ARM Cortex-M explained

The ARM Cortex-M is a group of 32-bit RISC ARM processor cores licensed by ARM Limited. These cores are optimized for low-cost and energy-efficient integrated circuits, which have been embedded in tens of billions of consumer devices.[1] Though they are most often the main component of microcontroller chips, sometimes they are embedded inside other types of chips too. The Cortex-M family consists of Cortex-M0, Cortex-M0+, Cortex-M1, Cortex-M3, Cortex-M4, Cortex-M7, Cortex-M23, Cortex-M33, Cortex-M35P, Cortex-M52, Cortex-M55, Cortex-M85. A floating-point unit (FPU) option is available for Cortex-M4 / M7 / M33 / M35P / M52 / M55 / M85 cores, and when included in the silicon these cores are sometimes known as "Cortex-MxF", where 'x' is the core variant.

Overview

32-bit
Year Core
2004 Cortex-M3
2007 Cortex-M1
2009 Cortex-M0
2010 Cortex-M4
2012 Cortex-M0+
2014 Cortex-M7
2016 Cortex-M23
2016 Cortex-M33
2018 Cortex-M35P
2020 Cortex-M55
2022 Cortex-M85
2023 Cortex-M52

See also: ARM architecture and List of ARM cores.

The ARM Cortex-M family are ARM microprocessor cores that are designed for use in microcontrollers, ASICs, ASSPs, FPGAs, and SoCs. Cortex-M cores are commonly used as dedicated microcontroller chips, but also are "hidden" inside of SoC chips as power management controllers, I/O controllers, system controllers, touch screen controllers, smart battery controllers, and sensor controllers.

The main difference from Cortex-A cores is that Cortex-M cores have no memory management unit (MMU) for virtual memory, considered essential for "full-fledged" operating systems. Cortex-M programs instead run bare metal or on one of the many real-time operating systems which support a Cortex-M.

Though 8-bit microcontrollers were very popular in the past, Cortex-M has slowly been chipping away at the 8-bit market as the prices of low-end Cortex-M chips have moved downward. Cortex-M have become a popular replacements for 8-bit chips in applications that benefit from 32-bit math operations, and replacing older legacy ARM cores such as ARM7 and ARM9.

License

ARM Limited neither manufactures nor sells CPU devices based on its own designs, but rather licenses the processor architecture 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 (including floating point), 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.

Some of the silicon options for the Cortex-M cores are:

ARM Cortex-M optional components
ARM Core Cortex
M0
Cortex
M0+
Cortex
M1
Cortex
M3
Cortex
M4
Cortex
M7
Cortex
M23
Cortex
M33
Cortex
M35P
Cortex
M52
Cortex
M55
Cortex
M85
Optional
(0,1)
Optional
(0, 1)
Optional
(0,1)
Optional
(0, 1, 2)
Single-cycle I/O port Optional Optional
Bit-Band memory Optional Optional Optional
Memory Protection
Unit (MPU)
Optional
(0, 8)
Optional
(0,8)
Optional
(0, 8)
Optional
(0, 8, 16)
Optional
(0, 4, 8, 12, 16)
Optional
(0, 4, 8, 12, 16)
Optional
(up to 16)*
Optional
(0, 4, 8, 12, 16)
Optional
(0, 4, 8, 12, 16)
Optional
(0, 4, 8, 12, 16)
Optional
(0, 4, 8)
Optional
(0, 4, 8)
Optional
(up to 8)*
Optional
(0, 4, 8)
Optional
(0, 4, 8)
Optional
(0, 4, 8)
[2] Optional
(up to 64 KB)
Optional
(up to 16 KB)
Optional
(up to 64 KB)
Optional
(up to 64 KB)
Optional
(up to 64 KB)
Optional
(up to 64 KB)
Optional
(up to 64 KB)
Optional
(up to 64 KB)
Optional
(up to 64 KB)
Instruction TCM
(ITCM) Memory
Optional
(up to 1 MB)
Optional
(up to 16 MB)
Optional
(up to 16 MB)
Optional
(up to 16 MB)
Optional
(up to 16 MB)
Data TCM
(DTCM) Memory
Optional
(up to 1 MB)
Optional
(up to 16 MB)
Optional
(up to 16 MB)
Optional
(up to 16 MB)
Optional
(up to 16 MB)
ECC for TCM
and Cache
Optional Optional Optional Optional
Vector Table Offset
Register (VTOR)
Optional
(0,1)
Optional
(0,1)
Optional
(0,1)
Optional
(0,1)
Optional
(0,1)
Optional
(0,1,2)

