The following two extensions are useful independent of CHERI:

The following extensions are added to the privleged specification

RV32Y/RV64Y is defined as the base extension which all CHERI RISC-V implementations must support. Zcherihybrid and Svucrg are optional extensions in addition to RV32Y/RV64Y.

We refer to software as purecap if it utilizes CHERI capabilities for all memory accesses — including loads, stores and instruction fetches — rather than integer addresses. Purecap software requires the CHERI RISC-V hart to support RV32Y/RV64Y. We refer to software as hybrid if it uses integer addresses or CHERI capabilities for memory accesses. Hybrid software requires the CHERI RISC-V hart to support RV32Y/RV64Y and Zcherihybrid.

See Appendix B for compatibility with other RISC-V extensions.

There are RISC-V extensions in development that may duplicate some aspects of CHERI functionality or directly conflict with CHERI and should only be available in Integer Pointer Mode on a CHERI-enabled hart. These include:

The lower XLEN bits of a capability encode the address of where the capability points. This is also referred to as the integer part of the capability. For registers that are extended but currently hold non-capability data, all other fields are typically zero.

The valid tag is an additional bit added to addressable memory and all CLEN-bit registers. It is stored separately and may be referred to as out of band or hidden, and is hardware managed. It indicates whether a CLEN-bit register or CLEN-aligned memory location contains a valid capability. If the valid tag is set, the capability is valid and can be dereferenced (contingent on checks such as permissions or bounds).

All registers or memory locations able to hold a capability are CLEN bits wide with an additional hidden valid tag bit. These are referred to as being CLEN-bit in this specification.

The valid tag cannot be directly set to one by software, it is not a conventionally accessible bit of state. If the valid tag is set then it shows that the capability has been derived correctly according to the principles listed above (provenance, integrity, monotonicity). If the rules are followed then the valid tag will propagate through the instructions that modify, load or store the capability.

Therefore, for capability manipulation in registers:

Capability load/store require the provenance check:

When an operation fails a check, either due to software error or malicious intent, then the operation raises an exception or sets the resulting valid tag to zero.

Using an invalid capability to dereference memory or authorize any operation raises an exception. All capabilities derived from invalid capabilities are themselves invalid, i.e., their valid tags are zero.

Every CLEN-bit register has a one-bit valid tag, indicating whether the capability in the register is valid to be dereferenced. This valid tag is cleared whenever an invalid capability operation is performed. Examples of such invalid operations include writing only the integer portion (the address field) of the register or attempting to increase bounds or permissions.

Valid tags are tracked through the memory subsystem: every aligned CLEN-bit wide region has a non-addressable one-bit valid tag, which the hardware manages atomically with the data. The valid tag is set to zero if any byte in the CLEN/8 aligned memory region is ever written using an operation other than a store of a capability operand which is permitted to set the valid tag to one (see C-permission), and that the stored capability data has its valid tag set.

Capabilities encode memory bounds, i.e., the lowest and highest byte in memory that it is permitted to access when dereferenced for data memory access, or for instruction execution.

Checking is on a byte-by-byte basis, so that it is possible for a memory access to be fully in-bounds, partially out-of-bounds or fully out-of-bounds.

It is not permitted to make any partially or fully out-of-bounds memory accesses.

Every capability has two memory address bounds: base representing the lowest accessible byte, and top representing one byte above the highest accessible byte.

Therefore a memory location A in the range base ≤ A < top is within bounds, and so valid to access.

A compressed format is used to encode the bounds with a scheme similar to floating-point using an exponent and a mantissa. Therefore small exponents can allow byte granularity on the bounds, but larger exponents give coarser granularity.

The bounds encoding format is defined in Section A.1.4.

Software can query the capability bounds:

On system initialization the Infinite capability is available which has bounds which cover all of memory, and maximum permissions set. All smaller capabilities are derived from this.

The ISA does not allow the bounds (and permissions) of a capability with its valid tag set to be increased (monotonicity).

Bounds can be programmed using the SCBNDS, SCBNDSI and SCBNDSR instructions, which set the current address to be the base bound and the length to be the operand (rs1 or imm) value. The granularity constraints means that not all requested combinations of top and base bounds can be encoded exactly.

The bounds are encoded relative to the address field, sharing some upper bits of the address. The number of shared bits depends on the exponent, see Section A.1.4.

