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The SCTLR_EL1 characteristics are:
Provides top level control of the system, including its memory system, at EL1 and EL0.
AArch64 System register SCTLR_EL1 bits [31:0] are architecturally mapped to AArch32 System register SCTLR[31:0] .
Some or all RW fields of this register have defined reset values. These apply only if the PE resets into EL1 using AArch64. Otherwise, RW fields in this register reset to architecturally UNKNOWN values.
SCTLR_EL1 is a 64-bit register.
The SCTLR_EL1 bit assignments are:
63 | 62 | 61 | 60 | 59 | 58 | 57 | 56 | 55 | 54 | 53 | 52 | 51 | 50 | 49 | 48 | 47 | 46 | 45 | 44 | 43 | 42 | 41 | 40 | 39 | 38 | 37 | 36 | 35 | 34 | 33 | 32 |
RES0 | DSSBS | ATA | ATA0 | TCF | TCF0 | ITFSB | BT1 | BT0 | RES0 | ||||||||||||||||||||||
EnIA | EnIB | LSMAOE | nTLSMD | EnDA | UCI | EE | E0E | SPAN | EIS | IESB | TSCXT | WXN | nTWE | RES0 | nTWI | UCT | DZE | EnDB | I | EOS | EnRCTX | UMA | SED | ITD | nAA | CP15BEN | SA0 | SA | C | A | M |
31 | 30 | 29 | 28 | 27 | 26 | 25 | 24 | 23 | 22 | 21 | 20 | 19 | 18 | 17 | 16 | 15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
Reserved, RES0.
Default PSTATE.SSBS value on Exception Entry. The defined values are:
DSSBS | Meaning |
---|---|
0b0 | PSTATE.SSBS is set to 0 on an exception to EL1 |
0b1 | PSTATE.SSBS is set to 1 on an exception to EL1 |
In a system where the PE resets into EL1, this field resets to an IMPLEMENTATION DEFINED value.
Reserved, RES0.
Allocation Tag Access in EL1. When SCR_EL3.ATA=1 and HCR_EL2.ATA=1, controls EL1 access to Allocation Tags.
When access to Allocation Tags is prevented:
Instructions which Load or Store data are Unchecked.
Instructions which Load or Store Allocation Tags treat the Allocation Tag as RAZ/WI.
Instructions which insert Logical Address Tags into addresses treat the Allocation Tag used to generate the Logical Address Tag as 0.
Cache maintenance instructions which invalidate Allocation Tags from caches behave as the equivalent Clean and Invalidate operation on Allocation Tags.
ATA | Meaning |
---|---|
0b0 | Access to Allocation Tags is prevented. |
0b1 | Access to Allocation Tags is not prevented. |
This bit is permitted to be cached in a TLB.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Allocation Tag Access in EL0. When SCR_EL3.ATA=1, HCR_EL2.ATA=1, and HCR_EL2.{E2H,TGE} != {1,1}, controls EL0 access to Allocation Tags.
When access to Allocation Tags is prevented:
Instructions which Load or Store data are Unchecked.
Instructions which Load or Store Allocation Tags treat the Allocation Tag as RAZ/WI.
Instructions which insert Logical Address Tags into addresses treat the Allocation Tag used to generate the Logical Address Tag as 0.
Cache maintenance instructions which invalidate Allocation Tags from caches behave as the equivalent Clean and Invalidate operation on Allocation Tags.
ATA0 | Meaning |
---|---|
0b0 | Access to Allocation Tags is prevented. |
0b1 | Access to Allocation Tags is not prevented. |
This field is permitted to be cached in a TLB.
Software may change this control bit on a context switch.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Tag Check Fail in EL1. Controls the effect of tag check fails due to Loads and Stores in EL1.
TCF | Meaning |
---|---|
0b00 | Tag check fails have no effect on the PE. |
0b01 | Tag check fails causes a synchronous exception. |
0b10 | Tag check fails are asynchronously accumulated. |
The value 0b11 is reserved.
This field is permitted to be cached in a TLB.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Tag Check Fail in EL0. When HCR_EL2.{E2H,TGE} != {1,1}, controls the effect of tag check fails due to Loads and Stores in EL0.
TCF0 | Meaning |
---|---|
0b00 | Tag check fails have no effect on the PE. |
0b01 | Tag check fails causes a synchronous exception. |
0b10 | Tag check fails are asynchronously accumulated. |
The value 0b11 is reserved.
