Control and Status Registers
CSR Map
Table 14 lists all implemented CSRs. To columns in Table 14 may require additional explanation:
The Parameter column identifies those CSRs that are dependent on the value of specific compile/synthesis parameters. If these parameters are not set as indicated in Table 14 then the associated CSR is not implemented. If the parameter column is empty then the associated CSR is always implemented.
The Privilege column indicates the access mode of a CSR. The first letter indicates the lowest privilege level required to access the CSR. Attempts to access a CSR with a higher privilege level than the core is currently running in will throw an illegal instruction exception. This is largely a moot point for the CV32E40X as it only supports machine and debug modes. The remaining letters indicate the read and/or write behavior of the CSR when accessed by the indicated or higher privilge level:
RW: CSR is read-write. That is, CSR instructions (e.g. csrrw) may write any value and that value will be returned on a subsequent read (unless a side-effect causes the core to change the CSR value).
RO: CSR is read-only. Writes by CSR instructions raise an illegal instruction exception.
Writes of a non-supported value to WLRL bitfields of a RW CSR do not result in an illegal instruction exception. The exact bitfield access types, e.g. WLRL or WARL, can be found in the RISC-V privileged specification.
Reads or writes to a CSR that is not implemented will result in an illegal instruction exception.
CSR Address |
Name |
Privilege |
Parameter |
Description |
|---|---|---|---|---|
Machine CSRs |
||||
0x300 |
|
MRW |
Machine Status (lower 32 bits). |
|
0x301 |
|
MRW |
Machine ISA |
|
0x304 |
|
MRW |
Machine Interrupt Enable Register |
|
0x305 |
|
MRW |
Machine Trap-Handler Base Address |
|
0x307 |
|
MRW |
|
Machine Trap-Handler Vector Table Base Address |
0x310 |
|
MRW |
Machine Status (upper 32 bits). |
|
0x320 |
|
MRW |
(HPM) Machine Counter-Inhibit Register |
|
0x323 |
|
MRW |
(HPM) Machine Performance-Monitoring Event Selector 3 |
|
. . . . |
||||
0x33F |
|
MRW |
(HPM) Machine Performance-Monitoring Event Selector 31 |
|
0x340 |
|
MRW |
Machine Scratch |
|
0x341 |
|
MRW |
Machine Exception Program Counter |
|
0x342 |
|
MRW |
Machine Trap Cause |
|
0x343 |
|
MRW |
Machine Trap Value |
|
0x344 |
|
MRW |
Machine Interrupt Pending Register |
|
0x345 |
|
MRW |
|
Interrupt handler address and enable modifier |
0x347 |
|
MRW |
|
Interrupt-level threshold |
0x349 |
|
MRW |
|
Conditional scratch swap on level change |
0x7A0 |
|
MRW |
|
Trigger Select Register |
0x7A1 |
|
MRW |
|
Trigger Data Register 1 |
0x7A2 |
|
MRW |
|
Trigger Data Register 2 |
0x7A4 |
|
MRW |
|
Trigger Info |
0x7B0 |
|
DRW |
|
Debug Control and Status |
0x7B1 |
|
DRW |
|
Debug PC |
0x7B2 |
|
DRW |
|
Debug Scratch Register 0 |
0x7B3 |
|
DRW |
|
Debug Scratch Register 1 |
0xB00 |
|
MRW |
(HPM) Machine Cycle Counter |
|
0xB02 |
|
MRW |
(HPM) Machine Instructions-Retired Counter |
|
0xB03 |
|
MRW |
(HPM) Machine Performance-Monitoring Counter 3 |
|
. . . . |
||||
0xB1F |
|
MRW |
(HPM) Machine Performance-Monitoring Counter 31 |
|
0xB80 |
|
MRW |
(HPM) Upper 32 Machine Cycle Counter |
|
0xB82 |
|
MRW |
(HPM) Upper 32 Machine Instructions-Retired Counter |
|
0xB83 |
|
MRW |
(HPM) Upper 32 Machine Performance-Monitoring Counter 3 |
|
. . . . |
||||
0xB9F |
|
MRW |
(HPM) Upper 32 Machine Performance-Monitoring Counter 31 |
|
0xF11 |
|
MRO |
Machine Vendor ID |
|
0xF12 |
|
MRO |
Machine Architecture ID |
|
0xF13 |
|
MRO |
Machine Implementation ID |
|
0xF14 |
|
MRO |
Hardware Thread ID |
|
0xF15 |
|
MRO |
Machine Configuration Pointer |
|
0xFB1 |
|
MRO |
|
Current interrupt levels |
CSR Address |
Name |
Privilege |
Parameter |
Description |
|---|---|---|---|---|
Unprivileged and User-Level CSRs |
||||
0x017 |
|
URW |
Table jump base vector and control register |
|
CSR Address |
Name |
Privilege |
Parameter |
Description |
|---|---|---|---|---|
User CSRs |
||||
0xC00 |
|
URO |
Cycle Counter |
|
0xC01 |
|
URO |
Time |
|
0xC02 |
|
URO |
Instructions-Retired Counter |
|
0xC80 |
|
URO |
Upper 32 Cycle Counter |
|
0xC81 |
|
URO |
Upper 32 Time |
|
0xC82 |
|
URO |
Upper 32 Instructions-Retired Counter |
|
CSR Address |
Name |
Privilege |
Parameter |
Description |
|---|---|---|---|---|
User CSRs |
||||
0xC03 |
|
URO |
(HPM) Performance-Monitoring Counter 3 |
|
. . . . . |
||||
0xC1F |
|
URO |
(HPM) Performance-Monitoring Counter 31 |
|
0xC83 |
|
URO |
(HPM) Upper 32 Performance-Monitoring Counter 3 |
|
. . . . . |
||||
0xC9F |
|
URO |
(HPM) Upper 32 Performance-Monitoring Counter 31 |
|
CSR Descriptions
What follows is a detailed definition of each of the CSRs listed above. The R/W column defines the access mode behavior of each bit field when accessed by the privilege level specified in Table 14 (or a higher privilege level):
R: read fields are not affected by CSR write instructions. Such fields either return a fixed value, or a value determined by the operation of the core.
