ARM Cortex-M

ARM Cortex-M0 and Cortex-M3 ICs from NXP and Energy Micro

Die of a STM32F100C4T6B ARM Cortex-M3 microcontroller with 16 KB flash memory, 24 MHz CPU, motor control, and CEC functions. Manufactured by STMicroelectronics.

The ARM Cortex-M is a group of 32-bit RISC ARM processor cores licensed by ARM Holdings. The cores are intended for microcontroller use, and consist of the Cortex-M0, M0+, M1, M3, M4, M7, M23, M33.^[1]^[2]^[3]^[4]^[5]

Overview

Announced
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

Main articles: ARM architecture and List of ARM cores

ARM license

ARM Holdings 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, 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 most important options for the Cortex-M cores are:

SysTick timer: A 24-bit system timer that extends the functionality of both the processor and the Nested Vectored Interrupt Controller (NVIC). When present, it also provides an additional configurable priority SysTick interrupt.^[6]^[7]^[8] Though the SysTick timer is optional, it's rare to see a Cortex-M microcontroller without it.
Bit-banding: Maps a complete word of memory onto a single bit in the bit-band region. For example, writing to an alias word will set or clear the corresponding bit in the bitband region. This allows every individual bit in the bit-banding region to be directly accessible from a word-aligned address, and individual bits to be toggled from C/C++ without performing a read-modify-write sequence of instructions.^[6]^[7]^[8]
Memory Protection Unit (MPU): Provides support for protecting regions of memory through enforcing privilege and access rules. It supports up to eight different regions, each of which can be split into a further eight equal-size sub-regions.^[6]^[7]^[8]

ARM Cortex-M optional components^[6]^[7]
ARM Cortex-M	SysTick Timer	Bit- banding	Memory Protection Unit (MPU)	Tightly-Coupled Memory (TCM)	CPU cache	Memory architecture	ARM architecture
Cortex-M0^[1]	Optional*	Optional^[9]	No	No	No^[10]	Von Neumann	ARMv6-M
Cortex-M0+^[2]	Optional*	Optional^[9]	Optional (8)	No	No	Von Neumann	ARMv6-M
Cortex-M1^[3]	Optional	Optional	No	Optional	No	Von Neumann	ARMv6-M
Cortex-M3^[4]	Yes	Optional*	Optional (8)	No	No	Harvard	ARMv7-M
Cortex-M4^[5]	Yes	Optional*	Optional (8)	No	Possible^[11]	Harvard	ARMv7E-M
Cortex-M7	Yes	No	Optional (8 or 16)	Optional	Optional	Harvard	ARMv7E-M

Note: Most Cortex-M3 and M4 chips have bit-banding and MPU. The bit-banding option can be added to the Cortex-M0 / M0+ using the Cortex-M System Design Kit.^[9]
Note: Software should validate the existence of a feature before attempting to use it.^[8]

Additional silicon options:^[6]^[7]

Data endianness: Little-endian or big-endian. Unlike legacy ARM cores, the Cortex-M is permanently fixed in silicon as one of these choices.
Interrupts: 1 to 32 (Cortex-M0/M0+/M1), 1 to 240 (Cortex-M3/M4/M7).
Wake-up interrupt controller: Optional.
Vector Table Offset Register: Optional.
Instruction fetch width: 16-bit only, or mostly 32-bit.
User/privilege support: Optional.
Reset all registers: Optional.
Single-cycle I/O port: Optional.
Debug Access Port (DAP): Optional.
Halting debug support: Optional.
Number of watchpoint comparators: 0 to 2 (Cortex M0/M0+/M1), 0 to 4 (Cortex-M3/M4/M7).
Number of breakpoint comparators: 0 to 4 (Cortex M0/M0+/M1), 0 to 8 (Cortex-M3/M4/M7).

Instruction sets

The Cortex-M0 / M0+ / M1 implement the ARMv6-M architecture,^[6] the Cortex-M3 implements the ARMv7-M architecture,^[7] and the Cortex-M4 / M7 implements the ARMv7E-M architecture.^[7] The architectures are binary instruction upward compatible from ARMv6-M to ARMv7-M to ARMv7E-M. Binary instructions available for the Cortex-M0 / M0+ / M1 can execute without modification on the Cortex-M3 / M4 / M7. Binary instructions available for the Cortex-M3 can execute without modification on the Cortex-M4 / M7.^[6]^[7] Only Thumb and Thumb-2 instruction sets are supported in Cortex-M architectures, but the legacy 32-bit ARM instruction set isn't supported.

