of the TI CC1200 RF transceiver on Sub-1GHz |
| FRDM-KL25Z | |
| LED driver | LED driver implementation for the FRDM-KL25Z |
| STM32Cube HAL APIs | Abstraction of STM32Cube HAL APIs as per Contiki coding rules |
| User Button on STM32 Nucleo | Defines some of the platforms capabilities |
| Acceleration Sensor | Maps the acceleration sensor on the STM32 Nucleo Sensor Expansion board |
| Gyroscope Sensor | Maps the gyroscope sensor on the STM32 Sensor Expansion board |
| Humidity Sensor | Maps the humidity sensor on the STM32 Nucleo Sensor Expansion board |
| Magneto Sensor | Maps the magneto sensor on the STM32 Nucleo Sensor Expansion board |
| Pressure Sensor | Maps the pressure sensor on the STM32 Nucleo Sensor Expansion board |
| Temperature Sensor | Maps the temperature sensor on the STM32 Nucleo Sensor Expansion board |
| Mountain Sensing code | |
| Libraries | |
| Cyclic Redundancy Check 16 (CRC16) calculation | The Cyclic Redundancy Check 16 is a hash function that produces a checksum that is used to detect errors in transmissions |
| Linked list library | The linked list library provides a set of functions for manipulating linked lists |
| Table-driven Manchester encoding and decoding | Manchester encoding is a bit encoding scheme which translates each bit into two bits: the original bit and the inverted bit |
| Ring buffer library | The ring buffer library implements ring (circular) buffer where bytes can be read and written independently |
| Settings Manager | The settings manager is an EEPROM-based key-value store |
| Trickle timers | This library implements timers which behave in accordance with RFC 6206 "The Trickle Algorithm" (http://tools.ietf.org/html/rfc6206) |
| Memory functions | |
| Memory block management functions | The memory block allocation routines provide a simple yet powerful set of functions for managing a set of memory blocks of fixed size |
| Managed memory allocator | The managed memory allocator is a fragmentation-free memory manager |
| Device driver APIs | |
| EEPROM API | The EEPROM API defines a common interface for EEPROM access on Contiki platforms |
| LEDs API | The LEDs API defines a set of functions for accessing LEDs for Contiki plaforms with LEDs |
| Radio API | The radio API module defines a set of functions that a radio device driver must implement |
| The Contiki build system | The Contiki build system is designed to make it easy to compile Contiki applications for either to a hardware platform or into a simulation platform by simply supplying different parameters to the make command, without having to edit makefiles or modify the application code |
| Contiki CPUs | |
| PIC32 Contiki Port | |
| AVR | This module contains AVR-specific code to implement the Contiki core clock functions |
| AVR clock implementation | |
| SMSC Registers | |
| XgNicLanc111 | |
| Wireless | This module contains the radio driver code for the Atmel AT86RF230, '231, and '212 chips |
| RF230 MAC | The equivalent IEEE 802.15.4 (2003/2006) header file for the mac primitives |
| SICSLoWMAC Implementation | |
| RF230 Frame handling | |
| RF230 hardware level drivers | HAL function names have the following conventions: |
| RF230 interface | |
| ARM | |
| CMSIS (Cortex Microcontroller Software Interface Standard) | |
| Cortex-M0 | |
| Cortex-M3 | |
| Cortex-M4 | |
| Functions and Instructions Reference | |
| NVIC Functions | Functions that manage interrupts and exceptions via the NVIC |
| SysTick Functions | Functions that configure the System |
| ITM Functions | Functions that access the ITM debug interface |
| CMSIS Core Register Access Functions | |
| Defines and Type Definitions | Type definitions and defines for Cortex-M processor based devices |
| Status and Control Registers | Core Register type definitions |
| Nested Vectored Interrupt Controller (NVIC) | Type definitions for the NVIC Registers |
| System Control Block (SCB) | Type definitions for the System Control Block Registers |
| System Tick Timer (SysTick) | Type definitions for the System Timer Registers |
| Core Debug Registers (CoreDebug) | Cortex-M0 Core Debug Registers (DCB registers, SHCSR, and DFSR) are only accessible over DAP and not via processor |
| Core Definitions | Definitions for base addresses, unions, and structures |
| System Controls not in SCB (SCnSCB) | Type definitions for the System Control and ID Register not in the SCB |
| Instrumentation Trace Macrocell (ITM) | Type definitions for the Instrumentation Trace Macrocell (ITM) |
| Data Watchpoint and Trace (DWT) | Type definitions for the Data Watchpoint and Trace (DWT) |
| Trace Port Interface (TPI) | Type definitions for the Trace Port Interface (TPI) |
| CMSIS Global Defines | IO Type Qualifiers are used |
| CMSIS_MISRA_Exceptions | |
| CMSIS_core_definitions | |
| CMSIS SIMD Intrinsics | Access to dedicated SIMD instructions |