RW: read/write fields store the value written by CSR writes. Subsequent reads return either the previously written value or a value determined by the operation of the core.
WARL: write-any-read-legal fields store only legal values written by CSR writes. The WARL keyword can optionally be followed by a legal value (or comma separated list of legal values) enclosed in brackets. If the legal value(s) are not specified, then all possible values are considered valid. For example, a WARL (0x0) field supports only the value 0x0. Any value may be written, but all reads would return 0x0 regardless of the value being written to it. A WARL field may support more than one value. If an unsupported value is (attempted to be) written to a WARL field, the value marked with an asterix (the so-called resolution value) is written. If there is no such predefined resolution value, then the original (legal) value of the bitfield is preserved.
WPRI: Software should ignore values read from these fields, and preserve the values when writing.
Note
The R/W information does not impact whether CSR accesses result in illegal instruction exceptions or not.
Jump Vector Table (jvt)
CSR Address: 0x017
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:6 |
WARL |
BASE[31:6]: Table Jump Base Address, 64 byte aligned. |
5:0 |
WARL (0x0) |
MODE: Jump table mode |
Table jump base vector and control register
Note
Memory writes to the jvt based vector table require an instruction barrier (fence.i) to guarantee that they are visible to the instruction fetch (see Fence.i external handshake and [RISC-V-UNPRIV]).
Machine Status (mstatus)
CSR Address: 0x300
Reset Value: defined (based on X_EXT, X_ECS_XS)
Bit # |
R/W |
Description |
|---|---|---|
31 |
R |
SD: State Dirty. |
30:23 |
WPRI (0x0) |
Reserved. Hardwired to 0. |
22 |
WARL (0x0) |
TSR. Hardwired to 0. |
21 |
WARL (0x0) |
TW. Hardwired to 0. |
20 |
WARL (0x0) |
TVM. Hardwired to 0. |
19 |
R (0x0) |
MXR. Hardwired to 0. |
18 |
R (0x0) |
SUM. Hardwired to 0. |
17 |
R (0x0) |
MPRV. Hardwired to 0. |
16:15 |
R / R (0x0) |
XS: Other Extension Context Status. R with reset value defined by |
14:13 |
RW / WARL (0x0) |
FS: FPU Extension Context Status. RW if |
12:11 |
WARL (0x3) |
MPP: Machine Previous Priviledge mode. Hardwired to 0x3. |
10:9 |
RW / WPRI (0x0) |
VS: Vector Extension Context Status. RW if |
8 |
WARL (0x0) |
SPP. Hardwired to 0. |
7 |
RW |
MPIE. When an exception is encountered, MPIE will be set to MIE. When the |
6 |
WARL (0x0) |
UBE. Hardwired to 0. |
5 |
R (0x0) |
SPIE. Hardwired to 0. |
4 |
WPRI (0x0) |
Reserved. Hardwired to 0. |
3 |
RW |
MIE: If you want to enable interrupt handling in your exception handler, set the Interrupt Enable MIE to 1 inside your handler code. |
2 |
WPRI (0x0) |
Reserved. Hardwired to 0. |
1 |
R (0x0) |
SIE. Hardwired to 0. |
0 |
WPRI (0x0) |
Reserved. Hardwired to 0 |
Machine ISA (misa)
CSR Address: 0x301
Reset Value: defined (based on RV32, A_EXT, M_EXT, X_EXT, X_MISA)
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:30 |
WARL (0x1) |
MXL (Machine XLEN). |
29:26 |
WARL (0x0) |
(Reserved). |
25 |
WARL (0x0) |
Z (Reserved). |
24 |
WARL (0x0) |
Y (Reserved). |
23 |
WARL (0x1) |
X (Non-standard extensions present). |
22 |
WARL (0x0) |
W (Reserved). |
21 |
WARL |
V (Tentatively reserved for Vector extension). |
20 |
WARL (0x0) |
U (User mode implemented). |
19 |
WARL (0x0) |
T (Tentatively reserved for Transactional Memory extension). |
18 |
WARL (0x0) |
S (Supervisor mode implemented). |
17 |
WARL (0x0) |
R (Reserved). |
16 |
WARL (0x0) |
Q (Quad-precision floating-point extension). |
15 |
WARL |
P (Packed-SIMD extension). |
14 |
WARL (0x0) |
O (Reserved). |
13 |
WARL (0x0) |
N |
12 |
WARL |
M (Integer Multiply/Divide extension). |
11 |
WARL (0x0) |