All six Cortex-M cores implement a common subset of instructions that consists of most Thumb, some Thumb-2, including a 32-bit result multiply. The Cortex-M0 / M0+ / M1 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 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 have all base Thumb and Thumb-2 instructions. The Cortex-M3 adds 3 Thumb instructions, all Thumb-2 instructions, hardware 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).^[6]^[7]

ARM Cortex-M instruction variations^[6]^[7]
ARM Cortex-M	Thumb	Thumb-2	Hardware multiply	Hardware divide	Saturated math	DSP extensions	Floating-Point Unit (FPU)	ARM architecture
Cortex-M0^[1]	Most	Some	32-bit result	No	No	No	No	ARMv6-M
Cortex-M0+^[2]	Most	Some	32-bit result	No	No	No	No	ARMv6-M
Cortex-M1^[3]	Most	Some	32-bit result	No	No	No	No	ARMv6-M
Cortex-M3^[4]	Entire	Entire	32 or 64-bit result	Yes	Yes	No	No	ARMv7-M
Cortex-M4^[5]	Entire	Entire	32 or 64-bit result	Yes	Yes	Yes	Optional: SP	ARMv7E-M
Cortex-M7	Entire	Entire	32 or 64-bit result	Yes	Yes	Yes	Optional: SP or SP & DP	ARMv7E-M

Note: The Cortex-M0 / M0+ / M1 doesn't include these 16-bit Thumb instructions: CBZ, CBNZ, IT.^[6]^[7]
Note: The Cortex-M0 / M0+ / M1 only include these 32-bit Thumb-2 instructions: BL, DMB, DSB, ISB, MRS, MSR.^[6]^[7]
Note: The Cortex-M0 / M0+ / M1 only has 32-bit multiply instructions with a lower-32-bit result (32bit × 32bit = lower 32bit), where as the Cortex-M3 / M4 / M7 includes additional 32-bit multiply instructions with 64-bit results (32bit × 32bit = 64bit). The Cortex-M4 / M7 also include DSP instructions for (16bit × 16bit = 32bit), (32bit × 16bit = upper 32bit), (32bit × 32bit = upper 32bit) multiplications. If a smaller silicon die is required, the Cortex-M0 / M0+ / M1 has an option to be a much slower instruction, though it is rarely implemented in the M0 or M0+.^[6]^[7]
Note: The Cortex-M4 has a silicon FPU option (VFPv4-SP) of single-precision (SP), which is known as a Cortex-M4F. The Cortex-M7 has silicon FPU options (VFPv5) of single-precision (SP), or both single-precision (SP) and double-precision (DP). If the Cortex-M4 or M7 has a FPU, then it is known as the Cortex-M4F or Cortex-M7F.^[6]^[7]
Note: The Cortex-M series includes three new 16-bit Thumb instructions for sleep mode: SEV, WFE, WFI.

ARM Cortex-M instruction groups
Instructions	Instruction size	Cortex M0	Cortex M0+	Cortex M1	Cortex M3	Cortex M4	Cortex M7
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, STMIA, STR, STRB, STRH, SUB, SVC, SXTB, SXTH, TST, UXTB, UXTH, WFE, WFI, YIELD	16-bit	Yes	Yes	Yes	Yes	Yes	Yes
BL, DMB, DSB, ISB, MRS, MSR	32-bit	Yes	Yes	Yes	Yes	Yes	Yes
CBNZ, CBZ, IT	16-bit	No	No	No	Yes	Yes	Yes
ADC, ADD, ADR, AND, ASR, B, BFC, BFI, BIC, CDP, CLREX, CLZ, CMN, CMP, DBG, EOR, LDC, LDMA, LDMDB, LDR, LDRB, LDRBT, LDRD, LDREX, LDREXB, LDREXH, LDRH, LDRHT, LDRSB, LDRSBT, LDRSHT, LDRSH, LDRT, MCR, LSL, LSR, MLS, MCRR, MLA, MOV, MOVT, MRC, MRRC, MUL, MVN, NOP, ORN, ORR, PLD, PLDW, PLI, POP, PUSH, RBIT, REV, REV16, REVSH, ROR, RRX, RSB, SBC, SBFX, SDIV, SEV, SMLAL, SMULL, SSAT, STC, STMDB, STR, STRB, STRBT, STRD, STREX, STREXB, STREXH, STRH, STRHT, STRT, SUB, SXTB, SXTH, TBB, TBH, TEQ, TST, UBFX, UDIV, UMLAL, UMULL, USAT, UXTB, UXTH, WFE, WFI, YIELD	32-bit	No	No	No	Yes	Yes	Yes
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	32-bit	No	No	No	No	Yes	Yes
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	32-bit	No	No	No	No	Optional SP FPU	Optional SP FPU
VCVTA, VCVTM, VCVTN, VCVTP, VMAXNM, VMINNM, VRINTA, VRINTM, VRINTN, VRINTP, VRINTR, VRINTX, VRINTZ, VSEL	32-bit	No	No	No	No	No	Optional DP FPU

