← Home

SCTLR: System Control Register

Purpose

Provides the top level control of the system, including its memory system.

Configuration

This register is banked between SCTLR and SCTLR_S and SCTLR_NS.

AArch32 System register SCTLR bits [31:0] are architecturally mapped to AArch64 System register SCTLR_EL1[31:0].

This register is present only when EL1 is capable of using AArch32. Otherwise, direct accesses to SCTLR are UNDEFINED.

Some bits in the register are read-only. These bits relate to non-configurable features of an implementation, and are provided for compatibility with previous versions of the architecture.

Attributes

SCTLR is a 32-bit register.

This register has the following instances:

Field descriptions

313029282726252423222120191817161514131211109876543210
DSSBSTEAFETRERES0EERES0SPANRES1RES0UWXNWXNnTWERES0nTWIRES0VIRES1EnRCTXRES0SEDITDUNKCP15BENLSMAOEnTLSMDCAM

DSSBS, bit [31]

When FEAT_SSBS is implemented:

Default PSTATE.SSBS value on Exception Entry. The defined values are:

DSSBSMeaning
0b0

PSTATE.SSBS is set to 0 on an exception to any mode in this security state except Hyp mode

0b1

PSTATE.SSBS is set to 1 on an exception to any mode in this security state except Hyp mode

Note

When EL3 is implemented and is using AArch32, this bit is banked between the two Security states.

The reset behavior of this field is:



Otherwise:

Reserved, RES0.

TE, bit [30]

T32 Exception Enable. This bit controls whether exceptions to an Exception level that is executing at PL1 are taken to A32 or T32 state:

TEMeaning
0b0

Exceptions, including reset, taken to A32 state.

0b1

Exceptions, including reset, taken to T32 state.

The reset behavior of this field is:

AFE, bit [29]

Access Flag Enable. When using the Short-descriptor translation table format for the PL1&0 translation regime, this bit enables use of the AP[0] bit in the translation descriptors as the Access flag, and restricts access permissions in the translation descriptors to the simplified model.

AFEMeaning
0b0

In the Translation table descriptors, AP[0] is an access permissions bit. The full range of access permissions is supported. No Access flag is implemented.

0b1

In the Translation table descriptors, AP[0] is the Access flag. Only the simplified model for access permissions is supported.

When using the Long-descriptor translation table format, the VMSA behaves as if this bit is set to 1, regardless of the value of this bit.

The AFE bit is permitted to be cached in a TLB.

The reset behavior of this field is:

TRE, bit [28]

TEX remap enable. This bit enables remapping of the TEX[2:1] bits in the PL1&0 translation regime for use as two translation table bits that can be managed by the operating system. Enabling this remapping also changes the scheme used to describe the memory region attributes in the VMSA.

TREMeaning
0b0

TEX remap disabled. TEX[2:0] are used, with the C and B bits, to describe the memory region attributes.

0b1

TEX remap enabled. TEX[2:1] are reassigned for use as bits managed by the operating system. The TEX[0], C, and B bits are used to describe the memory region attributes, with the MMU remap registers.

When the value of TTBCR.EAE is 1, this bit is RES1.

The TRE bit is permitted to be cached in a TLB.

The reset behavior of this field is:

Bits [27:26]

Reserved, RES0.

EE, bit [25]

The value of the PSTATE.E bit on branch to an exception vector or coming out of reset, and the endianness of stage 1 translation table walks in the PL1&0 translation regime.

EEMeaning
0b0

Little-endian. PSTATE.E is cleared to 0 on taking an exception or coming out of reset. Stage 1 translation table walks in the PL1&0 translation regime are little-endian.

0b1

Big-endian. PSTATE.E is set to 1 on taking an exception or coming out of reset. Stage 1 translation table walks in the PL1&0 translation regime are big-endian.

If an implementation does not provide Big-endian support for data accesses at Exception levels higher than EL0, this bit is RES0.

If an implementation does not provide Little-endian support for data accesses at Exception levels higher than EL0, this bit is RES1.

The reset behavior of this field is:

Bit [24]

Reserved, RES0.