L (Tentatively reserved for Decimal Floating-Point extension). |
10 |
WARL (0x0) |
K (Reserved). |
9 |
WARL (0x0) |
J (Tentatively reserved for Dynamically Translated Languages extension). |
8 |
WARL |
I (RV32I/64I/128I base ISA). |
7 |
WARL (0x0) |
H (Hypervisor extension). |
6 |
WARL (0x0) |
G (Additional standard extensions present). |
5 |
WARL |
F (Single-precision floating-point extension). |
4 |
WARL |
E (RV32E base ISA). |
3 |
WARL (0x0) |
D (Double-precision floating-point extension). |
2 |
WARL (0x1) |
C (Compressed extension). |
1 |
WARL (0x0) |
B Reserved. |
0 |
WARL |
A (Atomic extension). |
All bitfields in the misa CSR read as 0 except for the following:
A = 1 if
A_EXT== AC = 1
F = 1
X_EXT== 1 andX_MISA[5]== 1I = 1 if
RV32== RV32IE = 1 if
RV32== RV32EM = 1 if
M_EXT== M or (X_EXT== 1 andX_MISA[12]== 1)MXL = 1 (i.e. XLEN = 32)
P = 1
X_EXT== 1 andX_MISA[15]== 1V = 1
X_EXT== 1 andX_MISA[21]== 1X = 1
Note
Some of the WARL definitions in above table are depending on the X_EXT and X_MISA parameters. If X_EXT == 1, then X_MISA can be used
to force the P, V, F, M misa bits to 1. The value of X_MISA is effectively ORed into the misa CSR. Only the bits corresponding
to P, V, F, M are allowed to be set in X_MISA.
Note
None of the misa bits can be changed by writing the misa CSR.
Machine Interrupt Enable Register (mie) - CLIC == 0
CSR Address: 0x304
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:16 |
RW |
Machine Fast Interrupt Enables: Set bit x to enable interrupt irq_i[x]. |
15:12 |
WARL (0x0) |
Reserved. Hardwired to 0. |
11 |
RW |
MEIE: Machine External Interrupt Enable, if set, irq_i[11] is enabled. |
10 |
WARL (0x0) |
Reserved. Hardwired to 0. |
9 |
WARL (0x0) |
SEIE. Hardwired to 0 |
8 |
WARL (0x0) |
Reserved. Hardwired to 0. |
7 |
RW |
MTIE: Machine Timer Interrupt Enable, if set, irq_i[7] is enabled. |
6 |
WARL (0x0) |
Reserved. Hardwired to 0. |
5 |
WARL (0x0) |
STIE. Hardwired to 0. |
4 |
WARL (0x0) |
Reserved. Hardwired to 0. |
3 |
RW |
MSIE: Machine Software Interrupt Enable, if set, irq_i[3] is enabled. |
2 |
WARL (0x0) |
Reserved. Hardwired to 0. |
1 |
WARL (0x0) |
SSIE. Hardwired to 0. |
0 |
WARL (0x0) |
Reserved. Hardwired to 0. |
Machine Interrupt Enable Register (mie) - CLIC == 1
CSR Address: 0x304
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
WARL (0x0) |
Reserved. Hardwired to 0. |
Note
In CLIC mode the mie CSR is replaced by separate memory-mapped interrupt enables (clicintie).
Machine Trap-Vector Base Address (mtvec) - CLIC == 0
CSR Address: 0x305
Reset Value: Defined
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:7 |
WARL |
BASE[31:7]: Trap-handler base address, always aligned to 128 bytes. |
6:2 |
WARL (0x0) |
BASE[6:2]: Trap-handler base address, always aligned to 128 bytes. |
1:0 |
WARL (0x0, 0x1) |
MODE: Interrupt handling mode. 0x0 = non-vectored CLINT mode, 0x1 = vectored CLINT mode. |
Out of reset mtvec has the value of 32’h00000001. This value is not observable by SW as mtvec is initialized to {mtvec_addr_i[31:7], 5’b0, 2’b01} when fetch_enable_i is asserted the first time after reset release.
When an exception or an interrupt is encountered, the core jumps to the corresponding
handler using the content of the mtvec[31:7] as base address. Both non-vectored CLINT mode and vectored CLINT mode
are supported.
Upon an NMI in non-vectored CLINT mode the core jumps to mtvec[31:7], 5’h0, 2’b00} (i.e. index 0). Upon an NMI in vectored CLINT mode the core jumps to mtvec[31:7], 5’hF, 2’b00} (i.e. index 15).
Note
For NMIs the exception codes in the mcause CSR do not match the table index as for regular interrupts.
Note
Memory writes to the mtvec based vector table require an instruction barrier (fence.i) to guarantee that they are visible to the instruction fetch (see Fence.i external handshake and [RISC-V-UNPRIV]).