Note: The single-precision (SP) FPU instructions are valid in the Cortex-M4/M7 only when the SP FPU option exists in the silicon.
Note: The double-precision (DP) FPU instructions are valid in the Cortex-M7 only when the DP FPU option exists in the silicon.

ARM deprecations

The ARM architecture for ARM Cortex-M series removed some features from older legacy cores:^[6]^[7]

The 32-bit ARM instruction set is not included in Cortex-M cores.
Endianness is chosen at silicon implementation in Cortex-M cores. Legacy cores allowed "on-the-fly" changing of the data endian mode.
Co-processors aren't supported on Cortex-M cores.

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

The SWP and SWPB (swap) ARM instructions don't have a similar feature in Cortex-M.

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

"BLX <immediate>" instruction doesn't exist because it was used to switch from Thumb to ARM instruction set. The "BLX <register>" instruction is still available in the Cortex-M.
CPSIE and CPSID also don't exist because ARM instruction set is missing from Cortex-M. Other CPS instructions still exists in the Cortex-M.
SETEND doesn't exist because on-the-fly switching of data endian mode is no longer supported.
Co-processor instructions are not supported.
SWI instruction was renamed to SVC instruction, though the instruction binary coding is the same. However, the SVC handler code is different than SWI handler because of changes to the exception models.

Cortex-M0

Cortex-M0
Instruction set	Thumb (most), Thumb-2 (some)
Microarchitecture	ARMv6-M

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:^[1]

ARMv6-M architecture^[6]
3-stage pipeline.
Instruction sets:
- Thumb (most), missing CBZ, CBNZ, IT.
- Thumb-2 (some), only BL, DMB, DSB, ISB, MRS, MSR.
- 32-bit hardware multiply with 32-bit result.
1 to 32 interrupts, plus NMI.

Silicon options:

Hardware multiply speed: 1-cycle or 32-cycles.

Chips

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

Cypress PSoC 4
Infineon XMC1000
Nordic nRF51
NXP LPC1100, LPC1200
nuvoTon NuMicro
Sonix SN32F700
STMicroelectronics STM32 F0
Toshiba TX00
Vorago VA10800 (extreme temperature), VA10820 (radiation hardened)

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

NXP LPC4300 (one Cortex-M4F + one Cortex-M0)
Texas Instruments SimpleLink Wireless MCUs CC1310 and CC2650 (one programmable Cortex-M3 + one Cortex-M0 network processor + one proprietary Sensor Controller Engine)

Cortex-M0+

Cortex-M0+
Instruction set	Thumb (most), Thumb-2 (some)
Microarchitecture	ARMv6-M

Freescale FRDM-KL25Z Board with KL25Z128VLK (Kinetis L)

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. 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.^[2]

Key features of the Cortex-M0+ core are:^[2]

ARMv6-M architecture^[6]
2-stage pipeline (one fewer than Cortex-M0).
Instruction sets: (same as Cortex-M0)
- Thumb (most), missing CBZ, CBNZ, IT.
- Thumb-2 (some), only BL, DMB, DSB, ISB, MRS, MSR.
- 32-bit hardware multiply with 32-bit result.
1 to 32 interrupts, plus NMI.

Silicon options:

Hardware multiply speed: 1-cycle or 32-cycles.
8 region memory protection unit (MPU) (same as Cortex-M3 and Cortex-M4).
Vector table relocation (same as Cortex-M3 and Cortex-M4).
Single-cycle I/O port (unique to Cortex-M0+).
Micro Trace Buffer (MTB) (unique to Cortex-M0+).