Additional silicon options:

Instruction sets

The Cortex-M0 / M0+ / M1 implement the ARMv6-M architecture, the Cortex-M3 implements the ARMv7-M architecture, the Cortex-M4 / Cortex-M7 implements the ARMv7E-M architecture, the Cortex-M23 / M33 / M35P implement the ARMv8-M architecture, and the Cortex-M52 / M55 / M85 implements the ARMv8.1-M architecture. The architectures are binary instruction upward compatible from ARMv6-M to ARMv7-M to ARMv7E-M. Binary instructions available for the Cortex-M0 / Cortex-M0+ / Cortex-M1 can execute without modification on the Cortex-M3 / Cortex-M4 / Cortex-M7. Binary instructions available for the Cortex-M3 can execute without modification on the Cortex-M4 / Cortex-M7 / Cortex-M33 / Cortex-M35P. Only Thumb-1 and Thumb-2 instruction sets are supported in Cortex-M architectures; the legacy 32-bit ARM instruction set isn't supported.

All Cortex-M cores implement a common subset of instructions that consists of most Thumb-1, some Thumb-2, including a 32-bit result multiply. The Cortex-M0 / Cortex-M0+ / Cortex-M1 / Cortex-M23 were designed to create the smallest silicon die, thus having the fewest instructions of the Cortex-M family.

The Cortex-M0 / M0+ / M1 include Thumb-1 instructions, except new instructions (CBZ, CBNZ, IT) which were added in ARMv7-M architecture. The Cortex-M0 / M0+ / M1 include a minor subset of Thumb-2 instructions (BL, DMB, DSB, ISB, MRS, MSR). The Cortex-M3 / M4 / M7 / M33 / M35P have all base Thumb-1 and Thumb-2 instructions. The Cortex-M3 adds three Thumb-1 instructions, all Thumb-2 instructions, hardware integer divide, and saturation arithmetic instructions. The Cortex-M4 adds DSP instructions and an optional single-precision floating-point unit (VFPv4-SP). The Cortex-M7 adds an optional double-precision FPU (VFPv5). The Cortex-M23 / M33 / M35P / M52 / M55 / M85 add TrustZone instructions.