Machine Trap-Vector Base Address (mtvec) - CLIC == 1
CSR Address: 0x305
Reset Value: Defined
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:7 |
WARL |
BASE[31:7]: Trap-handler base address, always aligned to 128 bytes. |
6 |
WARL (0x0) |
BASE[6]: Trap-handler base address, always aligned to 128 bytes. |
5:2 |
WARL (0x0) |
SUBMODE: Sub mode. Reserved for future use. |
1:0 |
WARL (0x3) |
MODE: Interrupt handling mode. Always CLIC mode. |
Out of reset mtvec has the value of 32’h00000003. This value is not observable by SW as mtvec is initialized to {mtvec_addr_i[31:7], 1’b0, 6’b000011} when fetch_enable_i is asserted the first time after reset release.
Upon an NMI in CLIC mode the core jumps to mtvec[31:7], 5’h0, 2’b00} (i.e. index 0).
Note
Memory writes to the mtvec based vector table require an instruction barrier (fence.i) to guarantee that they are visible to the instruction fetch (see Fence.i external handshake and [RISC-V-UNPRIV]).
Machine Trap Vector Table Base Address (mtvt)
CSR Address: 0x307
Reset Value: 0x0000_0000
Include Condition: CLIC = 1
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:N |
RW |
BASE[31:N]: Trap-handler vector table base address. N = maximum(6, 2+CLIC_ID_WIDTH). See note below for alignment restrictions. |
N-1:6 |
WARL (0x0) |
BASE[N-1:6]: Trap-handler vector table base address.
This field is only defined if N > 6.
N = maximum(6, 2+CLIC_ID_WIDTH).
|
5:0 |
R (0x0) |
Reserved. Hardwired to 0. |
Note
The mtvt CSR holds the base address of the trap vector table, which has its alignment restricted to both at least 64-bytes and to
2^(2+CLIC_ID_WIDTH) bytes or greater power-of-two boundary. For example if CLIC_ID_WIDTH = 8, then 256 CLIC interrupts are supported and the trap vector table
is aligned to 1024 bytes, and therefore BASE[9:6] will be WARL (0x0).
Note
Memory writes to the mtvt based vector table require an instruction barrier (fence.i) to guarantee that they are visible to the instruction fetch (see Fence.i external handshake and [RISC-V-UNPRIV]).
Machine Status (mstatush)
CSR Address: 0x310
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Definition |
|---|---|---|
31:6 |
WPRI (0x0) |
Reserved. Hardwired to 0. |
5 |
WARL (0x0) |
MBE. Hardwired to 0. |
4 |
WARL (0x0) |
SBE. Hardwired to 0. |
3:0 |
WPRI (0x0) |
Reserved. Hardwired to 0. |
Machine Counter-Inhibit Register (mcountinhibit)
CSR Address: 0x320
Reset Value: Defined
The performance counter inhibit control register. The default value is to inihibit all implemented counters out of reset. The bit returns a read value of 0 for non implemented counters.
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:3 |
WARL |
|
2 |
WARL |
IR: |
1 |
WARL (0x0) |
Hardwired to 0. |
0 |
WARL |
CY: |
Machine Performance Monitoring Event Selector (mhpmevent3 .. mhpmevent31)
CSR Address: 0x323 - 0x33F
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Definition |
|---|---|---|
31:16 |
WARL (0x0) |
Hardwired to 0. |
15:0 |
WARL |
SELECTORS. Each bit represents a unique event to count. |
The event selector fields are further described in Performance Counters section. Non implemented counters always return a read value of 0.
Machine Scratch (mscratch)
CSR Address: 0x340
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
RW |
Scratch value |
Machine Exception PC (mepc)
CSR Address: 0x341
Reset Value: 0x0000_0000
Bit # |
R/W |
Description |
|---|---|---|
31:1 |
WARL |
Machine Expection Program Counter 31:1 |
0 |
WARL (0x0) |
Hardwired to 0. |
When an exception is encountered, the current program counter is saved in MEPC, and the core jumps to the exception address. When a mret instruction is executed, the value from MEPC replaces the current program counter.
Machine Cause (mcause) - CLIC == 0
CSR Address: 0x342
Reset Value: 0x0000_0000
Bit # |
R/W |
Description |
|---|---|---|
31 |
RW |
INTERRUPT. This bit is set when the exception was triggered by an interrupt. |
30:11 |
WLRL (0x0) |
EXCCODE[30:11]. Hardwired to 0. |
10:0 |
WLRL |
EXCCODE[10:0]. See note below. |
Note
Software accesses to mcause[10:0] must be sensitive to the WLRL field specification of this CSR. For example, when mcause[31] is set, writing 0x1 to mcause[1] (Supervisor software interrupt) will result in UNDEFINED behavior.
Machine Cause (mcause) - CLIC == 1
CSR Address: 0x342
Reset Value: 0x3000_0000
Bit # |
R/W |
Description |
|---|---|---|
31 |
RW |
INTERRUPT. This bit is set when the exception was triggered by an interrupt. |
30 |
RW |
MINHV. Set by hardware at start of hardware vectoring, cleared by hardware at end of successful hardware vectoring. |
29:28 |
WARL (0x3) |
MPP: Previous privilege mode. Same as |
27 |
RW |
MPIE: Previous interrupt enable. Same as |
26:24 |
RW |
Reserved. Hardwired to 0. |
23:16 |
RW |
MPIL: Previous interrupt level. |
15:12 |
WARL (0x0) |
Reserved. Hardwired to 0. |
11 |
WLRL (0x0) |
EXCCODE[11] |
10:0 |
WLRL |
EXCCODE[10:0] |
Note
mcause.MPP and mstatus.MPP mirror each other. mcause.MPIE and mstatus.MPIE mirror each other. Reading or writing the
fields MPP/MPIE in mcause is equivalent to reading or writing the homonymous field in mstatus.