Because CHERI concentrate encoding scheme shares the upper bits of the address with the bounds, the address of a capability cannot be arbitrary modified without risking changing the meaning of the bounds. This means that whenever a capability address is updated, the semantics of the SCADDR instruction are required to check that the decoding of the bounds hasn’t changed. If the interpretation of bounds has changed, then the valid tag is set to zero, so that the capability is invalid for use.

Due to the encoding of capability bounds, not all out-of-bounds pointers can be represented. The maximum range of address values that the pointer can take is defined by the representable region, which is checked on every update by SCADDR.

The bounds and representable region (or space) are illustrated in Figure 2. E, MW and R in the figure are all introduced in Section A.1.4.2 along with the bounds decoding.

This metadata field indicates the type of the capability. The type determines which operations the capability authorizes. The following capability types are defined in RV32Y/RV64Y:

When a sealed capability is used as a function pointer it is known as a sentry capability.

Sentries describe secure function entry points. They have a CT-field of 1.

They are used as the target of JALR (RV32Y/RV64Y), which must have a zero offset for the use of a sentry to be valid.

Sentry capabilities can establish a form of control-flow integrity between mutually distrusting code. JALR (RV32Y/RV64Y) with zero offset automatically unseals a sentry target capability and installs it in the program counter capability.

JALR (RV32Y/RV64Y) also seals the return register, so the callee can return to the caller but cannot access the memory pointed at by the return register, and cannot return elsewhere.

This metadata field encodes architecturally defined permissions of the capability. Permissions grant access subject to the valid tag being set, the capability being unsealed, and bounds checks passing. Any operation is also contingent on requirements imposed by other RISC-V architectural features, such as virtual memory, PMP and PMAs, even if the capability grants sufficient permissions. The permissions currently defined in RV32Y/RV64Y are listed below.

Permissions can only be removed using ACPERM on valid capabilities, they cannot be added.

The Capability Level (CL) field allows enforcing invariants on capability propagation. It affects data memory accesses.

For example, the Capability Level can be used to ensure that a callee can only write a copy of the passed-in argument capability to specific locations in memory (e.g., the callee’s stack frame but not the heap). It can also be used to avoid sharing of compartment-local data (such as pointers to a stack object) between compartments.

The Capability Level can hold two values:

Furthermore, the EL-permission can be used to restrict loading of global capabilities — causing the hardware to automatically set the level of loaded capabilities to local instead.

As with permissions, the Capability Level of a valid capability can only be decreased but never increased (without deriving from a capability with a higher level). But unlike architectural permissions, the Capability Level can be reduced even if the capability is sealed.

The metadata also contains an encoding-dependent number of software-defined permission (SDP) bits. They can be inspected by the kernel or application programs to enforce restrictions on API calls (e.g., permit/deny system calls, memory allocation, etc.). They can be cleared by ACPERM but are not interpreted by the CPU otherwise.

While these bits are not used by the hardware as architectural permissions, modification follows the same rules: SDP bits can only be cleared and never set on valid capabilities.

ARC note C registers will become Y registers

The XLEN-wide integer registers (e.g., sp, a0) are all extended to CLEN bits.

When referring to the extended registers, the x prefix is replaced with a c: i.e. the extended version of x1 becomes c1. The register can be referred to either way - as c1 accessing all CLEN bits or as x1 accessing only the address field (i.e., the lower XLEN bits). For the ABI register names the c prefix is added, e.g., csp to refer to all CLEN bits, and so the assembler can refer to either sp or csp.

The zero register is extended with zero metadata and a zero valid tag: this is called the NULL capability.

The pc is extended to be the Program Counter Capability. Extending the pc allows the range of branches, jumps and linear execution for currently executing code to be restricted. The pcc address field is the pc in the base RISC-V ISA so that the hardware automatically updates it as instructions are executed.

The hardware performs the following checks on pcc for each instruction executed in addition to the checks already required by the base RISC-V ISA. A failing check raises a CHERI exception.

On system initialization the pc bounds and permissions must be set such that the program can run successfully (e.g., by setting it to Infinite to ensure all instructions are in bounds).

The RV32Y/RV64Y ISA requires capabilities written to the pcc to follow these rules:

RV32Y and RV64Y add the CLEN-bit CSR shown in Table 6.

All CSRs that can hold addresses are extended to CLEN bits.

