ARM Cortex-R

Family of microprocessor cores with ARM microarchitecture
ARM Cortex-R
Mediatek MT6280A ARM Cortex-R4
General information
Designed byArm Ltd.
Architecture and classification
Instruction setARMv7-R, ARMv8-R,
ARM (32-bit),
ARM (64-bit),
Thumb (16-bit)

The ARM Cortex-R is a family of 32-bit and 64-bit RISC ARM processor cores licensed by Arm Ltd. The cores are optimized for hard real-time and safety-critical applications. Cores in this family implement the ARM Real-time (R) profile, which is one of three architecture profiles, the other two being the Application (A) profile implemented by the Cortex-A family and the Microcontroller (M) profile implemented by the Cortex-M family. The ARM Cortex-R family of microprocessors currently consists of ARM Cortex-R4(F), ARM Cortex-R5(F), ARM Cortex-R7(F), ARM Cortex-R8(F), ARM Cortex-R52(F), ARM Cortex-R52+(F), and ARM Cortex-R82(F).

Overview

32-bit
Year Core
2011 Cortex-R4(F)
2011 Cortex-R5(F)
2011 Cortex-R7(F)
2016 Cortex-R8(F)
2016 Cortex-R52(F)
2022 Cortex-R52+(F)
64-bit
Year Core
2020 Cortex-R82(F)

The ARM Cortex-R is a family of ARM cores implementing the R profile of the ARM architecture; that profile is designed for high performance hard real-time and safety critical applications. It is similar to the A profile for applications processing but adds features which make it more fault tolerant and suitable for use in hard real-time and safety critical applications.

Real time and safety critical features added include:

  • Tightly coupled memory (uncached memory with guaranteed fast access time)
  • Increased exception handling in hardware
  • Hardware division instructions
  • Memory protection unit (MPU)
  • Deterministic interrupt handling as well as fast non-maskable interrupts
  • ECC on L1 cache and buses
  • Dual-core lockstep for CPU fault tolerance

The Armv8-R architecture includes virtualization features similar to those introduced in the Armv7-A architecture. Two stages of MPU-based translation are provided to enable multiple operating systems to be isolated from one another under the control of a hypervisor.

Prior to the R82, introduced on 4 September 2020,[1] the Cortex-R family did not have a memory management unit (MMU). Models prior to the R82 could not use virtual memory, which made them unsuitable for many applications, such as full-featured Linux.[1] However, many real-time operating systems (RTOS), with an emphasis on total control, have traditionally regarded the lack of an MMU as a feature, not a bug.[1] On the R82, it may be possible to run a traditional RTOS in parallel with a paged OS such as Linux, where Linux takes advantage of the MMU for flexibility, while the RTOS locks the MMU into a direct translation mode on pages assigned to the RTOS so as to retain full predictability for real-time functions.[1]

ARM license

ARM Holdings neither manufactures nor sells CPU devices based on its own designs, but rather licenses the core designs to interested parties. ARM offers a variety of licensing terms, varying in cost and deliverables. To all licensees, ARM provides an integratable hardware description of the ARM core, as well as complete software development toolset and the right to sell manufactured silicon containing the ARM CPU.

Silicon customization

Integrated device manufacturers (IDM) receive the ARM Processor IP as synthesizable RTL (written in Verilog). In this form, they have the ability to perform architectural level optimizations and extensions. This allows the manufacturer to achieve custom design goals, such as higher clock speed, very low power consumption, instruction set extensions, optimizations for size, debug support, etc. To determine which components have been included in a particular ARM CPU chip, consult the manufacturer datasheet and related documentation.

Applications

The Cortex-R is suitable for use in computer-controlled systems where very low latency and/or a high level of safety is required. An example of a hard real-time, safety critical application would be a modern electronic braking system in an automobile. The system not only needs to be fast and responsive to a plethora of sensor data input, but is also responsible for human safety. A failure of such a system could lead to severe injury or loss of life.

Other examples of hard real-time and/or safety critical applications include:

See also

  • iconElectronics portal

References

  1. ^ a b c d Salter, Jim (9 September 2020). "Arm's new Cortex-R82 is its first 64-bit real-time processor". arstechnica.com. Ars Technica. Retrieved 11 September 2020.