ARM Cortex-M instruction variations
Arm Core Cortex
M0
Cortex
M0+
Cortex
M1
Cortex
M3
Cortex
M4
Cortex
M7
Cortex
M23
Cortex
M33
Cortex
M35P
Cortex
M52
Cortex
M55
Cortex
M85
ARMv6-M
ARMv6-M
ARMv6-M
ARMv7-M
ARMv7E-M
ARMv7E-M
ARMv8-M
Baseline
ARMv8-M
Mainline
ARMv8-M
Mainline
Armv8.1-M
Mainline
Armv8.1-M
Mainline
Armv8.1-M
Mainline
Von
Neumann
Von
Neumann
Harvard Harvard Von
Neumann
Harvard Harvard Harvard Harvard Harvard
3 stages 2 stages 3 stages 3 stages 3 stages 6 stages 2 stages 3 stages 3 stages 4 stages 4-5 stages 7 stages
Interrupt latency
(zero wait state memory)
16 cycles 15 cycles 23 for NMI,
26 for IRQ
12 cycles 12 cycles 12 cycles,
14 worst
case
15 cycles,
24 secure
to NS IRQ
12 cycles,
21 secure
to NS IRQ
TBD TBD TBD TBD
Thumb-1 instructions Most Most Most Most
Thumb-2 instructions Some Some Some Some
Multiply instructions
32×32 = 32-bit result
Multiply instructions
32×32 = 64-bit result
Divide instructions
32/32 = 32-bit quotient
Saturated math instructions Some
DSP instructions Optional Optional
Half-Precision (HP)
floating-point instructions
Optional Optional Optional
Single-Precision (SP)
floating-point instructions
Optional Optional Optional Optional Optional Optional Optional
Double-Precision (DP)
floating-point instructions
Optional Optional Optional Optional
Helium vector instructionsOptional Optional Optional
TrustZone security instructions Optional Optional Optional Optional Optional
Co-processor instructions Optional Optional Optional Optional Optional
ARM Custom Instructions (ACI) Optional Optional Optional Optional
Pointer Authentication and Branch Target
Identification (PACBTI) instructions
Optional Optional
ARM Cortex-M instruction groups
Group Instr
bits
Instructions Cortex
M0, M0+, M1
Cortex
M3
Cortex
M4
Cortex
M7
Cortex
M23
Cortex
M33
Cortex
M35P
Cortex
M52
Cortex
M55
Cortex
M85
16 ADC, ADD, ADR, AND, ASR, B, BIC, BKPT, BLX, BX, CMN, CMP, CPS, EOR, LDM, LDR, LDRB, LDRH, LDRSB, LDRSH, LSL, LSR, MOV, MUL, MVN, NOP, ORR, POP, PUSH, REV, REV16, REVSH, ROR, RSB, SBC, SEV, STM, STR, STRB, STRH, SUB, SVC, SXTB, SXTH, TST, UXTB, UXTH, WFE, WFI, YIELD
16 CBNZ, CBZ
16 IT
32 BL, DMB, DSB, ISB, MRS, MSR
32 SDIV, UDIV, MOVT, MOVW, B.W, LDREX, LDREXB, LDREXH, STREX, STREXB, STREXH
32 ADC, ADD, ADR, AND, ASR, B, BFC, BFI, BIC, CDP, CLREX, CLZ, CMN, CMP, DBG, EOR, LDC, LDM, LDR, LDRB, LDRBT, LDRD, LDRH, LDRHT, LDRSB, LDRSBT, LDRSH, LDRSHT, LDRT, LSL, LSR, MCR, MCRR, MLA, MLS, MRC, MRRC, MUL, MVN, NOP, ORN, ORR, PLD, PLDW, PLI, POP, PUSH, RBIT, REV, REV16, REVSH, ROR, RRX, RSB, SBC, SBFX, SEV, SMLAL, SMULL, SSAT, STC, STM, STR, STRB, STRBT, STRD, STRH, STRHT, STRT, SUB, SXTB, SXTH, TBB, TBH, TEQ, TST, UBFX, UMLAL, UMULL, USAT, UXTB, UXTH, WFE, WFI, YIELD
32 PKH, QADD, QADD16, QADD8, QASX, QDADD, QDSUB, QSAX, QSUB, QSUB16, QSUB8, SADD16, SADD8, SASX, SEL, SHADD16, SHADD8, SHASX, SHSAX, SHSUB16, SHSUB8, SMLABB, SMLABT, SMLATB, SMLATT, SMLAD, SMLALBB, SMLALBT, SMLALTB, SMLALTT, SMLALD, SMLAWB, SMLAWT, SMLSD, SMLSLD, SMMLA, SMMLS, SMMUL, SMUAD, SMULBB, SMULBT, SMULTT, SMULTB, SMULWT, SMULWB, SMUSD, SSAT16, SSAX, SSUB16, SSUB8, SXTAB, SXTAB16, SXTAH, SXTB16, UADD16, UADD8, UASX, UHADD16, UHADD8, UHASX, UHSAX, UHSUB16, UHSUB8, UMAAL, UQADD16, UQADD8, UQASX, UQSAX, UQSUB16, UQSUB8, USAD8, USADA8, USAT16, USAX, USUB16, USUB8, UXTAB, UXTAB16, UXTAH, UXTB16 Optional Optional
32 VABS, VADD, VCMP, VCMPE, VCVT, VCVTR, VDIV, VLDM, VLDR, VMLA, VMLS, VMOV, VMRS, VMSR, VMUL, VNEG, VNMLA, VNMLS, VNMUL, VPOP, VPUSH, VSQRT, VSTM, VSTR, VSUB Optional Optional Optional Optional Optional Optional Optional
32 VCVTA, VCVTM, VCVTN, VCVTP, VMAXNM, VMINNM, VRINTA, VRINTM, VRINTN, VRINTP, VRINTR, VRINTX, VRINTZ, VSEL Optional Optional Optional Optional
Acquire/Release 32 LDA, LDAB, LDAH, LDAEX, LDAEXB, LDAEXH, STL, STLB, STLH, STLEX, STLEXB, STLEXH
16 BLXNS, BXNS rowspan="2" rowspan="2" rowspan="2" rowspan="2" Optional Optional Optional Optional Optional rowspan="2"
32 SG, TT, TTT, TTA, TTAT
16 CDP, CDP2, MCR, MCR2, MCRR, MCRR2, MRC, MRC2, MRRC, MRRC2 Optional Optional Optional Optional Optional
ACI 32 CX1, CX1A, CX2, CX2A, CX3, CX3A, CX1D, CX1DA, CX2D, CX2DA, CX3D, CX3DA, VCX1, VCX1A, VCX2, VCX2A, VCX3, VCX3A Optional Optional Optional Optional
PACBTI 32 AUT, AUTG, BTI, BXAUT, PAC, PACBTI, PACG Optional Optional

