Store-release ordered pair of registers
This instruction calculates an address from a base register value and an optional offset, and stores two 32-bit words or two 64-bit doublewords to the calculated address, from two registers. For information on single-copy atomicity and alignment requirements, see Requirements for single-copy atomicity and Alignment of data accesses. The instruction also has memory ordering semantics, as described in Load-Acquire, Load-AcquirePC, and Store-Release, with the additional requirement that:
For information about addressing modes, see Load/Store addressing modes.
| 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 |
| 1 | x | 0 | 1 | 1 | 0 | 0 | 1 | 0 | 0 | 0 | Rt2 | 0 | 0 | 0 | x | 1 | 0 | Rn | Rt | ||||||||||||
| size | L | opc2 | |||||||||||||||||||||||||||||
if !IsFeatureImplemented(FEAT_LRCPC3) then EndOfDecode(Decode_UNDEF); end; let ispair : boolean = TRUE; let wback : boolean = opc2[0] == '0';
STILP has the same CONSTRAINED UNPREDICTABLE behavior as STP. For information about this CONSTRAINED UNPREDICTABLE behavior, see Architectural Constraints on UNPREDICTABLE behaviors, and particularly STP and STILP.
| <Wt1> |
Is the 32-bit name of the first general-purpose register to be transferred, encoded in the "Rt" field. |
| <Wt2> |
Is the 32-bit name of the second general-purpose register to be transferred, encoded in the "Rt2" field. |
| <Xn|SP> |
Is the 64-bit name of the general-purpose base register or stack pointer, encoded in the "Rn" field. |
| <Xt1> |
Is the 64-bit name of the first general-purpose register to be transferred, encoded in the "Rt" field. |
| <Xt2> |
Is the 64-bit name of the second general-purpose register to be transferred, encoded in the "Rt2" field. |
let t : integer{} = UInt(Rt); let t2 : integer{} = UInt(Rt2); let n : integer{} = UInt(Rn); let scale : integer{} = 2 + UInt(size[0]); let datasize : integer{} = 8 << scale; let offset : integer = if opc2[0] == '0' then -1 * (2 << scale) else 0; let acqrel : boolean = FALSE; let tagchecked : boolean = wback || n != 31; var rt_unknown : boolean = FALSE; if wback && (t == n || t2 == n) && n != 31 then let c : Constraint = ConstrainUnpredictable(Unpredictable_WBOVERLAPST); assert c IN {Constraint_NONE, Constraint_UNKNOWN, Constraint_UNDEF, Constraint_NOP}; case c of when Constraint_NONE => rt_unknown = FALSE; // value stored is pre-writeback when Constraint_UNKNOWN => rt_unknown = TRUE; // value stored is UNKNOWN when Constraint_UNDEF => EndOfDecode(Decode_UNDEF); when Constraint_NOP => EndOfDecode(Decode_NOP); end; end;
var address : bits(64); var data1 : bits(datasize); var data2 : bits(datasize); let dbytes : integer{} = datasize DIV 8; var accdesc : AccessDescriptor = CreateAccDescAcqRel(MemOp_STORE, tagchecked, ispair, acqrel, t, t2); if n == 31 then CheckSPAlignment(); address = SP{64}(); else address = X{64}(n); end; address = AddressAdd(address, offset, accdesc); if rt_unknown && t == n then data1 = ARBITRARY : bits(datasize); else data1 = X{datasize}(t); end; if rt_unknown && t2 == n then data2 = ARBITRARY : bits(datasize); else data2 = X{datasize}(t2); end; var full_data : bits(2*datasize); if BigEndian(accdesc.acctype) then full_data = data1::data2; else full_data = data2::data1; end; accdesc.highestaddressfirst = offset < 0; Mem{2*datasize}(address, accdesc) = full_data; if wback then if n == 31 then SP{64}() = address; else X{64}(n) = address; end; end;
This instruction is a data-independent-time instruction as described in About PSTATE.DIT.
2026-03_rel 2026-03-26 20:48:11
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