Chips

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

Atmel SAMD, SAMR, SAML, SAMC
Cypress PSoC 4S and FM0+
Freescale/NXP Kinetis E, EA, L, M, V1, W0
Holtek HT32F52xxx
NXP LPC800, LPC11E6x, LPC11U6x
Renesas Synergy S1
Silicon Labs/Energy Micro EFM32 Zero, Happy
STMicroelectronics STM32 L0

Smallest ARM microcontrollers are of the Cortex-M0+ type (as of 2014, smallest at 1.6 mm by 2 mm is Kinetis KL03)^[12]

Cortex-M1

Cortex-M1
Instruction set	Thumb (most), Thumb-2 (some)
Microarchitecture	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:^[3]

ARMv6-M architecture^[6]
3-stage pipeline.
Instruction sets:
- Thumb (most), missing CBZ, CBNZ, IT.
- Thumb-2 (some), only BL, DMB, DSB, ISB, MRS, MSR.
- 32-bit hardware multiply with 32-bit result.
1 to 32 interrupts, plus NMI.

Silicon options:

Hardware multiply speed: 3-cycle or 33-cycles.
Optional Tightly-Coupled Memory (TCM): 0 to 1 MB instruction-TCM, 0 to 1 MB data-TCM, each with optional ECC.
External interrupts: 0, 1, 8, 16, 32.
Debug: none, reduced, full.
Data endianness: little-endian or BE-8 big-endian.
OS extension: present or absent.

Chips

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

Actel/Microsemi FPGAs
Altera FPGAs
Xilinx FPGAs

Cortex-M3

Cortex-M3
Instruction set	Thumb, Thumb-2, Saturated Math
Microarchitecture	ARMv7-M

Arduino Due board with Atmel ATSAM3X8E (ARM Cortex-M3 core) microcontroller

NXP LPCXpresso Development Board with LPC1343

The TI Ducati SIP core uses a Cortex-M3 cores to offload video acceleration and image processing.

Key features of the Cortex-M3 core are:^[4]^[13]

ARMv7-M architecture^[7]
3-stage pipeline with branch speculation.
Instruction sets:
- Thumb (entire).
- Thumb-2 (entire).
- 32-bit hardware multiply with 32-bit or 64-bit result, signed or unsigned, add or subtract after the multiply.
- 32-bit hardware divide (2-12 cycles).
- saturation arithmetic support.
1 to 240 interrupts, plus NMI.
12 cycle interrupt latency.
Integrated sleep modes.

Silicon options:

Optional Memory Protection Unit (MPU): 0 or 8 regions.

Chips

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

Actel SmartFusion, SmartFusion 2
Analog Devices ADuCM3xx
Atmel SAM3A, SAM3N, SAM3S, SAM3U, SAM3X
Cypress PSoC 5LP, FM3
Holtek HT32F
Luminary Micro/TI LM3S1968
NXP LPC1300, LPC1700, LPC1800
ON Semiconductor Q32M210
Silicon Labs Precision32
Silicon Labs/Energy Micro EFM32 Tiny, Gecko, Leopard, Giant
STMicroelectronics STM32 F1, F2, L1, W
Texas Instruments SimpleLink Wireless MCUs (CC1310 Sub-GHz and CC2650 BLE+ZigBee+6LoWPAN)
Toshiba TX03

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

Apple A9 (Cortex-M3 as integrated M9 motion Co-Processor)
CSR Quatro 5300 (Cortex-M3 as co-processor)
Samsung Exynos 7420 (Cortex-M3 as a DVS microcontroller)^[14]
Texas Instruments F28, LM3, TMS470, OMAP 4470 (one Cortex-A9 + two Cortex-M3)
XMOS XS1-XA (seven xCORE + one Cortex-M3)

Cortex-M4

Cortex-M4(F)
Instruction set	Thumb, Thumb-2, Saturated Math, DSP, FPU (SP) (M4F)
Microarchitecture	ARMv7E-M

Energy Micro Wonder Gecko STK Board with EFM32WG990

TI Stellaris Launchpad Board with LM4F120

Conceptually the Cortex-M4 is a Cortex-M3 plus DSP Instructions, and optional floating-point unit (FPU). If a core contains an FPU, it is known as a Cortex-M4F, otherwise it is a Cortex-M4.

