SCTLR_EL3, System Control Register (EL3)

Reserved, RES0.

SP Interrupt Mask enable. When SCTLR_EL3.NMI is 1, controls whether PSTATE.SP acts as an interrupt mask, and controls the value of PSTATE.ALLINT on taking an exception to EL3.

SPINTMASK	Meaning
0b0	Does not cause PSTATE.SP to mask interrupts. PSTATE.ALLINT is set to 1 on taking an exception to EL3.
0b1	When PSTATE.SP is 1 and execution is at EL3, an IRQ or FIQ interrupt that is targeted to EL3 is masked regardless of any denotion of Superpriority. PSTATE.ALLINT is set to 0 on taking an exception to EL3.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Non-maskable Interrupt enable.

NMI	Meaning
0b0	This control does not affect interrupt masking behavior.
0b1	This control enables all of the following: The use of the PSTATE.ALLINT interrupt mask. IRQ and FIQ interrupts to have Superpriority as an additional attribute. PSTATE.SP to be used as an interrupt mask.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to 0.

Reserved, RES0.

Reserved, RES0.

Tag Checking Store Only.

TCSO	Meaning
0b0	This field has no effect on Tag checking.
0b1	Load instructions executed in EL3 are Tag Unchecked.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Enables the Transactional Memory Extension at EL3.

TME	Meaning
0b0	Any attempt to execute a TSTART instruction at EL3 is trapped, unless HCR_EL2.TME or SCR_EL3.TME causes TSTART instructions to be UNDEFINED at EL3.
0b1	This control does not cause any TSTART instruction to be trapped.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Forces a trivial implementation of the Transactional Memory Extension at EL3.

TMT	Meaning
0b0	This control does not cause any TSTART instruction to fail.
0b1	When the TSTART instruction is executed at EL3, the transaction fails with a TRIVIAL failure cause.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Default PSTATE.SSBS value on Exception Entry.

DSSBS	Meaning
0b0	PSTATE.SSBS is set to 0 on an exception to EL3.
0b1	PSTATE.SSBS is set to 1 on an exception to EL3.

The reset behavior of this field is:

• On a Warm reset, this field resets to an IMPLEMENTATION DEFINED value.

Reserved, RES0.

Allocation Tag Access in EL3.

Controls access to Allocation Tags and Tag Check operations in EL3.

ATA	Meaning
0b0	Access to Allocation Tags is prevented at EL3. Memory accesses at EL3 are not subject to a Tag Check operation.
0b1	This control does not prevent access to Allocation Tags at EL3. Tag Checked memory accesses at EL3 are subject to a Tag Check operation. The Tag Check operation depends on the type of tag at the memory being accessed: For Allocation Tagged memory, an Allocation Tag Check operation. If FEAT_MTE_CANONICAL_TAGS is implemented, for Canonically Tagged memory, a Canonical Tag Check operation.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Tag Check Fault in EL3. Controls the effect of Tag Check Faults due to Loads and Stores in EL3.

TCF	Meaning	Applies when
0b00	Tag Check Faults have no effect on the PE.
0b01	Tag Check Faults cause a synchronous exception.
0b10	Tag Check Faults are asynchronously accumulated.
0b11	Tag Check Faults cause a synchronous exception on reads, and are asynchronously accumulated on writes.	When FEAT_MTE3 is implemented

If FEAT_MTE3 is not implemented, the value 0b11 is reserved.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

When synchronous exceptions are not being generated by Tag Check Faults, this field controls whether on exception entry into EL3, all Tag Check Faults due to instructions executed before exception entry, that are reported asynchronously, are synchronized into TFSRE0_EL1 and TFSR_ELx registers.

ITFSB	Meaning
0b0	Tag Check Faults are not synchronized on entry to EL3.
0b1	Tag Check Faults are synchronized on entry to EL3.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

PAC Branch Type compatibility at EL3.