Deprecations

The ARM architecture for ARM Cortex-M series removed some features from older legacy cores:

The capabilities of the 32-bit ARM instruction set is duplicated in many ways by the Thumb-1 and Thumb-2 instruction sets, but some ARM features don't have a similar feature:

The 16-bit Thumb-1 instruction set has evolved over time since it was first released in the legacy ARM7T cores with the ARMv4T architecture. New Thumb-1 instructions were added as each legacy ARMv5 / ARMv6 / ARMv6T2 architectures were released. Some 16-bit Thumb-1 instructions were removed from the Cortex-M cores:

Cortex-M0

Cortex-M0
Arch:ARMv6-M (Thumb-1 (most),
Thumb-2 (some))

The Cortex-M0 core is optimized for small silicon die size and use in the lowest price chips.

Key features of the Cortex-M0 core are:

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M0 core:

The following chips have a Cortex-M0 as a secondary core:

Cortex-M0+

Cortex-M0+
Arch:Thumb-1 (most),
Thumb-2 (some)
Microarch:ARMv6-M

The Cortex-M0+ is an optimized superset of the Cortex-M0. The Cortex-M0+ has complete instruction set compatibility with the Cortex-M0 thus allowing the use of the same compiler and debug tools. The Cortex-M0+ pipeline was reduced from 3 to 2 stages, which lowers the power usage and increases performance (higher average IPC due to branches taking one fewer cycle). In addition to debug features in the existing Cortex-M0, a silicon option can be added to the Cortex-M0+ called the Micro Trace Buffer (MTB) which provides a simple instruction trace buffer. The Cortex-M0+ also received Cortex-M3 and Cortex-M4 features, which can be added as silicon options, such as the memory protection unit (MPU) and the vector table relocation.

Key features of the Cortex-M0+ core are:

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M0+ core:

The following chips have a Cortex-M0+ as a secondary core:

The smallest ARM microcontrollers are of the Cortex-M0+ type (as of 2014, smallest at 1.6 mm by 2 mm in a chip-scale package is Kinetis KL03).[6]

On 21 June 2018, the "world's smallest computer'", or computer device was announced based on the ARM Cortex-M0+ (and including RAM and wireless transmitters and receivers based on photovoltaics) by University of Michigan researchers at the 2018 Symposia on VLSI Technology and Circuits with the paper "A 0.04mm3 16nW Wireless and Batteryless Sensor System with Integrated Cortex-M0+ Processor and Optical Communication for Cellular Temperature Measurement." The device is one-tenth the size of IBM's previously claimed world-record-sized computer from months back in March 2018, which is smaller than a grain of salt.

Cortex-M1

Cortex-M1
Arch:Thumb-1 (most),
Thumb-2 (some)
Microarch:ARMv6-M

The Cortex-M1 is an optimized core especially designed to be loaded into FPGA chips.

