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The DBGWCR<n> characteristics are:
Holds control information for a watchpoint. Forms watchpoint n together with value register DBGWVR<n>.
AArch32 System register DBGWCR<n> bits [31:0] are architecturally mapped to AArch64 System register DBGWCR<n>_EL1[31:0] .
AArch32 System register DBGWCR<n> bits [31:0] are architecturally mapped to External register DBGWCR<n>_EL1[31:0] .
This register is present only when AArch32 is supported at any Exception level. Otherwise, direct accesses to DBGWCR<n> are UNKNOWN.
If watchpoint n is not implemented then accesses to this register are UNDEFINED.
Some or all RW fields of this register have defined reset values.
These apply
only if the PE resets into an Exception level that is using AArch32.
Otherwise,
RW fields in this register reset to architecturally UNKNOWN values.
DBGWCR<n> is a 32-bit register.
The DBGWCR<n> bit assignments are:
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 |
RES0 | MASK | RES0 | WT | LBN | SSC | HMC | BAS | LSC | PAC | E |
When the E field is zero, all the other fields in the register are ignored.
Reserved, RES0.
Address mask. Only objects up to 2GB can be watched using a single mask.
MASK | Meaning |
---|---|
0b00000 | No mask. |
0b00001 | Reserved. |
0b00010 | Reserved. |
If programmed with a reserved value, a watchpoint must behave as if either:
Software must not rely on this property because the behavior of reserved values might change in a future revision of the architecture.
Other values mask the corresponding number of address bits, from 0b00011 masking 3 address bits (0x00000007 mask for address) to 0b11111 masking 31 address bits (0x7FFFFFFF mask for address).
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Reserved, RES0.
Watchpoint type. Possible values are:
WT | Meaning |
---|---|
0b0 | Unlinked data address match. |
0b1 | Linked data address match. |
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Linked breakpoint number. For Linked data address watchpoints, this specifies the index of the Context-matching breakpoint linked to.
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Security state control. Determines the Security states under which a Watchpoint debug event for watchpoint n is generated. This field must be interpreted along with the HMC and PAC fields.
For more information, see 'Execution conditions for which a breakpoint generates Breakpoint exceptions' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, and 'Reserved DBGBCR<n>.{SSC, HMC, PMC} values' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile.
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Higher mode control. Determines the debug perspective for deciding when a Watchpoint debug event for watchpoint n is generated. This field must be interpreted along with the SSC and PAC fields.
For more information on the operation of the SSC, HMC, and PAC fields, see 'Execution conditions for which a watchpoint generates Watchpoint exceptions' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, section G2 (AArch32 Self-hosted Debug).
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Byte address select. Each bit of this field selects whether a byte from within the word or double-word addressed by DBGWVR<n> is being watched.
BAS | Description |
---|---|
0bxxxxxxx1 | Match byte at DBGWVR<n> |
0bxxxxxx1x | Match byte at DBGWVR<n>+1 |
0bxxxxx1xx | Match byte at DBGWVR<n>+2 |
0bxxxx1xxx | Match byte at DBGWVR<n>+3 |
In cases where DBGWVR<n> addresses a double-word:
BAS | Description, if DBGWVR<n>[2] == 0 |
---|---|
0bxxx1xxxx | Match byte at DBGWVR<n>+4 |
0bxx1xxxxx | Match byte at DBGWVR<n>+5 |
0bx1xxxxxx | Match byte at DBGWVR<n>+6 |
0b1xxxxxxx | Match byte at DBGWVR<n>+7 |
If DBGWVR<n>[2] == 1, only BAS[3:0] are used and BAS[7:4] are ignored. Arm deprecates setting DBGWVR<n>[2] == 1.
The valid values for BAS are non-zero binary numbers all of whose set bits are contiguous. All other values are reserved and must not be used by software. See 'Reserved DBGWCR<n>.BAS values' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, section G2 (AArch32 Self-hosted Debug)
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Load/store control. This field enables watchpoint matching on the type of access being made. Possible values of this field are:
LSC | Meaning |
---|---|
0b01 | Match instructions that load from a watchpointed address. |
0b10 | Match instructions that store to a watchpointed address. |
0b11 | Match instructions that load from or store to a watchpointed address. |
All other values are reserved, but must behave as if the watchpoint is disabled. Software must not rely on this property as the behavior of reserved values might change in a future revision of the architecture.
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Privilege of access control. Determines the Exception level or levels at which a Watchpoint debug event for watchpoint n is generated. This field must be interpreted along with the SSC and HMC fields.