BT	Meaning
0b0	When the PE is executing at EL3, PACIASP and PACIBSP are compatible with PSTATE.BTYPE == 0b11.
0b1	When the PE is executing at EL3, PACIASP and PACIBSP are not compatible with PSTATE.BTYPE == 0b11.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Controls enabling of pointer authentication of instruction addresses, using the APIAKey_EL1 key, in the EL3 translation regime.

Possible values of this bit are:

EnIA	Meaning
0b0	Pointer authentication of instruction addresses, using the APIAKey_EL1 key, is not enabled.
0b1	Pointer authentication of instruction addresses, using the APIAKey_EL1 key, is enabled.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Controls enabling of pointer authentication of instruction addresses, using the APIBKey_EL1 key, in the EL3 translation regime.

Possible values of this bit are:

EnIB	Meaning
0b0	Pointer authentication of instruction addresses, using the APIBKey_EL1 key, is not enabled.
0b1	Pointer authentication of instruction addresses, using the APIBKey_EL1 key, is enabled.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES1.

Controls enabling of pointer authentication of instruction addresses, using the APDAKey_EL1 key, in the EL3 translation regime.

EnDA	Meaning
0b0	Pointer authentication of data addresses, using the APDAKey_EL1 key, is not enabled.
0b1	Pointer authentication of data addresses, using the APDAKey_EL1 key, is enabled.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Endianness of data accesses at EL3, and stage 1 translation table walks in the EL3 translation regime.

EE	Meaning
0b0	Explicit data accesses at EL3, and stage 1 translation table walks in the EL3 translation regime are little-endian.
0b1	Explicit data accesses at EL3, and stage 1 translation table walks in the EL3 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.

The reset behavior of this field is:

• On a Warm reset, this field resets to an IMPLEMENTATION DEFINED value.

Reserved, RES0.

Reserved, RES1.

Exception Entry is Context Synchronizing.

EIS	Meaning
0b0	The taking of an exception to EL3 is not a context synchronizing event.
0b1	The taking of an exception to EL3 is a context synchronizing event.

If SCTLR_EL3.EIS is set to 0b0:

• Indirect writes to ESR_EL3, FAR_EL3, SPSR_EL3, ELR_EL3 are synchronized on exception entry to EL3, so that a direct read of the register after exception entry sees the indirectly written value caused by the exception entry.
• Memory transactions, including instruction fetches, from an Exception level always use the translation resources associated with that translation regime.
• Exception Catch debug events are synchronous debug events.
• DCPS* and DRPS instructions are context synchronization events.

The following are not affected by the value of SCTLR_EL3.EIS:

• Changes to the PSTATE information on entry to EL3.
• Behavior of accessing the banked copies of the stack pointer using the SP register name for loads, stores and data processing instructions.
• Debug state exit.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES1.

Implicit Error Synchronization event enable.

IESB	Meaning
0b0	Disabled.
0b1	An implicit error synchronization event is added: At each exception taken to EL3. Before the operational pseudocode of each ERET instruction executed at EL3.

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 and, if implemented, SCR_EL3.NMEA. If the Effective value of the field is 1, then an implicit error synchronization event is added after each DCPSx instruction taken to EL3 and before each DRPS instruction executed at EL3, in addition to the other cases where it is added.

When FEAT_DoubleFault is implemented, the PE is in Non-debug state, and the Effective value of SCR_EL3.NMEA is 1, this field is ignored and its Effective value is 1.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES0.

Write permission implies XN (Execute-never). For the EL3 translation regime, this bit can force all memory regions that are writable to be treated as XN.

WXN	Meaning
0b0	This control has no effect on memory access permissions.
0b1	Any region that is writable in the EL3 translation regime is forced to XN for accesses from software executing at EL3.

This bit applies only when SCTLR_EL3.M bit is set.

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

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES1.

Reserved, RES0.

Reserved, RES1.

Reserved, RES0.

Controls enabling of pointer authentication of instruction addresses, using the APDBKey_EL1 key, in the EL3 translation regime.