This field is permitted to be cached in a TLB.
Software may change this control bit on a context switch.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
When synchronous exceptions are not being generated by Tag Check fails which are generated for Loads and Stores in EL0 or EL1, controls the auto-synchronisaton of Tag Check fails into TFSRE0_EL1 and TFSR_EL1.
ITFSB | Meaning |
---|---|
0b0 | Tag check fails are not synchronized on entry to EL1. |
0b1 | Tag check fails are synchronized on entry to EL1. |
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
PAC Branch Type compatibility at EL1.
BT1 | Meaning |
---|---|
0b0 | When the PE is executing at EL1, PACIASP and PACIBSP are compatible with PSTATE.BTYPE == 0b11. |
0b1 | When the PE is executing at EL1, PACIASP and PACIBSP are not compatible with PSTATE.BTYPE == 0b11. |
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
PAC Branch Type compatibility at EL0.
BT0 | Meaning |
---|---|
0b0 | When the PE is executing at EL0, PACIASP and PACIBSP are compatible with PSTATE.BTYPE == 0b11. |
0b1 | When the PE is executing at EL0, PACIASP and PACIBSP are not compatible with PSTATE.BTYPE == 0b11. |
When HCR_EL2.E2H == 1 && HCR_EL2.TGE == 1, the value of the SCTLR_EL1.BT0 has no effect on execution at EL0
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Reserved, RES0.
Controls enabling of pointer authentication (using the APIAKey_EL1 key) of instruction addresses in the EL1&0 translation regime.
Possible values of this bit are:
EnIA | Meaning |
---|---|
0b0 | Pointer authentication (using the APIAKey_EL1 key) of instruction addresses is not enabled. |
0b1 | Pointer authentication (using the APIAKey_EL1 key) of instruction addresses is enabled. |
This field controls the behavior of the AddPACIA and AuthIA pseudocode functions. Specifically, when the field is 1, AddPACIA returns a copy of a pointer to which a pointer authentication code has been added, and AuthIA returns an authenticated copy of a pointer. When the field is 0, both of these functions are NOP.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Controls enabling of pointer authentication (using the APIBKey_EL1 key) of instruction addresses in the EL1&0 translation regime.
Possible values of this bit are:
EnIB | Meaning |
---|---|
0b0 | Pointer authentication (using the APIBKey_EL1 key) of instruction addresses is not enabled. |
0b1 | Pointer authentication (using the APIBKey_EL1 key) of instruction addresses is enabled. |
This field controls the behavior of the AddPACIB and AuthIB pseudocode functions. Specifically, when the field is 1, AddPACIB returns a copy of a pointer to which a pointer authentication code has been added, and AuthIB returns an authenticated copy of a pointer. When the field is 0, both of these functions are NOP.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Load Multiple and Store Multiple Atomicity and Ordering Enable.
LSMAOE | Meaning |
---|---|
0b0 | For all memory accesses at EL0, A32 and T32 Load Multiple and Store Multiple can have an interrupt taken during the sequence memory accesses, and the memory accesses are not required to be ordered. |
0b1 | The ordering and interrupt behavior of A32 and T32 Load Multiple and Store Multiple at EL0 is as defined for Armv8.0. |
This bit is permitted to be cached in a TLB.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1,1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES1.
No Trap Load Multiple and Store Multiple to Device-nGRE/Device-nGnRE/Device-nGnRnE memory.
nTLSMD | Meaning |
---|---|
0b0 | All memory accesses by A32 and T32 Load Multiple and Store Multiple at EL0 that are marked at stage 1 as Device-nGRE/Device-nGnRE/Device-nGnRnE memory are trapped and generate a stage 1 Alignment fault. |
0b1 | All memory accesses by A32 and T32 Load Multiple and Store Multiple at EL0 that are marked at stage 1 as Device-nGRE/Device-nGnRE/Device-nGnRnE memory are not trapped. |
This bit is permitted to be cached in a TLB.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1,1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES1.
Controls enabling of pointer authentication (using the APDAKey_EL1 key) of instruction addresses in the EL1&0 translation regime.