For more information on the operation of the SSC, HMC, and PAC fields, see 'Execution conditions for which a watchpoint generates Watchpoint exceptions' in the Arm® Architecture Reference Manual, Armv8, for Armv8-A architecture profile, section G2 (AArch32 Self-hosted Debug).
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Enable watchpoint n. Possible values are:
E | Meaning |
---|---|
0b0 | Watchpoint disabled. |
0b1 | Watchpoint enabled. |
The following resets apply:
On a Cold reset, this field resets to an architecturally UNKNOWN value.
On a Warm reset, the value of this field is unchanged.
Accesses to this register use the following encodings:
coproc | opc1 | CRn | CRm | opc2 |
---|---|---|---|---|
0b1110 | 0b000 | 0b0000 | n[3:0] | 0b111 |
if PSTATE.EL == EL0 then UNDEFINED; elsif PSTATE.EL == EL1 then if EL2Enabled() && !ELUsingAArch32(EL2) && MDCR_EL2.<TDE,TDA> != '00' then AArch64.AArch32SystemAccessTrap(EL2, 0x05); elsif EL2Enabled() && ELUsingAArch32(EL2) && HDCR.<TDE,TDA> != '00' then AArch32.TakeHypTrapException(0x05); elsif HaveEL(EL3) && !ELUsingAArch32(EL3) && MDCR_EL3.TDA == '1' then AArch64.AArch32SystemAccessTrap(EL3, 0x05); elsif ELUsingAArch32(EL1) && DBGOSLSR.OSLK == '0' && HaltingAllowed() && EDSCR.TDA == '1' then Halt(DebugHalt_SoftwareAccess); else return DBGWCR[UInt(CRm<3:0>)]; elsif PSTATE.EL == EL2 then if HaveEL(EL3) && !ELUsingAArch32(EL3) && MDCR_EL3.TDA == '1' then AArch64.AArch32SystemAccessTrap(EL3, 0x05); elsif ELUsingAArch32(EL1) && DBGOSLSR.OSLK == '0' && HaltingAllowed() && EDSCR.TDA == '1' then Halt(DebugHalt_SoftwareAccess); else return DBGWCR[UInt(CRm<3:0>)]; elsif PSTATE.EL == EL3 then if ELUsingAArch32(EL1) && DBGOSLSR.OSLK == '0' && HaltingAllowed() && EDSCR.TDA == '1' then Halt(DebugHalt_SoftwareAccess); else return DBGWCR[UInt(CRm<3:0>)];
coproc | opc1 | CRn | CRm | opc2 |
---|---|---|---|---|
0b1110 | 0b000 | 0b0000 | n[3:0] | 0b111 |
if PSTATE.EL == EL0 then UNDEFINED; elsif PSTATE.EL == EL1 then if EL2Enabled() && !ELUsingAArch32(EL2) && MDCR_EL2.<TDE,TDA> != '00' then AArch64.AArch32SystemAccessTrap(EL2, 0x05); elsif EL2Enabled() && ELUsingAArch32(EL2) && HDCR.<TDE,TDA> != '00' then AArch32.TakeHypTrapException(0x05); elsif HaveEL(EL3) && !ELUsingAArch32(EL3) && MDCR_EL3.TDA == '1' then AArch64.AArch32SystemAccessTrap(EL3, 0x05); elsif ELUsingAArch32(EL1) && DBGOSLSR.OSLK == '0' && HaltingAllowed() && EDSCR.TDA == '1' then Halt(DebugHalt_SoftwareAccess); else DBGWCR[UInt(CRm<3:0>)] = R[t]; elsif PSTATE.EL == EL2 then if HaveEL(EL3) && !ELUsingAArch32(EL3) && MDCR_EL3.TDA == '1' then AArch64.AArch32SystemAccessTrap(EL3, 0x05); elsif ELUsingAArch32(EL1) && DBGOSLSR.OSLK == '0' && HaltingAllowed() && EDSCR.TDA == '1' then Halt(DebugHalt_SoftwareAccess); else DBGWCR[UInt(CRm<3:0>)] = R[t]; elsif PSTATE.EL == EL3 then if ELUsingAArch32(EL1) && DBGOSLSR.OSLK == '0' && HaltingAllowed() && EDSCR.TDA == '1' then Halt(DebugHalt_SoftwareAccess); else DBGWCR[UInt(CRm<3:0>)] = R[t];
1327/1209/2019 1518:1348; 391b5248b29fb2f001ef74792eaacbd6fc72f2116134483bd14dc8c12a99c984cbfe3431cc1c9707
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