EnDB	Meaning
0b0	Pointer authentication of data addresses, using the APDBKey_EL1 key, is not enabled.
0b1	Pointer authentication of data addresses, using the APDBKey_EL1 key, is enabled.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Instruction access Cacheability control, for accesses at EL3:

I	Meaning
0b0	All instruction access to Normal memory from EL3 are Non-cacheable for all levels of instruction and unified cache. If the value of SCTLR_EL3.M is 0, instruction accesses from stage 1 of the EL3 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 EL3. If the value of SCTLR_EL3.M is 0, instruction accesses from stage 1 of the EL3 translation regime are to Normal, Outer Shareable, Inner Write-Through, Outer Write-Through memory.

This bit has no effect on the EL1&0, EL2, or EL2&0 translation regimes.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to 0.

Exception Exit is Context Synchronizing.

EOS	Meaning
0b0	An exception return from EL3 is not a context synchronizing event
0b1	An exception return from EL3 is a context synchronizing event

If SCTLR_EL3.EOS is set to 0b0:

• Memory transactions, including instruction fetches, from an Exception level always use the translation resources associated with that translation regime.
• Exception Catch debug events are synchronous debug events.
• DCPS* and DRPS instructions are context synchronization events.

The following are not affected by the value of SCTLR_EL3.EOS:

• The indirect write of the PSTATE and PC values from SPSR_EL3 and ELR_EL3 on exception return is synchronized.
• If the PE enters Debug state before the first instruction after an Exception return from EL3 to Non-secure state, any pending Halting debug event completes execution.
• The GIC behavior that allocates interrupts to FIQ or IRQ changes simultaneously with leaving the EL3 Exception level.
• Behavior of accessing the banked copies of the stack pointer using the SP register name for loads, stores and data processing instructions.
• Exit from Debug state.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES1.

Reserved, RES0.

Non-aligned access. This bit controls generation of Alignment faults at EL3 under certain conditions. The following instructions generate an Alignment fault if all bytes being accessed are not within a single 16-byte quantity, aligned to 16 bytes for access:

• LDAPR, LDAPRH, LDAPUR, LDAPURH, LDAPURSH, LDAPURSW, LDAR, LDARH, LDLAR, LDLARH.

• STLLR, STLLRH, STLR, STLRH, STLUR, and STLURH

If FEAT_LRCPC3 is implemented, the following instructions generate an Alignment fault if all bytes being accessed for a single register are not within a single 16-byte quantity, aligned to 16 bytes for access:

• LDIAPP, STILP, the post index versions of LDAPR and the pre index versions of STLR.

• If Advanced SIMD and floating-point instructions are implemented, LDAPUR (SIMD&FP), LDAP1 (SIMD&FP), STLUR (SIMD&FP), and STL1 (SIMD&FP).

nAA	Meaning
0b0	Unaligned accesses by the specified instructions generate an Alignment fault.
0b1	Unaligned accesses by the specified instructions do not generate an Alignment fault.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Reserved, RES0.

Reserved, RES1.

SP Alignment check enable. When set to 1, if a load or store instruction executed at EL3 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'.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

Cacheability control, for data accesses.

C	Meaning
0b0	All data access to Normal memory from EL3, and all Normal memory accesses to the EL3 translation tables, are Non-cacheable for all levels of data and unified cache.
0b1	This control has no effect on the Cacheability of: Data access to Normal memory from EL3. Normal memory accesses to the EL3 translation tables.

This bit has no effect on the EL1&0, EL2, or EL2&0 translation regimes.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to 0.

Alignment check enable. This is the enable bit for Alignment fault checking at EL3.

A	Meaning
0b0	Alignment fault checking is disabled when executing at EL3. Alignment checks on some instructions are not disabled by this control. For more information, see 'Alignment of data accesses'.
0b1	Alignment fault checking is enabled when executing at EL3. 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.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to an architecturally UNKNOWN value.

MMU enable for EL3 stage 1 address translation. Possible values of this bit are:

M	Meaning
0b0	EL3 stage 1 address translation disabled. See the SCTLR_EL3.I field for the behavior of instruction accesses to Normal memory.
0b1	EL3 stage 1 address translation enabled.

The reset behavior of this field is:

• On a Warm reset, in a system where the PE resets into EL3, this field resets to 0.