RV32Y/RV64Y has three classes of CSR:

When accessing CSRs these rules are followed:

The assembler pseudoinstruction to read a capability CSR csrr cd, csr, is encoded as csrrs cd, csr, c0.

In Table 7, when there is no read or write width shown, the CSR access is not made and there are no side-effects following standard Zicsr rules.

See CADD.

This instruction can propagate valid capabilities which fail integrity checks.

See SCBNDS.

Otherwise set rd to 0.

All load and store instructions behave as described in Load and Store Instructions with one fundamental difference:

All load and store instructions authorized by cs1 raise exceptions if any of these checks fail:

¹ All load/store encodings are reserved if cs1=c0 (since dereferencing NULL always faults). This principle is extended to all loads and stores authorized by cs1.

Load instructions, except for LC, always zero the valid tag and metadata of the result register.

Store instructions, except for SC, always write zero to the valid tag or tags associated with the memory locations that are written to.

Therefore, misaligned stores may clear up to two associated valid tag bits.

The changed interpretation of the base register also applies to all loads, stores and other memory operations defined in later chapters of this specification with a base operands of rs1 unless stated otherwise.

Under RV32Y/RV64Y all loads and stores are authorized by cs1.

These rules affect the following base ISA instructions listed in Table 15, and also apply to instructions added by other extensions, e.g.:

Also note that the RVC encodings C.FSD, C.FLD, C.FSDSP, C.FLDSP are remapped to load/store capability data instead.

These rules affect the following base ISA instructions listed in Table 15, and also apply to instructions added by other extensions, e.g.:

ARC review: we may need to push the AUIPC instruction into the same extension as the capability encoding, for CHERIoT

All RV32I/RV64I instructions are available in both CHERI execution modes.

The CHERI Execution Mode is determined by a bit in the metadata of the pcc called the M-bit. Zcherihybrid adds a new CHERI Execution Mode field (M) to the capability format. Although always present, it only takes effect in code capabilities, i.e., when the X-permission is set. The exact location of the M-bit in the capability format for XLEN=32 and XLEN=64 is described in Appendix A.

The M-bit of the pcc, may be overridden by the execution environment which may not grant permission to enter Capability Pointer Mode.

The M-bit of pcc can be updated by the instructions listed in Table 16:

The effective CHERI execution mode cannot be determined just by reading the M-bit from pcc since it also depends on the execution environment. The following code sequence demonstrate how a program can observe the current, effective CHERI execution mode. It will write 0 for Capability Pointer Mode and 1 for Integer Pointer Mode to x1:

ARC question: should misa.Y be 1 when in Capability Pointer Mode and 0 when in Integer Pointer Mode?

ddc is a read-write, user mode accessible capability CSR. It does not require ASR-permission in pcc for writes or reads. Similarly to pcc authorizing all control flow and instruction fetches, this capability register is implicitly checked to authorize all data memory accesses when the current CHERI mode is Integer Pointer Mode. On startup ddc bounds and permissions must be set such that the program can run successfully (e.g., by setting it to Infinite to ensure all data references are in bounds).

See MODESW.CAP.

When the CHERI execution mode is Capability Pointer Mode; the instruction behaves as described in Section 2.10. In Integer Pointer Mode, the capability authorizing the memory access is ddc, so the effective address is obtained by adding the x register to the sign-extended offset.

When the CHERI execution mode is Capability Pointer Mode; the instruction behaves as described in Section 2.10. In Integer Pointer Mode, the capability authorizing the memory access is ddc, so the effective address is obtained by adding the x register to the sign-extended offset.

See CSRRCI (RV32Y/RV64Y).

See CSRRCI (RV32Y/RV64Y).

See CSRRCI (RV32Y/RV64Y).

See CSRRCI (RV32Y/RV64Y).

The bit width of the permissions field depends on the value of MXLEN as shown in Table 20. A 5-bit vector encodes the permissions when MXLEN=32. For this case, the legal encodings of permissions are listed in Table 21. Certain combinations of permissions are impractical. For example, C-permission is superfluous when the capability does not grant either R-permission or W-permission. Therefore, it is only possible to encode a subset of all combinations.

For MXLEN=32, the permissions encoding is split into four quadrants. The quadrant is taken from bits [4:3] of the permissions encoding. The meaning for bits [2:0] are shown in Table 21 for each quadrant.