Machine Trap Value (mtval)
CSR Address: 0x343
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
WARL (0x0) |
Hardwired to 0. |
Machine Interrupt Pending Register (mip) - CLIC == 0
CSR Address: 0x344
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:16 |
R |
Machine Fast Interrupt Enables: Interrupt irq_i[x] is pending. |
15:12 |
WARL (0x0) |
Reserved. Hardwired to 0. |
11 |
R |
MEIP: Machine External Interrupt Enable, if set, irq_i[11] is pending. |
10 |
WARL (0x0) |
Reserved. Hardwired to 0. |
9 |
WARL (0x0) |
SEIP. Hardwired to 0 |
8 |
WARL (0x0) |
Reserved. Hardwired to 0. |
7 |
R |
MTIP: Machine Timer Interrupt Enable, if set, irq_i[7] is pending. |
6 |
WARL (0x0) |
Reserved. Hardwired to 0. |
5 |
WARL (0x0) |
STIP. Hardwired to 0. |
4 |
WARL (0x0) |
Reserved. Hardwired to 0. |
3 |
R |
MSIP: Machine Software Interrupt Enable, if set, irq_i[3] is pending. |
2 |
WARL (0x0) |
Reserved. Hardwired to 0. |
1 |
WARL (0x0) |
SSIP. Hardwired to 0. |
0 |
WARL (0x0) |
Reserved. Hardwired to 0. |
Machine Interrupt Pending Register (mip) - CLIC == 1
CSR Address: 0x344
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
WARL (0x0) |
Reserved. Hardwired to 0. |
Note
In CLIC mode the mip CSR is replaced by separate memory-mapped interrupt enables (clicintip).
Machine Next Interrupt Handler Address and Interrupt Enable (mnxti)
CSR Address: 0x345
Reset Value: 0x0000_0000
Include Condition: CLIC = 1
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
RW |
MNXTI: Machine Next Interrupt Handler Address and Interrupt Enable. |
This register can be used by the software to service the next interrupt when it is in the same privilege mode, without incurring the full cost of an interrupt pipeline flush and context save/restore.
Note
The mnxti CSR is only designed to be used with the CSRR (CSRRS rd,csr,x0), CSRRSI, and CSRRCI instructions.
Accessing the mnxti CSR using any other CSR instruction form is reserved and CV32E40X will treat such instruction as illegal instructions.
In addition, use of mnxti with CSRRSI with non-zero uimm values for bits 0, 2, and 4 are reserved for future use and will also be treated as illegal instructions.
Machine Interrupt-Level Threshold (mintthresh)
CSR Address: 0x347
Reset Value: 0x0000_0000
Include Condition: CLIC = 1
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:8 |
R (0x0) |
Reserved. Hardwired to 0. |
7:0 |
WARL |
TH: Threshold |
This register holds the machine mode interrupt level threshold.
Machine Scratch Swap for Interrupt-Level Change (mscratchcswl)
CSR Address: 0x349
Reset Value: 0x0000_0000
Include Condition: CLIC = 1
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
RW |
MSCRATCHCSWL: Machine Scratch Swap for Interrupt-Level Change |
Scratch swap register for multiple interrupt levels.
Note
Only the read-modify-write (swap/CSRRW) operation is useful for mscratchcswl.
The behavior of the non-CSRRW variants (i.e. CSRRS/C, CSRRWI, CSRRS/CI) and CSRRW variants with rd = x0 or rs1 = x0 on mscratchcswl are implementation-defined.
CV32E40X will treat such instructions as illegal instructions.
Trigger Select Register (tselect)
CSR Address: 0x7A0
Reset Value: 0x0000_0000
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
WARL
(0x0 - ( |
CV32E40X implements 0 to |
Trigger Data 1 (tdata1)
CSR Address: 0x7A1
Reset Value: 0x2800_1000
Bit# |
R/W |
Description |
|---|---|---|
31:28 |
WARL (0x2, 0x5, 0x6, 0xF*) |
TYPE. 0x2 ( |
27 |
WARL (0x1) |
DMODE. Only debug mode can write |
26:0 |
WARL |
DATA. Trigger data depending on type |
Note
Writing 0x0 to tdata1 disables the trigger and changes the value of tdata1 to
0xF800_0000, which is the only supported value for a disabled trigger.
The WARL behavior of tdata1.DATA depends on the value of tdata1.TYPE as described in
Match Control Type 2 (mcontrol), Match Control Type 6 (mcontrol6), Exception Trigger (etrigger) and Trigger Data 1 (tdata1) - disabled view.
tdata1 will also be set to 0xF800_0000 if tdata1 is attempted to be written with type 0x5 (etrigger) while at the same time tdata2
contains a value that is illegal for exception triggers.