Key features of the Cortex-M4 core are:^[5]

ARMv7E-M architecture^[7]
3-stage pipeline with branch speculation.
Instruction sets:
- Thumb (entire).
- Thumb-2 (entire).
- 32-bit hardware multiply with 32-bit or 64-bit result, signed or unsigned, add or subtract after the multiply.
- 32-bit hardware divide (2-12 cycles).
- Saturation arithmetic support.
- DSP extension: Single cycle 16/32-bit MAC, single cycle dual 16-bit MAC, 8/16-bit SIMD arithmetic.
1 to 240 interrupts, plus NMI.
12 cycle interrupt latency.
Integrated sleep modes.

Silicon options:

Optional Floating-Point Unit (FPU): single-precision only IEEE-754 compliant. It is called the FPv4-SP extension.
Optional Memory Protection Unit (MPU): 0 or 8 regions.

Chips

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

Atmel SAM4L, SAM4N, SAM4S, SAM4N
Freescale/NXP Kinetis K, W2

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

Atmel SAM4C (dual core), SAM4E, SAMG
Cypress FM4
Freescale/NXP Kinetis K, V3, V4
Infineon XMC4000
Microchip CEC1302
Nordic nRF52
NXP LPC4000, LPC4300 (one Cortex-M4F + one Cortex-M0)
Renesas Synergy S3, S5, S7
Silicon Labs/Energy Micro EFM32 Wonder
STMicroelectronics STM32 F3, F4, L4
Texas Instruments LM4F, TM4C, MSP432
Texas Instruments SimpleLink Wi-Fi CC3200 and CC3200MOD (FCC, IC, CE pre-certified module)
Toshiba TX04

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

Freescale/NXP Vybrid VF6 (one Cortex-A5 + one Cortex-M4F)
Freescale/NXP i.MX 6 SoloX (one Cortex-A9 + one Cortex-M4F)
Freescale/NXP i.MX 7 Solo/Dual (one or two Cortex-A7 + one Cortex-M4F)
Texas Instruments OMAP 5 (two Cortex-A15s + two Cortex-M4)
Texas Instruments Sitara AM57xx (one or two Cortex-A15s + two Cortex-M4s as image processing units + two Cortex-M4s as general purpose units)

Cortex-M7

Cortex-M7(F)
Instruction set	Thumb, Thumb-2, Saturated Math, DSP, FPU (SP & DP) (M7F)
Microarchitecture	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.^[15]^[16] 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:

ARMv7E-M architecture.
6-stage pipeline with branch speculation.
Instruction sets:
- Thumb (entire).
- Thumb-2 (entire).
- 32-bit hardware multiply with 32-bit or 64-bit result, signed or unsigned, add or subtract after the multiply.
- 32-bit hardware divide (2-12 cycles).
- Saturation arithmetic support.
- DSP extension: Single cycle 16/32-bit MAC, single cycle dual 16-bit MAC, 8/16-bit SIMD arithmetic.
1 to 240 interrupts, plus NMI.
12 cycle interrupt latency.
Integrated sleep modes.

Silicon options:

Optional Floating-Point Unit (FPU): (single precision) or (single and double-precision), both IEEE-754-2008 compliant. It is called the FPv5 extension.
Optional CPU cache: 0 to 64 KB instruction-cache, 0 to 64 KB data-cache, each with optional ECC.
Optional Tightly-Coupled Memory (TCM): 0 to 16 MB instruction-TCM, 0 to 16 MB data-TCM, each with optional ECC.
Optional Memory Protection Unit (MPU): 8 or 16 regions.
Optional Embedded Trace Macrocell (ETM): instruction-only, or instruction and data.
Optional Retention Mode (with ARM Power Management Kit) for Sleep Modes.

Chips

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

Atmel SAME70, SAMS70, SAMV70
Freescale/NXP Kinetis KV5x^[17]
STMicroelectronics STM32 F7,^[18] STM32 H7

Development tools

Main article: List of ARM Cortex-M development tools

Documentation

The amount of documentation for all ARM chips is daunting, especially for newcomers. The documentation for microcontrollers from past decades would easily be inclusive in a single document, but as chips have evolved so has the documentation grown. The total documentation is especially hard to grasp for all ARM chips since it consists of documents from the IC manufacturer and documents from CPU core vendor (ARM Holdings).

A typical top-down documentation tree is: manufacturer website, manufacturer marketing slides, manufacturer datasheet for the exact physical chip, manufacturer detailed reference manual that describes common peripherals and aspects of a physical chip family, ARM core generic user guide, ARM core technical reference manual, ARM architecture reference manual that describes the instruction set(s).