Quadrants 2 and 3 are arranged to implicitly grant future permissions which may be added with the existing allocated encodings. Quadrant 0 does the opposite - the encodings are allocated not to implicitly add future permissions, and so granting future permissions will require new encodings. Quadrant 1 encodes permissions for executable capabilities and the M-bit.

¹ Mode (M-bit) can only be set on a valid capability when Zcherihybrid is supported, otherwise such encodings are reserved. Despite being encoded here it is not an architectural permission.
² SL isn’t applicable in these cases, but this value is reported by GCPERM to simplify the rules followed by ACPERM
³ These entries are reserved for adding additional levels in a future extension

When MXLEN=64, there is a bit per permission as shown in Table 22. A permission is granted if its corresponding bit is set, otherwise the capability does not grant that permission.

The M-bit is only assigned meaning when the implementation supports Zcherihybrid and X-permission is set.

The width of the SDP-field depends on the underlying base architecture. The value of the SDP-field bits of the GCPERM result maps 1:1 to the SDP-field in the capability.

For RV32Y/RV64Y the CT field is one bit wide and maps 1:1 to the capability types listed in Table 2: it is a sentry capability if the bit is 1 or unsealed if it is 0.

The NULL capability is represented with 0 in all fields. This implies that it has no permissions and its exponent E is CAP_MAX_E (52 for MXLEN=64, 24 for MXLEN=32), so its bounds cover the entire address space such that the expanded base is 0 and top is 2^MXLEN.

The Infinite capability grants all permissions while its bounds also cover the whole address space. It includes X-permission and so includes the M-bit if Zcherihybrid is supported.

¹If Zcherihybrid is supported, then the Infinite capability must represent Integer Pointer Mode for compatibility with standard RISC-V code. Therefore:

²If an Infinite capability is used as a constant in either hardware or software, then the address field will typically be set to zero. If the address field is non-zero then it is still referred to as an Infinite capability, and it still has the authority to authorize all memory accesses.

The new address, after updating the address of a capability, is within the representable range if decompressing the capability’s bounds with the original and new addresses yields the same base and top bounds.

In other words, given a capability with address a and the new address a' = a + x, the bounds b and t are decoded using a and the new bounds b' and t' are decoded using a'. The new address is within the capability’s representable range if b == b' && t == t'.

Changing a capability’s address to a value outside the representable range unconditionally clears the capability’s tag. Examples are:

An artifact of the bounds encoding is that if an address is changed such that t != t', then it is also the case that b != b'. The inverse is also true, if b != b' then t != t'. Therefore, for representable range checking, it is acceptable to either check t == t' or b == b'.

In the bounds encoding in this specification, the top and bottom capability bounds are formed of two or three sections:

The representable range defines the range of addresses which do not corrupt the bounds encoding. The encoding was first introduced in Section A.1, and is repeated in a different form in Table 31 to aid this description.

For the address to be valid for the current bounds encoding, the value in the Upper Section of Table 31 must not change as this will change the meaning of the bounds. This is because T, B and E will be unchanged for the source and destination capabilities. Therefore, the Middle and Lower sections of the bounds calculation are also unchanged for source and destination capabilities.

When E > CAP_MAX_E - 2, the calculation of the top bound is entirely derived from T and E which will be identical for both the source and destination capabilities, thus guaranteeing that t == t'. Likewise, with such values of E, the base bound is entirely derived from B and E and therefore b == b'.

The calculation of the MSB of the top bound maybe inverted as specified Section A.1.4.3. Assuming (E < (CAP_MAX_E - 1)), the truth-table for this inversion is as follows:

Inspection of Table 32 shows that output_t[MXLEN] does not depend on input_t[MXLEN] as:

This leads to the conclusions:

Therefore, for the purposed of representable range checking, it is not required to check that t[MXLEN]==t'[XLEN].

Given that t[MXLEN] is not part of the representable range check:

Therefore, T and B are both derived from the capabilities metadata and are therefore constant. Which means that in this case too, the representable range check always passes.

As a result:

This gives a range of s=2E+MW, as shown in Figure 2.

The gap between the object bounds and the bound of the representable range is always guaranteed to be at least 1/4 of s. This is represented by R = B - 2MW-2 in Section A.1. This gives useful guarantees, such that if an executed instruction is in pcc bounds, then it is also guaranteed that the next linear instruction is representable.