Possible values of this bit are:
EnDA | Meaning |
---|---|
0b0 | Pointer authentication (using the APDAKey_EL1 key) of data addresses is not enabled. |
0b1 | Pointer authentication (using the APDAKey_EL1 key) of data addresses is enabled. |
This field controls the behavior of the AddPACDA and AuthDA pseudocode functions. Specifically, when the field is 1, AddPACDA returns a copy of a pointer to which a pointer authentication code has been added, and AuthDA returns an authenticated copy of a pointer. When the field is 0, both of these functions are NOP.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Traps EL0 execution of cache maintenance instructions to EL1, from AArch64 state only. This applies to DC CVAU, DC CIVAC, DC CVAC, DC CVAP, and IC IVAU.
If ARMv8.2-DCCVADP is implemented, this trap also applies to DC CVADP.
If ARMv8.5-MemTag is implemented, this trap also applies to DC CIGVAC, DC CIGDVAC, DC CGVAC, DC CGDVAC, DC CGVAP, and DC CGDVAP.
If ARMv8.2-DCCVADP and ARMv8.5-MemTag are implemented, this trap also applies to DC CGVADP and DC CGDVADP.
UCI | Meaning |
---|---|
0b0 | Execution of the specified instructions at EL0 using AArch64 is trapped to EL1. |
0b1 | This control does not cause any instructions to be trapped. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
If the Point of Coherency is before any level of data cache, it is IMPLEMENTATION DEFINED whether the execution of any data or unified cache clean, or clean and invalidate instruction that operates by VA to the point of coherency can be trapped when the value of this control is 1.
If the Point of Unification is before any level of data cache, it is IMPLEMENTATION DEFINED whether the execution of any data or unified cache clean by VA to the Point of Unification instruction can be trapped when the value of this control is 1.
If the Point of Unification is before any level of instruction cache, it is IMPLEMENTATION DEFINED whether the execution of any instruction cache invalidate by VA to the Point of Unification instruction can be trapped when the value of this control is 1.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Endianness of data accesses at EL1, and stage 1 translation table walks in the EL1&0 translation regime.
The possible values of this bit are:
EE | Meaning |
---|---|
0b0 | Explicit data accesses at EL1, and stage 1 translation table walks in the EL1&0 translation regime are little-endian. |
0b1 | Explicit data accesses at EL1, and stage 1 translation table walks in the EL1&0 translation regime are big-endian. |
If an implementation does not provide Big-endian support at Exception Levels higher than EL0, this bit is RES0.
If an implementation does not provide Little-endian support at Exception Levels higher than EL0, this bit is RES1.
The EE bit is permitted to be cached in a TLB.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on the PE.
In a system where the PE resets into EL1, this field resets to an IMPLEMENTATION DEFINED value.
Endianness of data accesses at EL0.
The possible values of this bit are:
E0E | Meaning |
---|---|
0b0 | Explicit data accesses at EL0 are little-endian. |
0b1 | Explicit data accesses at EL0 are big-endian. |
If an implementation only supports Little-endian accesses at EL0 then this bit is RES0. This option is not permitted when SCTLR_EL1.EE is RES1.
If an implementation only supports Big-endian accesses at EL0 then this bit is RES1. This option is not permitted when SCTLR_EL1.EE is RES0.
This bit has no effect on the endianness of LDTR, LDTRH, LDTRSH, LDTRSW, STTR, and STTRH instructions executed at EL1.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Set Privileged Access Never, on taking an exception to EL1.
SPAN | Meaning |
---|---|
0b0 | PSTATE.PAN is set to 1 on taking an exception to EL1. |
0b1 | The value of PSTATE.PAN is left unchanged on taking an exception to EL1. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES1.
Exception Entry is Context Synchronizing. The defined values are:
EIS | Meaning |
---|---|
0b0 | The taking of an exception to EL1 is not a context synchronizing event. |
0b1 | The taking of an exception to EL1 is a context synchronizing event. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1,1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES1.