| CMSIS Core Instruction Interface | Access to dedicated instructions |
| ADUCRF101 | |
| AT91SAM7S | |
| STM32F103 | |
| STM32W108 | Compiler and Platform specific definitions and typedefs common to all platforms |
| Status Codes | Many StZNet API functions return an StStatus value to indicate the success or failure of the call |
| Sample A/D converter driver. | See adc.h for source code |
| Sample API funtions for controlling LEDs. | When specifying an LED to use, always use the BOARDLEDx definitions that are defined within the BOARD_HEADER |
| Micro | Many of the supplied example applications use these microcontroller functions |
| System Timer | Functions that provide access to the system clock |
| Definition and description of public flash manipulation routines. | |
| Cortex-M3 Non-Volatile Memory data storage system. | This header defines the API for NVM data storage |
| GNU | Compiler and Platform specific definitions and typedefs for the GNU C ARM compiler |
| IAR | Compiler and Platform specific definitions and typedefs for the IAR ARM C compiler |
| CCxxx | |
| ADUCRF101 | |
| Configuration_of_CMSIS | |
| Device_Peripheral_Registers | |
| Native | |
| x86 | |
| nRF52832 | |
| Bluetooth Low Energy drivers | |
| Device drivers | |
| Clock driver | |
| Low power mode functions | |
| Hardware random number generator | |
| UART driver | |
| Watchdog driver | |
| Contiki system | |
| The Contiki file system interface | The Contiki file system interface (CFS) defines an abstract API for reading directories and for reading and writing files |
| Implicit network time synchronization | This crude and simple network time synchronization module synchronizes clocks of all nodes in a network |
| Argument buffer | The argument buffer can be used when passing an argument from an exiting process to a process that has not been created yet |
| Clock library | The clock library is the interface between Contiki and the platform specific clock functionality |
| Communication power accounting | The compower module accumulates power consumption information and attributes it to communication activities |
| Callback timer | The ctimer module provides a timer mechanism that calls a specified C function when a ctimer expires |
| Event timers | Event timers provides a way to generate timed events |
| The Contiki program loader | The Contiki program loader is an abstract interface for loading and starting programs |
| The Contiki ELF loader | The Contiki ELF loader links, relocates, and loads ELF (Executable Linkable Format) object files into a running Contiki system |
| Architecture specific functionality for the ELF loader. | The architecture specific functionality for the Contiki ELF loader has to be implemented for each processor type Contiki runs on |
| Multi-threading library | The event driven Contiki kernel does not provide multi-threading by itself - instead, preemptive multi-threading is implemented as a library that optionally can be linked with applications |
| Architecture support for multi-threading | The Contiki multi-threading library requires some architecture specific support for setting up and switching stacks |
| Contiki processes | A process in Contiki consists of a single protothread |
| Real-time task scheduling | The real-time module handles the scheduling and execution of real-time tasks (with predictable execution times) |
| Seconds timer library | The stimer library provides functions for setting, resetting and restarting timers, and for checking if a timer has expired |
| Contiki subprocesses | A Contiki subprocess is a "process-in-a-process" |
| Timer library | The Contiki kernel does not provide support for timed events |
| Protothreads | Protothreads are a type of lightweight stackless threads designed for severly memory constrained systems such as deeply embedded systems or sensor network nodes |
| Local continuations | Local continuations form the basis for implementing protothreads |
| Protothread semaphores | This module implements counting semaphores on top of protothreads |
| Communication stacks | |
| Link Layer Security | Layer for implementing link layer security |
| Link Layer Security Common Functionality | Common functionality of 802.15.4-compliant llsec_drivers |
| LLSEC driver with zero security (NULLSEC) | Insecure link layer security driver |
| LLSEC driver using a network-wide key (NONCORESEC) | Noncompromise-resilient 802.15.4 security |
| 802.15.4 frame creation and parsing | |
| The uIP TCP/IP stack | The uIP TCP/IP stack provides Internet communication abilities to Contiki |
| Protosockets library | The protosocket library provides an interface to the uIP stack that is similar to the traditional BSD socket interface |
| uIP hostname resolver functions | The uIP DNS resolver functions are used to lookup a hostname and map it to a numerical IP address |