SPAN, bit [23]

When FEAT_PAN is implemented:

Set Privileged Access Never, on taking an exception to EL1 from either Secure or Non-secure state, or to EL3 from Secure state when EL3 is using AArch32.

SPANMeaning
0b0

PSTATE.PAN is set to 1 in the following situations:

  • In Non-secure state, on taking an exception to EL1.
  • In Secure state, when EL3 is using AArch64, on taking an exception to EL1.
  • In Secure state, when EL3 is using AArch32, on taking an exception to EL3.
0b1

The value of PSTATE.PAN is left unchanged on taking an exception to EL1.

The reset behavior of this field is:



Otherwise:

Reserved, RES1.

Bit [22]

Reserved, RES1.

Bit [21]

Reserved, RES0.

UWXN, bit [20]

Unprivileged write permission implies PL1 XN (Execute-never). This bit can force all memory regions that are writable at PL0 to be treated as XN for accesses from software executing at PL1.

UWXNMeaning
0b0

This control has no effect on memory access permissions.

0b1

Any region that is writable at PL0 forced to XN for accesses from software executing at PL1.

The UWXN bit is permitted to be cached in a TLB.

The reset behavior of this field is:

WXN, bit [19]

Write permission implies XN (Execute-never). For the PL1&0 translation regime, this bit can force all memory regions that are writable to be treated as XN.

WXNMeaning
0b0

This control has no effect on memory access permissions.

0b1

Any region that is writable in the PL1&0 translation regime is forced to XN for accesses from software executing at PL1 or PL0.

This bit applies only when SCTLR.M bit is set.

The WXN bit is permitted to be cached in a TLB.

The reset behavior of this field is:

nTWE, bit [18]

Traps EL0 execution of WFE instructions to Undefined mode.

nTWEMeaning
0b0

Any attempt to execute a WFE instruction at EL0 is trapped to Undefined mode, 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.

The attempted execution of a conditional WFE instruction is only trapped if the instruction passes its condition code check.

Note

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.

The reset behavior of this field is:

Bit [17]

Reserved, RES0.

nTWI, bit [16]

Traps EL0 execution of WFI instructions to Undefined mode.

nTWIMeaning
0b0

Any attempt to execute a WFI instruction at EL0 is trapped to Undefined mode, 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.

The attempted execution of a conditional WFI instruction is only trapped if the instruction passes its condition code check.

Note

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.

The reset behavior of this field is:

Bits [15:14]

Reserved, RES0.

V, bit [13]

Vectors bit. This bit selects the base address of the exception vectors for exceptions taken to a PE mode other than Monitor mode or Hyp mode:

VMeaning
0b0

Normal exception vectors. Base address is held in VBAR.

0b1

High exception vectors (Hivecs), base address 0xFFFF0000. This base address cannot be remapped.

The reset behavior of this field is:

I, bit [12]

Instruction access Cacheability control, for accesses at EL1 and EL0:

IMeaning
0b0

All instruction access to Normal memory from PL1 and PL0 are Non-cacheable for all levels of instruction and unified cache.

If the value of SCTLR.M is 0, instruction accesses from stage 1 of the PL1&0 translation regime are to Normal, Outer Shareable, Inner Non-cacheable, Outer Non-cacheable memory.

0b1

All instruction access to Normal memory from PL1 and PL0 can be cached at all levels of instruction and unified cache.

If the value of SCTLR.M is 0, instruction accesses from stage 1 of the PL1&0 translation regime are to Normal, Outer Shareable, Inner Write-Through, Outer Write-Through memory.

Instruction accesses to Normal memory from EL1 and EL0 are Cacheable regardless of the value of the SCTLR.I bit if either:

The reset behavior of this field is:

Bit [11]

Reserved, RES1.

EnRCTX, bit [10]

When FEAT_SPECRES is implemented:

Enable EL0 access to the following System instructions:

EnRCTXMeaning
0b0

EL0 access to these instructions is disabled, and these instructions are trapped to EL1.

0b1

EL0 access to these instructions is enabled.

Note

When EL3 is implemented and is using AArch32, this bit is banked between the two Security states.