Implicit Error Synchronization event enable. Possible values are:
IESB | Meaning |
---|---|
0b0 | Disabled. |
0b1 | An implicit error synchronization event is added:
|
When the PE is in Debug state, the effect of this field is CONSTRAINED UNPREDICTABLE, and its Effective value might be 0 or 1 regardless of the value of the field. If the Effective value of the field is 1, then an implicit error synchronization event is added after each DCPSx instruction taken to EL1 and before each DRPS instruction executed at EL1, in addition to the other cases where it is added.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Trap EL0 Access to the SCXTNUM_EL0 register, when EL0 is using AArch64. The defined values are:
TSCXT | Meaning |
---|---|
0b0 | EL0 access to SCXTNUM_EL0 is not disabled by this mechanism. |
0b1 | EL0 access to SCXTNUM_EL0 is disabled, causing an exception to EL1, and the SCXTNUM_EL0 value is treated at 0. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1,1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES1.
Write permission implies XN (Execute-never). For the EL1&0 translation regime, this bit can force all memory regions that are writable to be treated as XN. The possible values of this bit are:
WXN | Meaning |
---|---|
0b0 | This control has no effect on memory access permissions. |
0b1 | Any region that is writable in the EL1&0 translation regime is forced to XN for accesses from software executing at EL1 or EL0. |
The WXN bit is permitted to be cached in a TLB.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on the PE.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Traps EL0 execution of WFE instructions to EL2, from both Execution states.
nTWE | Meaning |
---|---|
0b0 | Any attempt to execute a WFE instruction at EL0 is trapped to EL2, if the instruction would otherwise have caused the PE to enter a low-power state. |
0b1 | This control does not cause any instructions to be trapped. |
In AArch32 state, the attempted execution of a conditional WFE instruction is only trapped if the instruction passes its condition code check.
Since a WFE or WFI can complete at any time, even without a Wakeup event, the traps on WFE of WFI are not guaranteed to be taken, even if the WFE or WFI is executed when there is no Wakeup event. The only guarantee is that if the instruction does not complete in finite time in the absence of a Wakeup event, the trap will be taken.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Traps EL0 execution of WFE instructions to EL1, from both Execution states.
nTWE | Meaning |
---|---|
0b0 | Any attempt to execute a WFE instruction at EL0 is trapped to EL1, if the instruction would otherwise have caused the PE to enter a low-power state. |
0b1 | This control does not cause any instructions to be trapped. |
In AArch32 state, the attempted execution of a conditional WFE instruction is only trapped if the instruction passes its condition code check.
Since a WFE or WFI can complete at any time, even without a Wakeup event, the traps on WFE of WFI are not guaranteed to be taken, even if the WFE or WFI is executed when there is no Wakeup event. The only guarantee is that if the instruction does not complete in finite time in the absence of a Wakeup event, the trap will be taken.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Traps EL0 execution of WFI instructions to EL2, from both Execution states.
nTWI | Meaning |
---|---|
0b0 | Any attempt to execute a WFI instruction at EL0 is trapped to EL2, if the instruction would otherwise have caused the PE to enter a low-power state. |
0b1 | This control does not cause any instructions to be trapped. |
In AArch32 state, the attempted execution of a conditional WFI instruction is only trapped if the instruction passes its condition code check.
Since a WFE or WFI can complete at any time, even without a Wakeup event, the traps on WFE of WFI are not guaranteed to be taken, even if the WFE or WFI is executed when there is no Wakeup event. The only guarantee is that if the instruction does not complete in finite time in the absence of a Wakeup event, the trap will be taken.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Traps EL0 execution of WFI instructions to EL1, from both Execution states.
nTWI | Meaning |
---|---|
0b0 | Any attempt to execute a WFI instruction at EL0 is trapped to EL1, if the instruction would otherwise have caused the PE to enter a low-power state. |
0b1 | This control does not cause any instructions to be trapped. |
In AArch32 state, the attempted execution of a conditional WFI instruction is only trapped if the instruction passes its condition code check.
Since a WFE or WFI can complete at any time, even without a Wakeup event, the traps on WFE of WFI are not guaranteed to be taken, even if the WFE or WFI is executed when there is no Wakeup event. The only guarantee is that if the instruction does not complete in finite time in the absence of a Wakeup event, the trap will be taken.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Traps EL0 accesses to the CTR_EL0 to EL1, from AArch64 state only.
UCT | Meaning |
---|---|
0b0 | Accesses to the CTR_EL0 from EL0 using AArch64 are trapped to EL1. |
0b1 | This control does not cause any instructions to be trapped. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Traps EL0 execution of DC ZVA instructions to EL1, from AArch64 state only.
If ARMv8.5-MemTag is implemented, this trap also applies to DC GVA and DC GZVA.