Match Control Type 2 (mcontrol)
CSR Address: 0x7A1 (mcontrol is accessible as tdata1 when tdata1.TYPE is 0x2)
Reset Value: Not applicable
Bit# |
R/W |
Description |
|---|---|---|
31:28 |
WARL (0x2) |
TYPE. 2 = Address match trigger (legacy). |
27 |
WARL (0x1) |
DMODE. Only debug mode can write |
26:21 |
WARL (0x0) |
MASKMAX. Hardwired to 0. |
20 |
WARL (0x0) |
HIT. Hardwired to 0. |
19 |
WARL (0x0) |
SELECT. Only address matching is supported. |
18 |
WARL (0x0) |
TIMING. Break before the instruction at the specified address. |
17:16 |
WARL (0x0) |
SIZELO. Match accesses of any size. |
15:12 |
WARL (0x1) |
ACTION. Enter debug mode on match. |
11 |
WARL (0x0) |
CHAIN. Hardwired to 0. |
10:7 |
WARL (0x0*, 0x2, 0x3) |
MATCH. 0: Address matches tdata2, 2: Address is greater than or equal to tdata2, 3: Address is less than tdata2. |
6 |
WARL |
M. Match in machine mode. |
5 |
WARL (0x0) |
Hardwired to 0. |
4 |
WARL (0x0) |
S. Hardwired to 0. |
3 |
WARL (0x0) |
U. Hardwired to 0. |
2 |
WARL |
EXECUTE. Enable matching on instruction address. |
1 |
WARL |
STORE. Enable matching on store address. |
0 |
WARL |
LOAD. Enable matching on load address. |
Exception Trigger (etrigger)
CSR Address: 0x7A1 (etrigger is accessible as tdata1 when tdata1.TYPE is 0x5)
Reset Value: Not applicable
Bit# |
R/W |
Description |
|---|---|---|
31:28 |
WARL (0x5) |
TYPE. 5 = Exception trigger. |
27 |
WARL (0x1) |
DMODE. Only debug mode can write |
26 |
WARL (0x0) |
HIT. Hardwired to 0. |
25:13 |
WARL (0x0) |
Hardwired to 0. |
12 |
WARL (0x0) |
VS. Hardwired to 0. |
11 |
WARL (0x0) |
VU. Hardwired to 0. |
10 |
WARL (0x0) |
Hardwired to 0. |
9 |
WARL |
M. Match in machine mode. |
8 |
WARL (0x0) |
Hardwired to 0. |
7 |
WARL (0x0) |
S. Hardwired to 0. |
6 |
WARL (0x0) |
U. Hardwired to 0. |
5:0 |
WARL (0x1) |
ACTION. Enter debug mode on match. |
Match Control Type 6 (mcontrol6)
CSR Address: 0x7A1 (mcontrol6 is accessible as tdata1 when tdata1.TYPE is 0x6)
Reset Value: Not applicable
Bit# |
R/W |
Description |
|---|---|---|
31:28 |
WARL (0x6) |
TYPE. 6 = Address match trigger. |
27 |
WARL (0x1) |
DMODE. Only debug mode can write |
26 |
WARL (0x0) |
UNCERTAIN. Hardwired to 0. |
25 |
HIT1. Forms 2-bit WARL (0x0, 0x1) bitfield with HIT0. |
|
24 |
WARL (0x0) |
VS. Hardwired to 0. |
23 |
WARL (0x0) |
VU. Hardwired to 0. |
22 |
HIT0. Forms 2-bit WARL (0x0, 0x1) bitfield with HIT1. |
|
21 |
WARL (0x0) |
SELECT. Only address matching is supported. |
20:19 |
WARL (0x0) |
Hardwired to 0. |
18:16 |
WARL (0x0) |
SIZE. Match accesses of any size. |
15:12 |
WARL (0x1) |
ACTION. Enter debug mode on match. |
11 |
WARL (0x0) |
CHAIN. Hardwired to 0. |
10:7 |
WARL (0x0*, 0x2, 0x3) |
MATCH. 0: Address matches tdata2, 2: Address is greater than or equal to tdata2, 3: Address is less than tdata2. |
6 |
WARL |
M. Match in machine mode. |
5 |
WARL (0x0) |
UNCERTAINEN. Hardwired to 0. |
4 |
WARL (0x0) |
S. Hardwired to 0. |
3 |
WARL (0x0) |
U. Hardwired to 0. |
2 |
WARL |
EXECUTE. Enable matching on instruction address. |
1 |
WARL |
STORE. Enable matching on store address. |
0 |
WARL |
LOAD. Enable matching on load address. |
Note
The hit1 (MSB) and hit0 (LSB) bitfields form a 2-bit bitfield together that has WARL (0x0, 0x1) behavior.
Trigger Data 1 (tdata1) - disabled view
CSR Address: 0x7A1 (tdata1 view when tdata1.TYPE is 0xF)
Reset Value: Not applicable
Bit# |
R/W |
Description |
|---|---|---|
31:28 |
WARL (0xF) |
TYPE. 0xF ( |
27 |
WARL (0x1) |
DMODE. Only debug mode can write |
26:0 |
WARL (0x0) |
DATA. |
Note
Writing 0x0 to tdata1 disables the trigger and changes the value of tdata1 to
0xF800_0000, which is the only supported value for a disabled trigger.