Documentation tree (top to bottom)

IC manufacturer website
IC manufacturer marketing slides
IC manufacturer datasheet
IC manufacturer reference manual
ARM core website
ARM core generic user guide
ARM core technical reference manual
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.

References

1 2 3 4 Cortex-M0 r0p0 Technical Reference Manual; ARM Holdings.
1 2 3 4 5 Cortex-M0+ r0p0 Technical Reference Manual; ARM Holdings.
1 2 3 4 Cortex-M1 r1p0 Technical Reference Manual; ARM Holdings.
1 2 3 4 Cortex-M3 r2p1 Technical Reference Manual; ARM Holdings.
1 2 3 4 Cortex-M4 r0p1 Technical Reference Manual; ARM Holdings.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 ARMv6-M Architecture Reference Manual; ARM Holdings.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 ARMv7-M Architecture Reference Manual; ARM Holdings.
1 2 3 4 Cortex-M3 Embedded Software Development; App Note 179; ARM Holdings.
1 2 3 Cortex-M System Design Kit; ARM Holdings.
↑ http://infocenter.arm.com/help/index.jsp?topic=/com.arm.doc.dai0321a/BIHEADII.html
↑ K60 Family Product Brief; Freescale; May 2011.
↑ Fingas, Jon (25 February 2014). "Freescale makes the world's smallest ARM controller chip even tinier". Retrieved 2 October 2014.
↑ Sadasivan, Shyam. "An Introduction to the ARM Cortex-M3 Processor" (PDF). ARM Holdings. Archived from the original on July 26, 2014. CS1 maint: Unfit url (link)
↑ "The Samsung Exynos 7420 Deep Dive - Inside A Modern 14nm SoC". AnandTech. Retrieved 2015-06-15.
↑ "Cortex-M7 Processor". ARM Holdings. Retrieved 2014-09-24.
↑ Press Release - ARM Supercharges MCU Market with High Performance Cortex-M7 Processor; arm.com; September 24, 2014;
↑ "KV5x: Kinetis KV5x - 240 MHz, ARM® Cortex®-M7, Real-Time Control, Ethernet, Motor Control and Power Conversion, High-Performance Microcontrollers (MCUs)". Freescale Semiconductor. Retrieved 2015-04-09.
↑ "STM32 F7 series of very high performance MCUs with ARM® Cortex®-M7 core". STMicroelectronics. Retrieved 2014-09-24.

External links

Wikimedia Commons has media related to ARM Cortex-M.

ARM Cortex-M official documents

ARM Core	ARM Website	ARM Generic User Guide	ARM Technical Reference Manual	ARM Architecture Reference Manual
Cortex-M0	Link	Link	Link	ARMv6-M
Cortex-M0+	Link	Link	Link	ARMv6-M
Cortex-M1	Link	Link	Link	ARMv6-M
Cortex-M3	Link	Link	Link	ARMv7-M
Cortex-M4	Link	Link	Link	ARMv7E-M
Cortex-M7	Link	Link	Link	ARMv7E-M

Quick Reference Cards

Instructions: Thumb (1), ARM and Thumb-2 (2), Vector Floating-Point (3), arm.com
Opcodes: Thumb (1, 2), ARM (3, 4), GNU Assembler Directives (5).

Migrating

Migrating from 8051 to Cortex-M, arm.com
Migrating from PIC to Cortex-M3, arm.com
Migrating from ARM7TDMI to Cortex-M3, arm.com

Other

Bit Banding on the STM32 microcontrollers

Embedded ARM-based chips

Embedded
microcontrollers

Cortex-M0	Cypress PSoC 4 Infineon XMC1000 Nordic nRF51 NXP LPC11xx, LPC12xx nuvoTon NuMicro Sonix SN32F700 STMicroelectronics STM32 F0 Toshiba TX00 Vorago VA108x0

Cortex-M0+	Atmel SAMD, SAMR Freescale/NXP Kinetis E, EA, L, M, V1, W0 Holtek HT32F52xxx NXP LPC8xx, LPC11E6x, LPC11U6x Silicon Labs/Energy Micro EFM32 Zero Spansion FM0+ STMicroelectronics STM32 L0