DZE | Meaning |
---|---|
0b0 | Any attempt to execute an instruction that this trap applies to at EL0 using AArch64 is trapped to EL1. Reading DCZID_EL0.DZP from EL0 returns 1, indicating that the instructions this trap applies to are not supported. |
0b1 | This control does not cause any instructions to be trapped. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Controls enabling of pointer authentication (using the APDBKey_EL1 key) of instruction addresses in the EL1&0 translation regime.
EnDB | Meaning |
---|---|
0b0 | Pointer authentication (using the APDBKey_EL1 key) of data addresses is not enabled. |
0b1 | Pointer authentication (using the APDBKey_EL1 key) of data addresses is enabled. |
This field controls the behavior of the AddPACDB and AuthDB pseudocode functions. Specifically, when the field is 1, AddPACDB returns a copy of a pointer to which a pointer authentication code has been added, and AuthDB returns an authenticated copy of a pointer. When the field is 0, both of these functions are NOP.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
Instruction access Cacheability control, for accesses at EL0 and EL1:
I | Meaning |
---|---|
0b0 | All instruction access to Normal memory from EL0 and EL1 are Non-cacheable for all levels of instruction and unified cache. If the value of SCTLR_EL1.M is 0, instruction accesses from stage 1 of the EL1&0 translation regime are to Normal, Outer Shareable, Inner Non-cacheable, Outer Non-cacheable memory. |
0b1 | This control has no effect on the Cacheability of instruction access to Normal memory from EL0 and EL1. If the value of SCTLR_EL1.M is 0, instruction accesses from stage 1 of the EL1&0 translation regime are to Normal, Outer Shareable, Inner Write-Through, Outer Write-Through memory. |
When the value of the HCR_EL2.DC bit is 1, then instruction access to Normal memory from EL0 and EL1 are Cacheable regardless of the value of the SCTLR_EL1.I bit.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on the PE.
In a system where the PE resets into EL1, this field resets to 0.
Exception Exit is Context Synchronizing. The defined values are:
EOS | Meaning |
---|---|
0b0 | An exception return from EL1 is not a context synchronizing event |
0b1 | An exception return from EL1 is a context synchronizing event |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1,1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES1.
Enable EL0 Access to the AArch32 CFPRCTX, DVPRCTX and CPPRCTX instructions, and the AArch64 CFP RCTX, DVP RCT and CPP RCTX instructions. The defined values are:
EnRCTX | Meaning |
---|---|
0b0 | EL0 access to these instructions is disabled, and these instructions are trapped to EL1. |
0b1 | EL0 access to these instructions is enabled. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1,1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
User Mask Access. Traps EL0 execution of MSR and MRS instructions that access the PSTATE.{D, A, I, F} masks to EL1, from AArch64 state only.
UMA | Meaning |
---|---|
0b0 | Any attempt at EL0 using AArch64 to execute an MRS, MSR(register), or MSR(immediate) instruction that accesses the DAIF is trapped to EL1. |
0b1 | This control does not cause any instructions to be trapped. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
SETEND instruction disable. Disables SETEND instructions at EL0 using AArch32.
SED | Meaning |
---|---|
0b0 | SETEND instruction execution is enabled at EL0 using AArch32. |
0b1 | SETEND instructions are UNDEFINED at EL0 using AArch32. |
If the implementation does not support mixed-endian operation at any Exception level, this bit is RES1.
If EL0 cannot use AArch32, this bit is RES1.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
IT Disable. Disables some uses of IT instructions at EL0 using AArch32.
ITD | Meaning |
---|---|
0b0 | All IT instruction functionality is enabled at EL0 using AArch32. |
0b1 | Any attempt at EL0 using AArch32 to execute any of the following is UNDEFINED:
These instructions are always UNDEFINED, regardless of whether they would pass or fail the condition code check that applies to them as a result of being in an IT block. It is IMPLEMENTATION DEFINED whether the IT instruction is treated as:
This means that, for the situations that are UNDEFINED, either the second 16-bit instruction or the 32-bit instruction is UNDEFINED. An implementation might vary dynamically as to whether IT is treated as a 16-bit instruction or the first half of a 32-bit instruction. |
If an instruction in an active IT block that would be disabled by this field sets this field to 1 then behavior is CONSTRAINED UNPREDICTABLE. For more information see 'Changes to an ITD control by an instruction in an IT block' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, section E1.2.4
If EL0 cannot use AArch32, this bit is RES1.