The reset behavior of this field is:



Otherwise:

Reserved, RES0.

Bit [9]

Reserved, RES0.

SED, bit [8]

SETEND instruction disable. Disables SETEND instructions at PL0 and PL1.

SEDMeaning
0b0

SETEND instruction execution is enabled at PL0 and PL1.

0b1

SETEND instructions are UNDEFINED at PL0 and PL1.

If the implementation does not support mixed-endian operation at any Exception level, this bit is RES1.

The reset behavior of this field is:

ITD, bit [7]

IT Disable. Disables some uses of IT instructions at PL1 and PL0.

ITDMeaning
0b0

All IT instruction functionality is enabled at PL1 and PL0.

0b1

Any attempt at PL1 or PL0 to execute any of the following is UNDEFINED:

  • All encodings of the IT instruction with hw1[3:0]!=1000.
  • All encodings of the subsequent instruction with the following values for hw1:
    • 11xxxxxxxxxxxxxx: All 32-bit instructions, and the 16-bit instructions B, UDF, SVC, LDM, and STM.
    • 1011xxxxxxxxxxxx: All instructions in 'Miscellaneous 16-bit instructions'.
    • 10100xxxxxxxxxxx: ADD Rd, PC, #imm
    • 01001xxxxxxxxxxx: LDR Rd, [PC, #imm]
    • 0100x1xxx1111xxx: ADD Rdn, PC; CMP Rn, PC; MOV Rd, PC; BX PC; BLX PC.
    • 010001xx1xxxx111: ADD PC, Rm; CMP PC, Rm; MOV PC, Rm. This pattern also covers unpredictable cases with BLX Rn.

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:

  • A 16-bit instruction, that can only be followed by another 16-bit instruction.
  • The first half of a 32-bit instruction.

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'.

ITD is optional, but if it is implemented in the SCTLR then it must also be implemented in the SCTLR_EL1, SCTLR_EL2, and HSCTLR.

The reset behavior of this field is:

When an implementation does not implement ITD, access to this field is RAZ/WI.

UNK, bit [6]

Writes to this bit are IGNORED. Reads of this bit return an UNKNOWN value.

The reset behavior of this field is:

CP15BEN, bit [5]

System instruction memory barrier enable. Enables accesses to the DMB, DSB, and ISB System instructions in the (coproc==0b1111) encoding space from PL1 and PL0:

CP15BENMeaning
0b0

PL0 and PL1 execution of the CP15DMB, CP15DSB, and CP15ISB instructions is UNDEFINED.

0b1

PL0 and PL1 execution of the CP15DMB, CP15DSB, and CP15ISB instructions is enabled.

CP15BEN is optional, but if it is implemented in the SCTLR then it must also be implemented in the SCTLR_EL1, SCTLR_EL2, and HSCTLR.

The reset behavior of this field is:

When an implementation does not implement CP15BEN, access to this field is RAO/WI.

LSMAOE, bit [4]

When FEAT_LSMAOC is implemented:

Load Multiple and Store Multiple Atomicity and Ordering Enable.

LSMAOEMeaning
0b0

For all memory accesses at EL1 or 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 EL1 or EL0 is as defined for Armv8.0.

This bit is permitted to be cached in a TLB.

The reset behavior of this field is:



Otherwise:

Reserved, RES1.

nTLSMD, bit [3]

When FEAT_LSMAOC is implemented:

No Trap Load Multiple and Store Multiple to Device-nGRE/Device-nGnRE/Device-nGnRnE memory.

nTLSMDMeaning
0b0

All memory accesses by A32 and T32 Load Multiple and Store Multiple at EL1 or 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 EL1 or 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.

The reset behavior of this field is:



Otherwise:

Reserved, RES1.

C, bit [2]

Cacheability control, for data accesses at EL1 and EL0:

CMeaning
0b0

All data access to Normal memory from PL1 and PL0, and all accesses to the PL1&0 stage 1 translation tables, are Non-cacheable for all levels of data and unified cache.

0b1

All data access to Normal memory from PL1 and PL0, and all accesses to the PL1&0 stage 1 translation tables, can be cached at all levels of data and unified cache.