| A simple UDP API | The default Contiki UDP API is difficult to use |
| Serial Line IP (SLIP) protocol | The SLIP protocol is a very simple way to transmit IP packets over a serial line |
| The Contiki/uIP interface | TCP/IP support in Contiki is implemented using the uIP TCP/IP stack |
| uIP TCP throughput booster hack | The basic uIP TCP implementation only allows each TCP connection to have a single TCP segment in flight at any given time |
| uIP configuration functions | The uIP configuration functions are used for setting run-time parameters in uIP such as IP addresses |
| uIP initialization functions | The uIP initialization functions are used for booting uIP |
| uIP device driver functions | These functions are used by a network device driver for interacting with uIP |
| uIP application functions | Functions used by an application running on top of uIP |
| uIP conversion functions | These functions can be used for converting between different data formats used by uIP |
| Variables used in uIP device drivers | UIP has a few global variables that are used in device drivers for uIP |
| Configuration options for uIP | UIP is configured using the per-project configuration file "uipopt.h" |
| Static configuration options | These configuration options can be used for setting the IP address settings statically, but only if UIP_FIXEDADDR is set to 1 |
| General configuration options | |
| IP configuration options | |
| IPv6 configuration options | |
| UDP configuration options | |
| TCP configuration options | The name of the function that should be called when UDP datagrams arrive |
| ARP configuration options | |
| layer 2 options (for ipv6) | |
| 6lowpan options (for ipv6) | |
| CPU architecture configuration | The CPU architecture configuration is where the endianess of the CPU on which uIP is to be run is specified |
| Application specific configurations | An uIP application is implemented using a single application function that is called by uIP whenever a TCP/IP event occurs |
| uIP packet forwarding | |
| uIP Address Resolution Protocol | The Address Resolution Protocol ARP is used for mapping between IP addresses and link level addresses such as the Ethernet MAC addresses |
| 6LoWPAN implementation | 6lowpan is a Working Group in IETF which defines the use of IPv6 on IEEE 802.15.4 links |
| uIP IPv6 specific features | The uIP IPv6 stack provides new Internet communication abilities to Contiki |
| IPv6 Multicast Forwarding | We currently support 2 engines: |
| ROLL Trickle Multicast | IPv6 multicast according to the algorithm in the "MCAST Forwarding Using Trickle" internet draft |
| 'Stateless Multicast RPL Forwarding' (SMRF) | SMRF will only work in RPL networks in MOP 3 "Storing with Multicast" |
| Architecture specific uIP functions | The functions in the architecture specific module implement the IP check sum and 32-bit additions |
| The Rime communication stack | The Rime communication stack provides a set of lightweight communication primitives ranging from best-effort anonymous local area broadcast to reliable network flooding |
| Rime addresses | The linkaddr module is an abstract representation of addresses in Rime |
| Rime buffer management | The packetbuf module does Rime's buffer management |
| Rime queue buffer management | The queuebuf module handles buffers that are queued |
| Anonymous best-effort local area broadcast | The abc module sends packets to all local area neighbors |
| Announcements | The Announcement primitive does local area announcements |
| Broadcast announcement | The broadcast announcement module implements a periodic explicit announcement |
| Best-effort local area broadcast | The broadcast module sends packets to all local area neighbors with an a header that identifies the sender |
| Link estimate management | The link estimate module is used for computing estimations of link quality |
| Collect neighbor management | The neighbor module manages the neighbor table that is used by the Collect module |
| Tree-based hop-by-hop reliable data collection | The collect module implements a hop-by-hop reliable data collection mechanism |
| Ipolite best effort local broadcast | The ipolite module sends one local area broadcast packet within one time interval |
| Mesh routing | The mesh module sends packets using multi-hop routing to a specified receiver somewhere in the network |
| Best-effort multihop forwarding | The multihop module implements a multihop forwarding mechanism |
| Neighbor discovery | The neighbor-discovery module implements a periodic neighbor discovery mechanism |
| Best-effort network flooding | The netflood module does best-effort flooding |
| Packet queue | The packetqueue module handles a list of queued packets |