Cortex-M1	Actel FPGAs Altera FPGAs Xilinx FPGAs

Cortex-M3	Actel SmartFusion, SmartFusion 2 Analog Devices ADuCM3xx Atmel SAM3A, SAM3N, SAM3S, SAM3U, SAM3X Cypress PSoC 5 Energy Micro/Silicon Labs EFM32 Tiny, Gecko, Leopard, Giant Fujitsu FM3 Holtek HT32F NXP LPC13xx, LPC17xx, LPC18xx ON Semiconductor Q32M210 Silicon Labs Precision32 STMicroelectronics STM32 F1, F2, L1, W Texas Instruments F28, LM3, TMS470, OMAP 4 Toshiba TX03 XMOS XS1-XA

Cortex-M4	Atmel SAM4L, SAM4N, SAM4S Freescale/NXP Kinetis K, W2

Cortex-M4F	Atmel SAM4C, SAM4E, SAMG Energy Micro/Silicon Labs EFM32 Wonder Freescale/NXP Kinetis K, V3, V4 Infineon XMC4000 Microchip CEC1302 NXP LPC40xx, LPC43xx Spansion FM4 STMicroelectronics STM32 F3, F4 Texas Instruments LM4F/TM4C

Cortex-M7F	Atmel SAME70, SAMS70, SAMV70 STMicroelectronics STM32 F7, H7

Real-time
microcontrollers

Cortex-R4F	Texas Instruments RM4, TMS570

Cortex-R5F	Scaleo OLEA Texas Instruments RM57 Xilinx ZynqMP

Classic ARM-based chips

Classic
processors

ARM7	Atmel SAM7L, SAM7S, SAM7SE, SAM7X, SAM7XC, AT91CAP7, AT91M, AT91R NXP LPC21xx, LPC22xx, LPC23xx, LPC24xx, LH7 STMicroelectronics STR7

ARM9	Atmel SAM9G, SAM9M, SAM9N, SAM9R, SAM9X, SAM9XE, SAM926x, AT91CAP9 Freescale i.MX1x, i.MX2x Rockchip RK27xx, RK28xx NXP LPC29xx, LPC3xxx, LH7A ST-Ericsson Nomadik STn881x STMicroelectronics STR9 Texas Instruments OMAP 1, AM1x VIA WonderMedia WM8505/8650 ZiiLABS ZMS-05

ARM11	Broadcom BCM2835 Freescale i.MX3x Infotmic IMAPX210/220 Mindspeed Comcerto 1000 Nvidia Tegra APX, 6xx Qualcomm MSM7000, Snapdragon S1 ST-Ericsson Nomadik STn882x Telechips TCC8902 Texas Instruments OMAP 2 VIA WonderMedia WM87x0

ARMv2a compatible	Amber (open FPGA core)

ARMv4 compatible	DEC StrongARM

ARMv5 compatible	Intel/Marvell XScale Marvell Sheeva, Feroceon, Jolteon, Mohawk

ARMv6 compatible	Mindspeed Comcerto 1000

Microcontrollers

Main

Architectures

Families

4-bit	TLCS-47 TMS 1000 S1C6x μCOM-4 MARC4

8-bit	AVR PIC10/12/16/17/18 COP8 MCS-48/51 Z8 eZ80 68HC08/11 H8 TLCS-870 XC800 740

16-bit	C166 CR16/CR16C H8S MSP430 PIC24/dsPIC R8C RL78 TLCS-900 XC 2000 XE166 68HC12/16

32-bit	Am29000 ARM AVR32 ColdFire CRX FR FR-V H8SX M32R MPC5xx PIC32 PowerPC Propeller TLCS-900 TriCore V850

64-bit	ARM64 PowerPC64 MIPS64

Interfaces

Programming	In-circuit serial programming (ICSP) In-system programming (ISP) Program and Debug Interface (PDI) High-voltage serial programming (HVSP) High voltage parallel programming (HVPP) Bootloader ROM aWire

Debugging	debugWIRE Joint Test Action Group (JTAG) In-circuit debugging (ICD) In-circuit emulator (ICE) In-target probe (ITP)

Simulators

gpsim

Lists

Common microcontrollers
By manufacturer
- Freescale
- Intel

ARM Cortex-M

Overview

ARM license

Silicon customization

Instruction sets

ARM deprecations

Cortex-M0

Chips

Cortex-M0+

Chips

Cortex-M1

Chips

Cortex-M3

Chips

Cortex-M4

Chips

Cortex-M7

Chips

Development tools

Documentation

See also

References

Further reading

External links