The PE ignores SCTLR.C, and data accesses to Normal memory from EL1 and EL0 are Cacheable, if either:

The reset behavior of this field is:

A, bit [1]

Alignment check enable. This is the enable bit for Alignment fault checking at PL1 and PL0:

AMeaning
0b0

Alignment fault checking disabled when executing at PL1 or PL0.

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 PL1 or PL0.

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.

The reset behavior of this field is:

M, bit [0]

MMU enable for EL1 and EL0 stage 1 address translation. Possible values of this bit are:

MMeaning
0b0

EL1 and EL0 stage 1 address translation disabled.

See the SCTLR.I field for the behavior of instruction accesses to Normal memory.

0b1

EL1 and EL0 stage 1 address translation enabled.

The PE behaves as if the value of the SCTLR.M field is 0 for all purposes other than returning the value of a direct read of the field if either:

The reset behavior of this field is:

Accessing SCTLR

Accesses to this register use the following encodings in the System register encoding space:

MRC{<c>}{<q>} <coproc>, {#}<opc1>, <Rt>, <CRn>, <CRm>{, {#}<opc2>}

coprocopc1CRnCRmopc2
0b11110b0000b00010b00000b000

if PSTATE.EL == EL0 then UNDEFINED; elsif PSTATE.EL == EL1 then if EL2Enabled() && !ELUsingAArch32(EL2) && HSTR_EL2.T1 == '1' then AArch64.AArch32SystemAccessTrap(EL2, 0x03); elsif EL2Enabled() && ELUsingAArch32(EL2) && HSTR.T1 == '1' then AArch32.TakeHypTrapException(0x03); elsif EL2Enabled() && !ELUsingAArch32(EL2) && HCR_EL2.TRVM == '1' then AArch64.AArch32SystemAccessTrap(EL2, 0x03); elsif EL2Enabled() && ELUsingAArch32(EL2) && HCR.TRVM == '1' then AArch32.TakeHypTrapException(0x03); elsif HaveEL(EL3) && ELUsingAArch32(EL3) then R[t] = SCTLR_NS; else R[t] = SCTLR; elsif PSTATE.EL == EL2 then if HaveEL(EL3) && ELUsingAArch32(EL3) then R[t] = SCTLR_NS; else R[t] = SCTLR; elsif PSTATE.EL == EL3 then if SCR.NS == '0' then R[t] = SCTLR_S; else R[t] = SCTLR_NS;

MCR{<c>}{<q>} <coproc>, {#}<opc1>, <Rt>, <CRn>, <CRm>{, {#}<opc2>}

coprocopc1CRnCRmopc2
0b11110b0000b00010b00000b000

if PSTATE.EL == EL0 then UNDEFINED; elsif PSTATE.EL == EL1 then if EL2Enabled() && !ELUsingAArch32(EL2) && HSTR_EL2.T1 == '1' then AArch64.AArch32SystemAccessTrap(EL2, 0x03); elsif EL2Enabled() && ELUsingAArch32(EL2) && HSTR.T1 == '1' then AArch32.TakeHypTrapException(0x03); elsif EL2Enabled() && !ELUsingAArch32(EL2) && HCR_EL2.TVM == '1' then AArch64.AArch32SystemAccessTrap(EL2, 0x03); elsif EL2Enabled() && ELUsingAArch32(EL2) && HCR.TVM == '1' then AArch32.TakeHypTrapException(0x03); elsif HaveEL(EL3) && ELUsingAArch32(EL3) then SCTLR_NS = R[t]; else SCTLR = R[t]; elsif PSTATE.EL == EL2 then if HaveEL(EL3) && ELUsingAArch32(EL3) then SCTLR_NS = R[t]; else SCTLR = R[t]; elsif PSTATE.EL == EL3 then if SCR.NS == '0' && CP15SDISABLE == Signal_High then UNDEFINED; elsif SCR.NS == '0' && CP15SDISABLE2 == Signal_High then UNDEFINED; else if SCR.NS == '0' then SCTLR_S = R[t]; else SCTLR_NS = R[t];