FPSR, Floating-point Status Register

The FPSR characteristics are:

Purpose

Provides floating-point system status information.

Configuration

AArch64 System register FPSR bits [31:27] are architecturally mapped to AArch32 System register FPSCR[31:27].

AArch64 System register FPSR bit [7] is architecturally mapped to AArch32 System register FPSCR[7].

AArch64 System register FPSR bits [4:0] are architecturally mapped to AArch32 System register FPSCR[4:0].

Attributes

FPSR is a 64-bit register.

Field descriptions

6362616059585756555453525150494847464544434241403938373635343332
313029282726252423222120191817161514131211109876543210
RES0
NZCVQCRES0IDCRES0IXCUFCOFCDZCIOC

Bits [63:32]

Reserved, RES0.

N, bit [31]
When AArch32 is supported and AArch32 floating-point is implemented:

Negative condition flag for AArch32 floating-point comparison operations.

Note

AArch64 floating-point comparisons set the PSTATE.N flag instead.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

Z, bit [30]
When AArch32 is supported and AArch32 floating-point is implemented:

Zero condition flag for AArch32 floating-point comparison operations.

Note

AArch64 floating-point comparisons set the PSTATE.Z flag instead.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

C, bit [29]
When AArch32 is supported and AArch32 floating-point is implemented:

Carry condition flag for AArch32 floating-point comparison operations.

Note

AArch64 floating-point comparisons set the PSTATE.C flag instead.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

V, bit [28]
When AArch32 is supported and AArch32 floating-point is implemented:

Overflow condition flag for AArch32 floating-point comparison operations.

Note

AArch64 floating-point comparisons set the PSTATE.V flag instead.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

QC, bit [27]

Cumulative saturation bit, Advanced SIMD only. This bit is set to 1 to indicate that an Advanced SIMD integer operation has saturated since 0 was last written to this bit.

The reset behavior of this field is:

Bits [26:8]

Reserved, RES0.

IDC, bit [7]

Input Denormal cumulative floating-point exception bit. This bit is set to 1 to indicate that the Input Denormal floating-point exception has occurred since 0 was last written to this bit.

How scalar and Advanced SIMD floating-point instructions update this bit depends on the value of the FPCR.IDE bit. This bit is set to 1 to indicate a floating-point exception only if FPCR.IDE is 0.

The reset behavior of this field is:

Bits [6:5]

Reserved, RES0.

IXC, bit [4]

Inexact cumulative floating-point exception bit. This bit is set to 1 to indicate that the Inexact floating-point exception has occurred since 0 was last written to this bit.

How scalar and Advanced SIMD floating-point instructions update this bit depends on the value of the FPCR.IXE bit. This bit is set to 1 to indicate a floating-point exception only if FPCR.IXE is 0.

The criteria for the Inexact floating-point exception to occur are affected by whether denormalized numbers are flushed to zero and by the value of the FPCR.AH bit. For more information, see 'Floating-point exceptions and exception traps'.

The reset behavior of this field is:

UFC, bit [3]

Underflow cumulative floating-point exception bit. This bit is set to 1 to indicate that the Underflow floating-point exception has occurred since 0 was last written to this bit.

How scalar and Advanced SIMD floating-point instructions update this bit depends on the value of the FPCR.UFE bit. This bit is set to 1 to indicate a floating-point exception only if FPCR.UFE is 0 or if flushing denormalized numbers to zero is enabled.

The criteria for the Underflow floating-point exception to occur are affected by whether denormalized numbers are flushed to zero and by the value of the FPCR.AH bit. For more information, see 'Floating-point exceptions and exception traps'.

The reset behavior of this field is:

OFC, bit [2]

Overflow cumulative floating-point exception bit. This bit is set to 1 to indicate that the Overflow floating-point exception has occurred since 0 was last written to this bit.

How scalar and Advanced SIMD floating-point instructions update this bit depends on the value of the FPCR.OFE bit. This bit is set to 1 to indicate a floating-point exception only if FPCR.OFE is 0.

The reset behavior of this field is:

DZC, bit [1]

Divide by Zero cumulative floating-point exception bit. This bit is set to 1 to indicate that the Divide by Zero floating-point exception has occurred since 0 was last written to this bit.

How scalar and Advanced SIMD floating-point instructions update this bit depends on the value of the FPCR.DZE bit. This bit is set to 1 to indicate a floating-point exception only if FPCR.DZE is 0.

The reset behavior of this field is:

IOC, bit [0]

Invalid Operation cumulative floating-point exception bit. This bit is set to 1 to indicate that the Invalid Operation floating-point exception has occurred since 0 was last written to this bit.

How scalar and Advanced SIMD floating-point instructions update this bit depends on the value of the FPCR.IOE bit. This bit is set to 1 to indicate a floating-point exception only if FPCR.IOE is 0.

The criteria for the Invalid Operation floating-point exception to occur are affected by the value of the FPCR.AH bit. For more information, see 'Floating-point exceptions and exception traps'.