External links

ARM Cortex-R official documents
  • ARM Cortex-R official website
ARM
Core		 Bit
Width		 ARM
Website		 ARM Technical
Reference Manual		 ARM Architecture
Reference Manual
Cortex-R4(F) 32 Link Link ARMv7-R
Cortex-R5(F) 32 Link Link ARMv7-R
Cortex-R7(F) 32 Link Link ARMv7-R
Cortex-R8(F) 32 Link Link ARMv7-R
Cortex-R52(F) 32 Link Link ARMv8

ARMv8-R

Cortex-R52+(F) 32 Link Link ARMv8-R
Cortex-R82(F) 64 Link Link ARMv8-R (AArch64)
Migrating
  • Migrating from MIPS to ARM – arm.com
  • Migrating from PPC to ARM – arm.com
  • Migrating from IA-32 (x86-32) to ARM – arm.com
Other
  • CORTEX-R versus CORTEX-M
  • v
  • t
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Embedded ARM-based chips
Embedded
microcontrollers
Cortex-M0
  • Cypress PSoC 4000, 4100, 4100M, 4200, 4200DS, 4200L, 4200M
  • Infineon XMC1000
  • Nordic nRF51
  • NXP LPC1100, LPC1200
  • nuvoTon NuMicro
  • Sonix SN32F700
  • STMicroelectronics STM32 F0
  • Toshiba TX00
  • Vorago VA108x0
Cortex-M0+
  • Cypress PSoC 4000S, 4100S, 4100S+, 4100PS, 4700S, FM0+
  • Holtek HT32F52000
  • Microchip (Atmel) SAM C2, D0, D1, D2, DA, L2, R2, R3
  • NXP LPC800, LPC11E60, LPC11U60
  • NXP (Freescale) Kinetis E, EA, L, M, V1, W0
  • Raspberry Pi RP2040
  • Renesas Synergy S1
  • Silicon Labs (Energy Micro) EFM32 Zero, Happy
  • STMicroelectronics STM32 L0
Cortex-M1
  • Altera FPGAs Cyclone-II, Cyclone-III, Stratix-II, Stratix-III
  • Microsemi (Actel) FPGAs Fusion, IGLOO/e, ProASIC3L, ProASIC3/E
  • Xilinx FPGAs Spartan-3, Virtex-2-3-4
Cortex-M3
Cortex-M4
  • Microchip (Atmel) SAM 4L, 4N, 4S
  • NXP (Freescale) Kinetis K, W2
  • Renesas RA4W1, RA6M1, RA6M2, RA6M3, RA6T1
Cortex-M4F
  • Cypress 6200, FM4
  • Infineon XMC4000
  • Microchip (Atmel) SAM 4C, 4E, D5, E5, G5
  • Microchip CEC1302
  • Nordic nRF52
  • NXP LPC4000, LPC4300
  • NXP (Freescale) Kinetis K, V3, V4
  • Renesas Synergy S3, S5, S7
  • Silicon Labs (Energy Micro) EFM32 Wonder
  • STMicroelectronics STM32 F3, F4, L4, L4+, WB
  • Texas Instruments LM4F/TM4C, MSP432
  • Toshiba TX04
Cortex-M7F
  • Microchip (Atmel) SAM E7, S7, V7
  • NXP (Freescale) Kinetis KV5x, i.MX RT 10xx, i.MX RT 11xx, S32K3xx
  • STMicroelectronics STM32 F7, H7
Cortex-M23
  • GigaDevice CD32E2xx
  • Microchip (Atmel) SAM L10, L11, and PIC 32CM-LE 32CM-LS
  • Nuvoton M23xx family, M2xx family, NUC1262, M2L31
  • Renesas S1JA, RA2A1, RA2L1, RA2E1, RA2E2
Cortex-M33F
  • Analog Devices ADUCM4
  • Dialog DA1469x
  • GigaDevice GD32E5, GD32W5
  • Nordic nRF91, nRF5340, nRF54
  • NXP LPC5500, i.MX RT600
  • ON RSL15
  • Renesas RA4, RA6
  • ST STM32 H5, L5, U5, WBA
  • Silicon Labs Wireless Gecko Series 2
Cortex-M35P
  • STMicroelectronics ST33K
Cortex-M55F
Cortex-M85F
  • Renesas RA8
Real-time
microprocessors
Cortex-R4F
  • Texas Instruments RM4, TMS570
  • Renesas RZ/T1
Cortex-R5F
Cortex-R7F
  • Renesas RZ/G2E, RZ/G2H, RZ/G2M, RZ/G2N
Cortex-R52F
  • NXP S32Z, S32E
  • Renesas RZ/N2L, RZ/T2L, RZ/T2M
Cortex-R52+F
  • STMicroelectronics Stellar G, Stellar P
  • v
  • t
  • e
Main
Architectures
Word length
4-bit
8-bit
16-bit
32-bit
64-bit
Interfaces
Programming
Debugging
Lists
See also