Key features of the Cortex-M1 core are:

Silicon options:

Chips

The following vendors support the Cortex-M1 as soft-cores on their FPGA chips:

Cortex-M3

Cortex-M3
Arch:Thumb-1, Thumb-2,
Saturated (some), Divide
Microarch:ARMv7-M

Key features of the Cortex-M3 core are:[9]

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M3 core:

The following chips have a Cortex-M3 as a secondary core:

The following FPGAs include a Cortex-M3 core:

The following vendors support the Cortex-M3 as soft-cores on their FPGA chips:

Cortex-M4

Cortex-M4
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (SP)
Microarch:ARMv7E-M

Conceptually the Cortex-M4 is a Cortex-M3 plus DSP instructions, and optional floating-point unit (FPU). A core with an FPU is known as Cortex-M4F.

Key features of the Cortex-M4 core are:

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M4 core:

The following microcontrollers are based on the Cortex-M4F (M4 + FPU) core:

The following chips have either a Cortex-M4 or M4F as a secondary core:

Cortex-M7

Cortex-M7
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (SP & DP)
Microarch:ARMv7E-M

The Cortex-M7 is a high-performance core with almost double the power efficiency of the older Cortex-M4. It features a 6-stage superscalar pipeline with branch prediction and an optional floating-point unit capable of single-precision and optionally double-precision operations.[12] The instruction and data buses have been enlarged to 64-bit wide over the previous 32-bit buses. If a core contains an FPU, it is known as a Cortex-M7F, otherwise it is a Cortex-M7.

Key features of the Cortex-M7 core are:

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M7 core:

Cortex-M23

Cortex-M23
Arch:Thumb-1 (most),
Thumb-2 (some),
Divide, TrustZone
Microarch:ARMv8-M Baseline

The Cortex-M23 core was announced in October 2016[13] and based on the ARMv8-M architecture that was previously announced in November 2015.[14] Conceptually the Cortex-M23 is similar to a Cortex-M0+ plus integer divide instructions and TrustZone security features, and also has a 2-stage instruction pipeline.

Key features of the Cortex-M23 core are:[13]

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M23 core:

Cortex-M33

Cortex-M33
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (SP),
TrustZone, Co-processor
Microarch:ARMv8-M Mainline

The Cortex-M33 core was announced in October 2016[13] and based on the ARMv8-M architecture that was previously announced in November 2015.[14] Conceptually the Cortex-M33 is similar to a cross of Cortex-M4 and Cortex-M23, and also has a 3-stage instruction pipeline.

Key features of the Cortex-M33 core are:[13]

Silicon options:

Chips

The following microcontrollers are based on the Cortex-M33 core:

The following chips have a Cortex-M33 or M33F as a secondary core:

Cortex-M35P

Cortex-M35P
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (SP),
TrustZone, Co-processor
Microarch:ARMv8-M Mainline

The Cortex-M35P core was announced in May 2018 and based on the Armv8-M architecture. It is conceptually a Cortex-M33 core with a new instruction cache, plus new tamper-resistant hardware concepts borrowed from the ARM SecurCore family, and configurable parity and ECC features.

Currently, information about the Cortex-M35P is limited, because its Technical Reference Manual and Generic User Guide haven't been released yet.

Chips

The following microcontrollers are based on the Cortex-M35P core:

Cortex-M52

Cortex-M52
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (VFPv5),
TrustZone, Coprocessor, MVE
Microarch:ARMv8.1-M Mainline Helium

The Cortex-M52 core was announced in November 2023 and based on the Armv8.1-M architecture. It has a 4 stage instruction pipeline.

Key features of the Cortex-M52 core include:

Silicon options:

Chips

Cortex-M55

Cortex-M55
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (VFPv5),
TrustZone, Coprocessor, MVE
Microarch:ARMv8.1-M Mainline Helium

The Cortex-M55 core was announced in February 2020 and based on the Armv8.1-M architecture. It has a 4 or 5 stage instruction pipeline.

Key features of the Cortex-M55 core include:

Silicon options:

Chips

Cortex-M85

Cortex-M85
Arch:Thumb-1, Thumb-2,
Saturated, DSP,
Divide, FPU (VFPv5),
TrustZone, Coprocessor, MVE
Microarch:ARMv8.1-M Mainline Helium

The Cortex-M85 core was announced in April 2022 and based on the Armv8.1-M architecture. It has a 7-stage instruction pipeline.