| Polite announcement | The polite announcement module implements a periodic explicit announcement |
| Polite anonymous best effort local broadcast | The polite module sends one local area broadcast packet within one time interval |
| Reliable multihop forwarding | The rmh module implements a multihop forwarding mechanism |
| Rime route discovery protocol | The route-discovery module does route discovery for Rime |
| Rime route table | The route module handles the route table in Rime |
| Multi-hop reliable bulk data transfer (rudolph1) | The rudolph1 module implements a multi-hop reliable bulk data transfer mechanism |
| Single-hop reliable bulk data transfer (rudolph2) | The rudolph2 module implements a single-hop reliable bulk data transfer mechanism |
| Single-hop reliable unicast | The reliable single-hop unicast primitive (runicast) reliably sends a packet to a single-hop neighbor |
| Stubborn best-effort local area broadcast | The stbroadcast module provides stubborn anonymous best-effort local area broadcast |
| Stubborn unicast | The stubborn single-hop unicast primitive (stunicast) repeatedly sends a packet to a single-hop neighbor using the unicast primitive |
| Reliable single-source multi-hop flooding | The trickle module sends a single packet to all nodes on the network |
| Single-hop unicast | The unicast module sends a packet to an identified single-hop neighbor |
| Tutorials | This module contains all Contiki related tutorials |
| Running Contiki with uIPv6 and SICSlowpan support on Atmel RAVEN hardware | This tutorial explains how to run Contiki with IPv6 and 6lowpan support on Atmel RAVEN hardware |
| Interrupt vector numbers | |
| Cortex M0 Core Configuration | |
| Device Peripheral Access Layer | |
| ADC Peripheral Access Layer | |
| ADC - Register accessor macros | |
| ADC Register Masks | |
| CMP Peripheral Access Layer | |
| CMP - Register accessor macros | |
| CMP Register Masks | |
| DAC Peripheral Access Layer | |
| DAC - Register accessor macros | |
| DAC Register Masks | |
| DMA Peripheral Access Layer | |
| DMA - Register accessor macros | |
| DMA Register Masks | |
| DMAMUX Peripheral Access Layer | |
| DMAMUX - Register accessor macros | |
| DMAMUX Register Masks | |
| FGPIO Peripheral Access Layer | |
| FGPIO - Register accessor macros | |
| FGPIO Register Masks | |
| FTFA Peripheral Access Layer | |
| FTFA - Register accessor macros | |
| FTFA Register Masks | |
| GPIO Peripheral Access Layer | |
| GPIO - Register accessor macros | |
| GPIO Register Masks | |
| I2C Peripheral Access Layer | |
| I2C - Register accessor macros | |
| I2C Register Masks | |
| LLWU Peripheral Access Layer | |
| LLWU - Register accessor macros | |
| LLWU Register Masks | |
| LPTMR Peripheral Access Layer | |
| LPTMR - Register accessor macros | |
| LPTMR Register Masks | |
| MCG Peripheral Access Layer | |
| MCG - Register accessor macros | |
| MCG Register Masks | |
| MCM Peripheral Access Layer | |
| MCM - Register accessor macros | |
| MCM Register Masks | |
| MTB Peripheral Access Layer | |
| MTB - Register accessor macros | |
| MTB Register Masks | |
| MTBDWT Peripheral Access Layer | |
| MTBDWT - Register accessor macros | |
| MTBDWT Register Masks | |
| NV Peripheral Access Layer | |
| NV - Register accessor macros | |
| NV Register Masks | |
| OSC Peripheral Access Layer | |
| OSC - Register accessor macros | |
| OSC Register Masks | |
| PIT Peripheral Access Layer | |
| PIT - Register accessor macros | |
| PIT Register Masks | |
| PMC Peripheral Access Layer | |
| PMC - Register accessor macros | |
| PMC Register Masks | |
| PORT Peripheral Access Layer | |
| PORT - Register accessor macros | |
| PORT Register Masks | |
| RCM Peripheral Access Layer | |
| RCM - Register accessor macros | |
| RCM Register Masks | |
| ROM Peripheral Access Layer | |
| ROM - Register accessor macros | |
| ROM Register Masks | |
| RTC Peripheral Access Layer | |
| RTC - Register accessor macros | |
| RTC Register Masks | |
| SIM Peripheral Access Layer | |
| SIM - Register accessor macros | |
| SIM Register Masks | |
| SMC Peripheral Access Layer | |
| SMC - Register accessor macros | |
| SMC Register Masks | |
| SPI Peripheral Access Layer | |
| SPI - Register accessor macros | |
| SPI Register Masks | |
| TPM Peripheral Access Layer | |
| TPM - Register accessor macros | |
| TPM Register Masks | |
| TSI Peripheral Access Layer | |
| TSI - Register accessor macros | |
| TSI Register Masks | |
| UART Peripheral Access Layer | |
| UART - Register accessor macros | |
| UART Register Masks | |
| UART0 Peripheral Access Layer | |
| UART0 - Register accessor macros | |
| UART0 Register Masks | |
| USB Peripheral Access Layer | |
| USB - Register accessor macros | |
| USB Register Masks | |
| Backward Compatibility | |
| C2538-ecc-algo | |
| C2538-ecc-curves | |
| Cc2538-sha256 | |
| Sensortag-common-peripherals |