Trigger Data Register 2 (tdata2)
CSR Address: 0x7A2
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
WARL |
DATA |
Note
The WARL behavior of tdata2 depends on the values of tdata1.TYPE and tdata1.DMODE as described in
Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0x2, Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0x5, Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0x6 and Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0xF.
Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0x2
CSR Address: 0x7A2
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
WARL |
DATA |
Note
Accessible in Debug Mode or M-Mode, depending on tdata1.DMODE.
This register stores the instruction address, load address or store address to match against for a breakpoint trigger.
Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0x5
CSR Address: 0x7A2
Reset Value: 0x0000_0000
Note
Bits 4 and 6 for misaligned load and stores are WARL (0x0) when A_EXT == A_NONE. For any other value of A_EXT (A_ZALRSC or A) the bits are WARL.
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:25 |
WARL (0x0) |
DATA[31:25] |
24 |
WARL |
DATA[24]. Instruction bus fault. |
23:12 |
WARL (0x0) |
DATA[23:12] |
11 |
WARL |
DATA[11]. Environment call from M-Mode (ECALL). |
10:8 |
WARL (0x0) |
DATA[10:8] |
7 |
WARL |
DATA[7]. Store/AMO access fault. |
6 |
WARL |
DATA[6]. Store/AMO address misaligned (only for atomics). |
5 |
WARL |
DATA[5]. Load access fault. |
4 |
WARL |
DATA[4]. Load address misaligned (only for atomics). |
3 |
WARL |
DATA[3]. Breakpoint. |
2 |
WARL |
DATA[2]. Illegal instruction. |
1 |
WARL |
DATA[1]. Instruction access fault. |
0 |
WARL (0x0) |
DATA[0] |
Note
Accessible in Debug Mode or M-Mode, depending on tdata1.DMODE.
This register stores the currently selected exception codes for an exception trigger.
Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0x6
CSR Address: 0x7A2
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
WARL |
DATA |
Note
Accessible in Debug Mode or M-Mode, depending on tdata1.DMODE.
This register stores the instruction address, load address or store address to match against for a breakpoint trigger.
Trigger Data Register 2 (tdata2) - View when tdata1.TYPE is 0xF
CSR Address: 0x7A2
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
WARL |
DATA |
Note
Accessible in Debug Mode or M-Mode, depending on tdata1.DMODE.
Trigger Info (tinfo)
CSR Address: 0x7A4
Reset Value: 0x0100_8064
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:24 |
R (0x1) |
VERSION. Sdtrig version 1.0. |
23:16 |
WARL (0x0) |
Hardwired to 0. |
15:0 |
R (0x8064) |
INFO. Types 0x2, 0x5, 0x6 and 0xF are supported. |
The info field contains one bit for each possible type enumerated in tdata1. Bit N corresponds to type N. If the bit is set, then that type is supported by the currently selected trigger. If the currently selected trigger does not exist, this field contains 1.
Accessible in Debug Mode or M-Mode.
Debug Control and Status (dcsr)
CSR Address: 0x7B0
Reset Value: 0x4000_0413
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:28 |
R (0x4) |
XDEBUGVER. External debug support exists as described in [RISC-V-DEBUG]. |
27:18 |
WARL (0x0) |
Reserved |
17 |
WARL (0x0) |
EBREAKVS. Hardwired to 0 |
16 |
WARL (0x0) |
EBREAKVU. Hardwired to 0. |
15 |
RW |
EBREAKM. Set to enter debug mode on |
14 |
WARL (0x0) |
Hardwired to 0. |
13 |
WARL (0x0) |
EBREAKS. Hardwired to 0. |
12 |
WARL (0x0) |
EBREAKU. Hardwired to 0. |
11 |
WARL |
STEPIE. Set to enable interrupts during single stepping. |
10 |
WARL |
STOPCOUNT. |
9 |
WARL (0x0) |
STOPTIME. Hardwired to 0. |
8:6 |
R |
CAUSE. Return the cause of debug entry. |
5 |
WARL (0x0) |
V. Hardwired to 0. |
4 |
WARL (0x1) |
MPRVEN. Hardwired to 1. |
3 |
R |
NMIP. If set, an NMI is pending |
2 |
RW |
STEP. Set to enable single stepping. |
1:0 |
WARL (0x3) |
PRV. Returns the privilege mode before debug entry. |
Debug PC (dpc)
CSR Address: 0x7B1
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:1 |
RW |
DPC[31:1]. Debug PC 31:1 |
0 |
WARL (0x0) |
DPC[0]. Hardwired to 0. |
When the core enters in Debug Mode, DPC contains the virtual address of the next instruction to be executed.
Debug Scratch Register 0/1 (dscratch0/1)
CSR Address: 0x7B2/0x7B3
Reset Value: 0x0000_0000
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
RW |
DSCRATCH0/1 |
Machine Cycle Counter (mcycle)
CSR Address: 0xB00
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
RW |
The lower 32 bits of the 64 bit machine mode cycle counter. |
Machine Instructions-Retired Counter (minstret)
CSR Address: 0xB02
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
RW |
The lower 32 bits of the 64 bit machine mode instruction retired counter. |
Machine Performance Monitoring Counter (mhpmcounter3 .. mhpmcounter31)
CSR Address: 0xB03 - 0xB1F
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
RW |
Machine performance-monitoring counter |
The lower 32 bits of the 64 bit machine performance-monitoring counter(s).