Silicon options:

Chips

Development tools

See main article: article and List of ARM Cortex-M development tools.

Documentation

The documentation for ARM chips is extensive. In the past, 8-bit microcontroller documentation would typically fit in a single document, but as microcontrollers have evolved, so has everything required to support them. A documentation package for ARM chips typically consists of a collection of documents from the IC manufacturer as well as the CPU core vendor (ARM Limited).

A typical top-down documentation tree is:

Documentation tree (top to bottom)
  1. IC manufacturer website.
  2. IC manufacturer marketing slides.
  3. IC manufacturer datasheet for the exact physical chip.
  4. IC manufacturer reference manual that describes common peripherals and aspects of a physical chip family.
  5. ARM core website.
  6. ARM core generic user guide.
  7. ARM core technical reference manual.
  8. ARM architecture reference manual.

IC manufacturers have additional documents, such as: evaluation board user manuals, application notes, getting started guides, software library documents, errata, and more. See External links section for links to official Arm documents.

See also

Further reading

External links

ARM Cortex-M official documents
ARM
core
Bit
width
ARM
website
ARM generic
user guide
ARM technical
reference manual
ARM architecture
reference manual
32 Link Link Link ARMv6-M
32 Link Link Link ARMv6-M
32 Link Link Link ARMv6-M
32 Link Link Link ARMv7-M
32 Link Link Link ARMv7E-M
32 Link Link Link ARMv7E-M
32 Link Link Link ARMv8-M
32 Link Link Link ARMv8-M
32 Link ARMv8-M
32 Link Link ARMv8.1-M
32 Link Link Link ARMv8.1-M
32 Link Link Link ARMv8.1-M
Quick reference cards
Migrating
Other

Notes and References

  1. http://www.arm.com/products/processors/cortex-m ARM Cortex-M website; ARM Limited.
  2. http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dai0321a/BIHEADII.html ARM Cortex-M Programming Guide to Memory Barrier Instructions; Section 3.6 System implementation requirements; AppNote 321; ARM Limited.
  3. Web site: Cortex-M System Design Kit (CMSDK) . . https://web.archive.org/web/20160304000010/http://www.arm.com/products/processors/cortex-m/cortex-m-system-design-kit.php . March 4, 2016 . dead.
  4. http://infocenter.arm.com/help/topic/com.arm.doc.dai0179b/AppsNote179.pdf Cortex-M3 Embedded Software Development; App Note 179; ARM Limited.
  5. https://www.microchip.com/en-us/products/microcontrollers-and-microprocessors/32-bit-mcus 32-bit PIC and SAM Microcontrollers; Microchip.
  6. News: Freescale makes the world's smallest ARM controller chip even tinier . Jon . Fingas . 25 February 2014 . 2 October 2014.
  7. https://www.gowinsemi.com/en/about/detail/latest_news/37/ GOWIN Semiconductor joins ARM DesignStart offering free ARM Cortex-M1 Processors for its FPGA product families
  8. https://silver.arm.com/browse/AT472 Cortex-M1 DesignStart FPGA XilinxEdition; ARM Limited.
  9. Web site: Sadasivan . Shyam . An Introduction to the ARM Cortex-M3 Processor . ARM Limited . dead . https://web.archive.org/web/20140726212528/http://www.arm.com/files/pdf/IntroToCortex-M3.pdf . July 26, 2014 .
  10. Web site: Samsung Exynos 7420 Deep Dive - Inside a Modern 14nm SoC . AnandTech . 2015-06-15.
  11. https://silver.arm.com/browse/AT426 Cortex-M3 DesignStart FPGA XilinxEdition
  12. ARM Supercharges MCU Market with High Performance Cortex-M7 Processor . ARM Limited . September 24, 2014.
  13. https://www.arm.com/files/pdf/cortex_m23_and_cortex_m33.pdf New ARM Cortex-M processors offer the next industry standard for secure IoT; ARM Limited; October 25, 2016.
  14. https://www.arm.com/about/newsroom/armv8-m-architecture-simplifies-security-for-smart-embedded-devices.php ARMv8-M Architecture Simplifies Security for Smart Embedded Devices; ARM Limited; November 10, 2015.