A-profile CPU architecture support
QEMU’s TCG emulation includes support for the Armv5, Armv6, Armv7 and Armv8 versions of the A-profile architecture. It also has support for the following architecture extensions:
FEAT_AA32BF16 (AArch32 BFloat16 instructions)
FEAT_AA32EL0 (Support for AArch32 at EL0)
FEAT_AA32EL1 (Support for AArch32 at EL1)
FEAT_AA32EL2 (Support for AArch32 at EL2)
FEAT_AA32EL3 (Support for AArch32 at EL3)
FEAT_AA32HPD (AArch32 hierarchical permission disables)
FEAT_AA32I8MM (AArch32 Int8 matrix multiplication instructions)
FEAT_AA64EL0 (Support for AArch64 at EL0)
FEAT_AA64EL1 (Support for AArch64 at EL1)
FEAT_AA64EL2 (Support for AArch64 at EL2)
FEAT_AA64EL3 (Support for AArch64 at EL3)
FEAT_AdvSIMD (Advanced SIMD Extension)
FEAT_AES (AESD and AESE instructions)
FEAT_Armv9_Crypto (Armv9 Cryptographic Extension)
FEAT_ASID16 (16 bit ASID)
FEAT_BBM at level 2 (Translation table break-before-make levels)
FEAT_BF16 (AArch64 BFloat16 instructions)
FEAT_BTI (Branch Target Identification)
FEAT_CCIDX (Extended cache index)
FEAT_CRC32 (CRC32 instructions)
FEAT_Crypto (Cryptographic Extension)
FEAT_CSV2 (Cache speculation variant 2)
FEAT_CSV2_1p1 (Cache speculation variant 2, version 1.1)
FEAT_CSV2_1p2 (Cache speculation variant 2, version 1.2)
FEAT_CSV2_2 (Cache speculation variant 2, version 2)
FEAT_CSV2_3 (Cache speculation variant 2, version 3)
FEAT_CSV3 (Cache speculation variant 3)
FEAT_DGH (Data gathering hint)
FEAT_DIT (Data Independent Timing instructions)
FEAT_DPB (DC CVAP instruction)
FEAT_DPB2 (DC CVADP instruction)
FEAT_Debugv8p1 (Debug with VHE)
FEAT_Debugv8p2 (Debug changes for v8.2)
FEAT_Debugv8p4 (Debug changes for v8.4)
FEAT_Debugv8p8 (Debug changes for v8.8)
FEAT_DotProd (Advanced SIMD dot product instructions)
FEAT_DoubleFault (Double Fault Extension)
FEAT_E0PD (Preventing EL0 access to halves of address maps)
FEAT_ECV (Enhanced Counter Virtualization)
FEAT_EL0 (Support for execution at EL0)
FEAT_EL1 (Support for execution at EL1)
FEAT_EL2 (Support for execution at EL2)
FEAT_EL3 (Support for execution at EL3)
FEAT_EPAC (Enhanced pointer authentication)
FEAT_ETS2 (Enhanced Translation Synchronization)
FEAT_EVT (Enhanced Virtualization Traps)
FEAT_F32MM (Single-precision Matrix Multiplication)
FEAT_F64MM (Double-precision Matrix Multiplication)
FEAT_FCMA (Floating-point complex number instructions)
FEAT_FGT (Fine-Grained Traps)
FEAT_FHM (Floating-point half-precision multiplication instructions)
FEAT_FP (Floating Point extensions)
FEAT_FP16 (Half-precision floating-point data processing)
FEAT_FPAC (Faulting on AUT* instructions)
FEAT_FPACCOMBINE (Faulting on combined pointer authentication instructions)
FEAT_FPACC_SPEC (Speculative behavior of combined pointer authentication instructions)
FEAT_FRINTTS (Floating-point to integer instructions)
FEAT_FlagM (Flag manipulation instructions v2)
FEAT_FlagM2 (Enhancements to flag manipulation instructions)
FEAT_GTG (Guest translation granule size)
FEAT_HAFDBS (Hardware management of the access flag and dirty bit state)
FEAT_HBC (Hinted conditional branches)
FEAT_HCX (Support for the HCRX_EL2 register)
FEAT_HPDS (Hierarchical permission disables)
FEAT_HPDS2 (Translation table page-based hardware attributes)
FEAT_HPMN0 (Setting of MDCR_EL2.HPMN to zero)
FEAT_I8MM (AArch64 Int8 matrix multiplication instructions)
FEAT_IDST (ID space trap handling)
FEAT_IESB (Implicit error synchronization event)
FEAT_JSCVT (JavaScript conversion instructions)
FEAT_LOR (Limited ordering regions)
FEAT_LPA (Large Physical Address space)
FEAT_LPA2 (Large Physical and virtual Address space v2)
FEAT_LRCPC (Load-acquire RCpc instructions)
FEAT_LRCPC2 (Load-acquire RCpc instructions v2)
FEAT_LSE (Large System Extensions)
FEAT_LSE2 (Large System Extensions v2)
FEAT_LVA (Large Virtual Address space)
FEAT_MixedEnd (Mixed-endian support)
FEAT_MixdEndEL0 (Mixed-endian support at EL0)
FEAT_MOPS (Standardization of memory operations)
FEAT_MTE (Memory Tagging Extension)
FEAT_MTE2 (Memory Tagging Extension)
FEAT_MTE3 (MTE Asymmetric Fault Handling)
FEAT_MTE_ASYM_FAULT (Memory tagging asymmetric faults)
FEAT_NMI (Non-maskable Interrupt)
FEAT_NV (Nested Virtualization)
FEAT_NV2 (Enhanced nested virtualization support)