ITD is optional, but if it is implemented in the SCTLR then it must also be implemented in the SCTLR_EL1. If it is not implemented then this bit is RAZ/WI.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Non-aligned access. This bit controls generation of Alignment faults at EL1 and EL0 under certain conditions.
nAA | Meaning |
---|---|
0b0 | LDAPR, LDAPRH, LDAPUR, LDAPURH, LDAPURSH, LDAPURSW, LDAPURW, LDAR, LDARH, LDLAR, LDLARH, STLLR, STLLRH, STLR, STLRH, STLUR, and STLURH generate an Alignment fault if all bytes being accessed are not within a single 16-byte quantity, aligned to 16 bytes for accesses. |
0b1 | This control bit does not cause LDAPR, LDAPRH, LDAPUR, LDAPURH, LDAPURSH, LDAPURSW, LDAPURW, LDAR, LDARH, LDLAR, LDLARH, STLLR, STLLRH, STLR, STLRH, STLUR, or STLURH to generate an Alignment fault if all bytes being accessed are not within a single 16-byte quantity, aligned to 16 bytes. |
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Reserved, RES0.
System instruction memory barrier enable. Enables accesses to the DMB, DSB, and ISB System instructions in the (coproc==0b1111) encoding space from EL0:
CP15BEN | Meaning |
---|---|
0b0 | EL0 using AArch32: EL0 execution of the CP15DMB, CP15DSB, and CP15ISB instructions is UNDEFINED. |
0b1 | EL0 using AArch32: EL0 execution of the CP15DMB, CP15DSB, and CP15ISB instructions is enabled. |
If EL0 cannot use AArch32, this bit is RES0.
CP15BEN is optional, but if it is implemented in the SCTLR then it must also be implemented in the SCTLR_EL1. If it is not implemented then this bit is RAO/WI.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
SP Alignment check enable for EL0. When set to 1, if a load or store instruction executed at EL0 uses the SP as the base address and the SP is not aligned to a 16-byte boundary, then a SP alignment fault exception is generated. For more information, see 'SP alignment checking' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, section D1 (The AArch64 System Level Programmers' Model).
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
SP Alignment check enable. When set to 1, if a load or store instruction executed at EL1 uses the SP as the base address and the SP is not aligned to a 16-byte boundary, then a SP alignment fault exception is generated. For more information, see 'SP alignment checking' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, section D1 (The AArch64 System Level Programmers' Model).
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on the PE.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
Cacheability control, for data accesses.
C | Meaning |
---|---|
0b0 | All data access to Normal memory from EL0 and EL1, and all Normal memory accesses to the EL1&0 stage 1 translation tables, are Non-cacheable for all levels of data and unified cache. |
0b1 | This control has no effect on the Cacheability of:
|
When the value of the HCR_EL2.DC bit is 1, the PE ignores SCLTR.C. This means that Non-secure EL0 and Non-secure EL1 data accesses to Normal memory are Cacheable.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on the PE.
In a system where the PE resets into EL1, this field resets to 0.
Alignment check enable. This is the enable bit for Alignment fault checking at EL1 and EL0.
A | Meaning |
---|---|
0b0 | Alignment fault checking disabled when executing at EL1 or EL0. Instructions that load or store one or more registers, other than load/store exclusive and load-acquire/store-release, do not check that the address being accessed is aligned to the size of the data element(s) being accessed. |
0b1 | Alignment fault checking enabled when executing at EL1 or EL0. All instructions that load or store one or more registers have an alignment check that the address being accessed is aligned to the size of the data element(s) being accessed. If this check fails it causes an Alignment fault, which is taken as a Data Abort exception. |
Load/store exclusive and load-acquire/store-release instructions have an alignment check regardless of the value of the A bit.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on execution at EL0.
In a system where the PE resets into EL1, this field resets to an architecturally UNKNOWN value.
MMU enable for EL1 and EL0 stage 1 address translation. Possible values of this bit are:
M | Meaning |
---|---|
0b0 | EL1 and EL0 stage 1 address translation disabled. See the SCTLR_EL1.I field for the behavior of instruction accesses to Normal memory. |
0b1 | EL1 and EL0 stage 1 address translation enabled. |
If the value of HCR_EL2.{DC, TGE} is not {0, 0} then in Non-secure state the PE behaves as if the value of the SCTLR_EL1.M field is 0 for all purposes other than returning the value of a direct read of the field.