The number of machine performance-monitoring counters is determined by the parameter NUM_MHPMCOUNTERS with a range from 0 to 29 (default value of 1). Non implemented counters always return a read value of 0.
Upper 32 Machine Cycle Counter (mcycleh)
CSR Address: 0xB80
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
RW |
The upper 32 bits of the 64 bit machine mode cycle counter. |
Upper 32 Machine Instructions-Retired Counter (minstreth)
CSR Address: 0xB82
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
RW |
The upper 32 bits of the 64 bit machine mode instruction retired counter. |
Upper 32 Machine Performance Monitoring Counter (mhpmcounter3h .. mhpmcounter31h)
CSR Address: 0xB83 - 0xB9F
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
RW |
Machine performance-monitoring counter |
The upper 32 bits of the 64 bit machine performance-monitoring counter(s).
The number of machine performance-monitoring counters is determined by the parameter NUM_MHPMCOUNTERS with a range from 0 to 29 (default value of 1). Non implemented counters always return a read value of 0.
Machine Vendor ID (mvendorid)
CSR Address: 0xF11
Reset Value: 0x0000_0602
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:7 |
R (0xC) |
Number of continuation codes in JEDEC manufacturer ID. |
6:0 |
R (0x2) |
Final byte of JEDEC manufacturer ID, discarding the parity bit. |
The mvendorid encodes the OpenHW JEDEC Manufacturer ID, which is 2 decimal (bank 13).
Machine Architecture ID (marchid)
CSR Address: 0xF12
Reset Value: 0x0000_0014
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
R (0x14) |
Machine Architecture ID of CV32E40X is 0x14 (decimal 20) |
Machine Implementation ID (mimpid)
CSR Address: 0xF13
Reset Value: Defined
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:20 |
R (0x0) |
Hardwired to 0. |
19:16 |
R (0x0) |
MAJOR. |
15:12 |
R (0x0) |
Hardwired to 0. |
11:8 |
R (0x0) |
MINOR. |
7:4 |
R (0x0) |
Hardwired to 0. |
3:0 |
R |
PATCH. mimpid_patch_i, see Core Integration |
The Machine Implementation ID uses a Major, Minor, Patch versioning scheme. The PATCH bitfield is defined and set by the integrator and shall be set to 0 when no patches are applied. It is made available as mimpid_patch_i on the boundary of CV32E40X such that it can easily be changed by a metal layer only change.
Hardware Thread ID (mhartid)
CSR Address: 0xF14
Reset Value: Defined
Bit # |
R/W |
Description |
|---|---|---|
31:0 |
R |
Machine Hardware Thread ID mhartid_i, see Core Integration |
Machine Configuration Pointer (mconfigptr)
CSR Address: 0xF15
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Definition |
|---|---|---|
31:0 |
R (0x0) |
Reserved |
Machine Interrupt Status (mintstatus)
CSR Address: 0xFB1
Reset Value: 0x0000_0000
Include Condition: CLIC = 1
Detailed:
Bit # |
R/W |
Description |
|---|---|---|
31:24 |
R |
MIL: Machine Interrupt Level |
23:16 |
R (0x0) |
Reserved. Hardwired to 0. |
15: 8 |
R (0x0) |
SIL: Supervisor Interrupt Level, hardwired to 0. |
7: 0 |
R (0x0) |
UIL: User Interrupt Level, hardwired to 0. |
This register holds the active interrupt level for each privilege mode. Only Machine Interrupt Level is supported.
Cycle Counter (cycle)
CSR Address: 0xC00
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the lower 32 bits of the 64 bit machine mode cycle counter.
Time (time)
CSR Address: 0xC01
Reset Value: defined (based on time_i)
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the lower 32 bits of the 64 bit time counter. A
read of the time CSR value returns the value present on the time_i[31:0] pins.
Instructions-Retired Counter (instret)
CSR Address: 0xC02
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the lower 32 bits of the 64 bit machine mode instruction retired counter.
Performance Monitoring Counter (hpmcounter3 .. hpmcounter31)
CSR Address: 0xC03 - 0xC1F
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the lower 32 bits of the 64 bit machine mode performance counter. Non implemented counters always return a read value of 0.
Upper 32 Cycle Counter (cycleh)
CSR Address: 0xC80
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the upper 32 bits of the 64 bit machine mode cycle counter.
Upper 32 Time (timeh)
CSR Address: 0xC81
Reset Value: defined (based on time_i)
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the upper 32 bits of the 64 bit time counter. A
read of the time CSR value returns the value present on the time_i[63:32] pins.
Upper 32 Instructions-Retired Counter (instreth)
CSR Address: 0xC82
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the upper 32 bits of the 64 bit machine mode instruction retired counter.
Upper 32 Performance Monitoring Counter (hpmcounter3h .. hpmcounter31h)
CSR Address: 0xC83 - 0xC9F
Reset Value: 0x0000_0000
Detailed:
Bit# |
R/W |
Description |
|---|---|---|
31:0 |
R |
Read-only unprivileged shadow of the upper 32 bits of the 64 bit machine mode performance counter. Non implemented counters always return a read value of 0.