FEAT_PACIMP (Pointer authentication - IMPLEMENTATION DEFINED algorithm)
FEAT_PACQARMA3 (Pointer authentication - QARMA3 algorithm)
FEAT_PACQARMA5 (Pointer authentication - QARMA5 algorithm)
FEAT_PAN (Privileged access never)
FEAT_PAN2 (AT S1E1R and AT S1E1W instruction variants affected by PSTATE.PAN)
FEAT_PAN3 (Support for SCTLR_ELx.EPAN)
FEAT_PAuth (Pointer authentication)
FEAT_PAuth2 (Enhancements to pointer authentication)
FEAT_PMULL (PMULL, PMULL2 instructions)
FEAT_PMUv3 (PMU extension version 3)
FEAT_PMUv3p1 (PMU Extensions v3.1)
FEAT_PMUv3p4 (PMU Extensions v3.4)
FEAT_PMUv3p5 (PMU Extensions v3.5)
FEAT_RAS (Reliability, availability, and serviceability)
FEAT_RASv1p1 (RAS Extension v1.1)
FEAT_RDM (Advanced SIMD rounding double multiply accumulate instructions)
FEAT_RME (Realm Management Extension) (NB: support status in QEMU is experimental)
FEAT_RNG (Random number generator)
FEAT_S2FWB (Stage 2 forced Write-Back)
FEAT_SB (Speculation Barrier)
FEAT_SEL2 (Secure EL2)
FEAT_SHA1 (SHA1 instructions)
FEAT_SHA256 (SHA256 instructions)
FEAT_SHA3 (Advanced SIMD SHA3 instructions)
FEAT_SHA512 (Advanced SIMD SHA512 instructions)
FEAT_SM3 (Advanced SIMD SM3 instructions)
FEAT_SM4 (Advanced SIMD SM4 instructions)
FEAT_SME (Scalable Matrix Extension)
FEAT_SME_FA64 (Full A64 instruction set in Streaming SVE mode)
FEAT_SME_F64F64 (Double-precision floating-point outer product instructions)
FEAT_SME_I16I64 (16-bit to 64-bit integer widening outer product instructions)
FEAT_SVE (Scalable Vector Extension)
FEAT_SVE_AES (Scalable Vector AES instructions)
FEAT_SVE_BitPerm (Scalable Vector Bit Permutes instructions)
FEAT_SVE_PMULL128 (Scalable Vector PMULL instructions)
FEAT_SVE_SHA3 (Scalable Vector SHA3 instructions)
FEAT_SVE_SM4 (Scalable Vector SM4 instructions)
FEAT_SVE2 (Scalable Vector Extension version 2)
FEAT_SPECRES (Speculation restriction instructions)
FEAT_SSBS (Speculative Store Bypass Safe)
FEAT_TGran16K (Support for 16KB memory translation granule size at stage 1)
FEAT_TGran4K (Support for 4KB memory translation granule size at stage 1)
FEAT_TGran64K (Support for 64KB memory translation granule size at stage 1)
FEAT_TIDCP1 (EL0 use of IMPLEMENTATION DEFINED functionality)
FEAT_TLBIOS (TLB invalidate instructions in Outer Shareable domain)
FEAT_TLBIRANGE (TLB invalidate range instructions)
FEAT_TTCNP (Translation table Common not private translations)
FEAT_TTL (Translation Table Level)
FEAT_TTST (Small translation tables)
FEAT_UAO (Unprivileged Access Override control)
FEAT_VHE (Virtualization Host Extensions)
FEAT_VMID16 (16-bit VMID)
FEAT_WFxT (WFE and WFI instructions with timeout)
FEAT_XNX (Translation table stage 2 Unprivileged Execute-never)
For information on the specifics of these extensions, please refer to the Armv8-A Arm Architecture Reference Manual.
When a specific named CPU is being emulated, only those features which
are present in hardware for that CPU are emulated. (If a feature is
not in the list above then it is not supported, even if the real
hardware should have it.) The max
CPU enables all features.
R-profile CPU architecture support
QEMU’s TCG emulation support for R-profile CPUs is currently limited. We emulate only the Cortex-R5 and Cortex-R5F CPUs.
M-profile CPU architecture support
QEMU’s TCG emulation includes support for Armv6-M, Armv7-M, Armv8-M, and Armv8.1-M versions of the M-profile architucture. It also has support for the following architecture extensions:
FP (Floating-point Extension)
FPCXT (FPCXT access instructions)
HP (Half-precision floating-point instructions)
LOB (Low Overhead loops and Branch future)
M (Main Extension)
MPU (Memory Protection Unit Extension)
PXN (Privileged Execute Never)
RAS (Reliability, Serviceability and Availability): “minimum RAS Extension” only
S (Security Extension)
ST (System Timer Extension)
For information on the specifics of these extensions, please refer to the Armv8-M Arm Architecture Reference Manual.
When a specific named CPU is being emulated, only those features which
are present in hardware for that CPU are emulated. (If a feature is
not in the list above then it is not supported, even if the real
hardware should have it.) There is no equivalent of the max
CPU for
M-profile.