The reset behavior of this field is:

Accessing FPSR

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

MRS <Xt>, FPSR

op0op1CRnCRmop2
0b110b0110b01000b01000b001

if PSTATE.EL == EL0 then if HaveEL(EL3) && EL3SDDUndefPriority() && CPTR_EL3.TFP == '1' then UNDEFINED; elsif !ELIsInHost(EL0) && CPACR_EL1.FPEN != '11' then if EL2Enabled() && HCR_EL2.TGE == '1' then AArch64.SystemAccessTrap(EL2, 0x00); else AArch64.SystemAccessTrap(EL1, 0x07); elsif ELIsInHost(EL0) && CPTR_EL2.FPEN != '11' then AArch64.SystemAccessTrap(EL2, 0x07); elsif ELIsInHost(EL2) && CPTR_EL2.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL2, 0x07); elsif EL2Enabled() && !ELIsInHost(EL2) && CPTR_EL2.TFP == '1' then AArch64.SystemAccessTrap(EL2, 0x07); elsif HaveEL(EL3) && CPTR_EL3.TFP == '1' then if EL3SDDUndef() then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x07); else X[t, 64] = FPSR; elsif PSTATE.EL == EL1 then if HaveEL(EL3) && EL3SDDUndefPriority() && CPTR_EL3.TFP == '1' then UNDEFINED; elsif CPACR_EL1.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL1, 0x07); elsif EL2Enabled() && !ELIsInHost(EL2) && CPTR_EL2.TFP == '1' then AArch64.SystemAccessTrap(EL2, 0x07); elsif ELIsInHost(EL2) && CPTR_EL2.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL2, 0x07); elsif HaveEL(EL3) && CPTR_EL3.TFP == '1' then if EL3SDDUndef() then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x07); else X[t, 64] = FPSR; elsif PSTATE.EL == EL2 then if HaveEL(EL3) && EL3SDDUndefPriority() && CPTR_EL3.TFP == '1' then UNDEFINED; elsif !ELIsInHost(EL2) && CPTR_EL2.TFP == '1' then AArch64.SystemAccessTrap(EL2, 0x07); elsif ELIsInHost(EL2) && CPTR_EL2.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL2, 0x07); elsif HaveEL(EL3) && CPTR_EL3.TFP == '1' then if EL3SDDUndef() then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x07); else X[t, 64] = FPSR; elsif PSTATE.EL == EL3 then if CPTR_EL3.TFP == '1' then AArch64.SystemAccessTrap(EL3, 0x07); else X[t, 64] = FPSR;

MSR FPSR, <Xt>

op0op1CRnCRmop2
0b110b0110b01000b01000b001

if PSTATE.EL == EL0 then if HaveEL(EL3) && EL3SDDUndefPriority() && CPTR_EL3.TFP == '1' then UNDEFINED; elsif !ELIsInHost(EL0) && CPACR_EL1.FPEN != '11' then if EL2Enabled() && HCR_EL2.TGE == '1' then AArch64.SystemAccessTrap(EL2, 0x00); else AArch64.SystemAccessTrap(EL1, 0x07); elsif ELIsInHost(EL0) && CPTR_EL2.FPEN != '11' then AArch64.SystemAccessTrap(EL2, 0x07); elsif ELIsInHost(EL2) && CPTR_EL2.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL2, 0x07); elsif EL2Enabled() && !ELIsInHost(EL2) && CPTR_EL2.TFP == '1' then AArch64.SystemAccessTrap(EL2, 0x07); elsif HaveEL(EL3) && CPTR_EL3.TFP == '1' then if EL3SDDUndef() then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x07); else FPSR = X[t, 64]; elsif PSTATE.EL == EL1 then if HaveEL(EL3) && EL3SDDUndefPriority() && CPTR_EL3.TFP == '1' then UNDEFINED; elsif CPACR_EL1.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL1, 0x07); elsif EL2Enabled() && !ELIsInHost(EL2) && CPTR_EL2.TFP == '1' then AArch64.SystemAccessTrap(EL2, 0x07); elsif ELIsInHost(EL2) && CPTR_EL2.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL2, 0x07); elsif HaveEL(EL3) && CPTR_EL3.TFP == '1' then if EL3SDDUndef() then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x07); else FPSR = X[t, 64]; elsif PSTATE.EL == EL2 then if HaveEL(EL3) && EL3SDDUndefPriority() && CPTR_EL3.TFP == '1' then UNDEFINED; elsif !ELIsInHost(EL2) && CPTR_EL2.TFP == '1' then AArch64.SystemAccessTrap(EL2, 0x07); elsif ELIsInHost(EL2) && CPTR_EL2.FPEN IN {'x0'} then AArch64.SystemAccessTrap(EL2, 0x07); elsif HaveEL(EL3) && CPTR_EL3.TFP == '1' then if EL3SDDUndef() then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x07); else FPSR = X[t, 64]; elsif PSTATE.EL == EL3 then if CPTR_EL3.TFP == '1' then AArch64.SystemAccessTrap(EL3, 0x07); else FPSR = X[t, 64];


26/03/2024 09:49; 67c0ae5282a7629ba0ea0ba7267b43cd4f7939f6

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