When ARMv8.1-VHE is implemented, and the value of HCR_EL2.{E2H, TGE} is {1, 1}, this bit has no effect on the PE.
In a system where the PE resets into EL1, this field resets to 0.
When HCR_EL2.E2H is 1, without explicit synchronization, access from EL3 using the mnemonic SCTLR_EL1 or SCTLR_EL12 are not guaranteed to be ordered with respect to accesses using the other mnemonic.
Accesses to this register use the following encodings:
op0 | op1 | CRn | CRm | op2 |
---|---|---|---|---|
0b11 | 0b000 | 0b0001 | 0b0000 | 0b000 |
if PSTATE.EL == EL0 then UNDEFINED; elsif PSTATE.EL == EL1 then if EL2Enabled() && !ELUsingAArch32(EL2) && HCR_EL2.TRVM == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && !ELUsingAArch32(EL2) && HCR_EL2.<NV2,NV1,NV> == '111' then return NVMem[0x110]; else return SCTLR_EL1; elsif PSTATE.EL == EL2 then if HCR_EL2.E2H == '1' then return SCTLR_EL2; else return SCTLR_EL1; elsif PSTATE.EL == EL3 then return SCTLR_EL1;
op0 | op1 | CRn | CRm | op2 |
---|---|---|---|---|
0b11 | 0b000 | 0b0001 | 0b0000 | 0b000 |
if PSTATE.EL == EL0 then UNDEFINED; elsif PSTATE.EL == EL1 then if EL2Enabled() && !ELUsingAArch32(EL2) && HCR_EL2.TVM == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && !ELUsingAArch32(EL2) && HCR_EL2.<NV2,NV1,NV> == '111' then NVMem[0x110] = X[t]; else SCTLR_EL1 = X[t]; elsif PSTATE.EL == EL2 then if HCR_EL2.E2H == '1' then SCTLR_EL2 = X[t]; else SCTLR_EL1 = X[t]; elsif PSTATE.EL == EL3 then SCTLR_EL1 = X[t];
op0 | op1 | CRn | CRm | op2 |
---|---|---|---|---|
0b11 | 0b101 | 0b0001 | 0b0000 | 0b000 |
if PSTATE.EL == EL0 then
UNDEFINED;
elsif PSTATE.EL == EL1 then
if EL2Enabled() && HCR_EL2.<NV2,NV1,NV> == '101' then
return NVMem[0x110];
elsif EL2Enabled() && HCR_EL2.NV == '1' then
AArch64.SystemAccessTrap(EL2, 0x18);
else
UNDEFINED;
elsif PSTATE.EL == EL2 then
if EL2Enabled() && HCR_EL2.E2H == '1' then
if PSTATE.EL == EL2 then
return SCTLR_EL1;
else
UNDEFINED;
elsif PSTATE.EL == EL3 then
if EL2Enabled() && HCR_EL2.E2H == '1' then
return SCTLR_EL1;
else
else
UNDEFINED;
op0 | op1 | CRn | CRm | op2 |
---|---|---|---|---|
0b11 | 0b101 | 0b0001 | 0b0000 | 0b000 |
if PSTATE.EL == EL0 then
UNDEFINED;
elsif PSTATE.EL == EL1 then
if EL2Enabled() && HCR_EL2.<NV2,NV1,NV> == '101' then
NVMem[0x110] = X[t];
elsif EL2Enabled() && HCR_EL2.NV == '1' then
AArch64.SystemAccessTrap(EL2, 0x18);
else
UNDEFINED;
elsif PSTATE.EL == EL2 then
if EL2Enabled() && HCR_EL2.E2H == '1' then
if PSTATE.EL == EL2 then
SCTLR_EL1 = X[t];
else
UNDEFINED;
elsif PSTATE.EL == EL3 then
if EL2Enabled() && HCR_EL2.E2H == '1' then
SCTLR_EL1 = X[t];
else
else
UNDEFINED;
2713/0312/20192018 2116:5942; e5e4db499bf9867a4b93324c4dbac985d3da93766379d01c197f1d40720d32d0f84c419c9187c009
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