The mtvecc register extends mtvec to hold a code capability. Its reset value is nominally the Infinite capability.

The fields in the metadata are WARL as many fields can be implemented as constants.

When traps are taken into machine mode, the pc is updated following the standard mtvec behavior. The valid tag and metadata from mtvecc are also written to the pcc.

Following the standard mtvec behavior, the value of mtvecc.address can be viewed with a range of different addresses:

HICAUSE is defined to be the largest interrupt cause value that the implementation can write to Xcause when an interrupt is taken.

Therefore the minimum observable address is mtvecc.address & ~3 and the maximum is (mtvecc.address & ~3) + 4 x HICAUSE.

All possible observable values must be in the Representable Range. Software must ensure this is true when writing to mtvecc, and the hardware sets the valid tag to zero if any values are out of the Representable Range.

mtvecc is always updated using SCADDR semantics and so writing a sealed capability will cause the valid tag to be set to zero.

mtvecc follows the rule from mtvec about not needing to be able to hold all possible invalid addresses (see Invalid address conversion).

The mscratchc register extends mscratch to hold a capability.

The reset value of the valid tag of this CSR is zero, the reset values of the metadata and address fields are UNSPECIFIED.

It is not WARL, all capability fields must be implemented.

The mepcc register extends mepc to hold a capability. Its reset value is nominally the Infinite capability.

mepcc.address is the mepc CSR, and so the follows the standard rules meaning that:

As listed above for mtvecc, this means that mepcc.address can represent multiple different values. Therefore software must ensure that all possible values are in the Representable Range on writing, otherwise the hardware sets the written valid tag to zero.

Sealed capabilities may be written to mepcc. The valid tag is set to zero on writing if:

In the following case the value of the valid tag observable in the CSR depends on the value of IALIGN:

The valid tag is zero then IALIGN=32 when reading the CSR, or executing MRET(RV32Y/RV64Y), and the valid tag is one when IALIGN=16.

When a trap is taken into M-mode, the pc is written to mepcc.address following the standard behavior. The valid tag and metadata of the pcc are also written to mepcc.

The capability in mepcc is unsealed when it is written to pcc on execution of an MRET(RV32Y/RV64Y) instruction.

mepcc follows the rule from mepc about not needing to be able to hold all possible invalid addresses (see Invalid address conversion).

The mtidc register is used to identify the current software thread in machine mode, using the method defined in the section for the unprivileged utidc CSR. On reset the valid tag of mtidc will be set to zero and the remainder of the data is UNSPECIFIED.

The mstatus and mstatush registers operate as described in Section 6.2.1 with two restrictions:

Changing XLEN or endianness would change the interpretation of all in-memory capabilities, so allowing these fields to change at runtime is prohibited.

Section 6.2.1.MXR has no effect on the CHERI permission checking.

RV32Y/RV64Y adds a new exception code for CHERI exceptions that mcause must be able to represent. The new exception code and its priority are listed in Machine cause (mcause) register values after trap and Synchronous exception priority in decreasing priority order respectively. The behavior and usage of mcause otherwise remains as described in mcause.

This table needs to be merged with the main table once we’ve resolve the Xcause type

¹ PCC bounds are checked against all bytes of fetched instructions. If the instructions cannot be decoded to determine the length, then the pcc bounds check is made against the minimum sized instruction supported by the implementation which can be executed, when prioritizing against Instruction Access Faults.

² The higher priority CHERI PTE page fault covers capability loads or atomics where the loaded valid tag is not checked, and all capability stores and atomics where the stored valid tag is set.

³ CHERI PTE page fault exceptions have the same priority against access faults as normal RISC-V page faults. If a normal RISC-V page fault and a CHERI PTE page fault are both detected simultaneously, then both are recorded as shown in Table 36.

⁴ The lower priority CHERI PTE page fault only covers capability loads and atomics where the loaded valid tag is checked.

Bit 28 of medeleg now refers to a valid exception and so can be used to delegate CHERI exceptions to supervisor mode.

The mtval register is an MXLEN-bit read-write register formatted as shown in Figure 17. When a data memory access causes a CHERI fault taken into M-mode, mtval is written with the MXLEN-bit effective address which caused the fault according to the existing rules for reporting load/store addresses. In this case the TYPE field of mtval2 shown in Table 34 is set to 1. For all other CHERI faults mtval is set to zero.

The behavior of mtval is otherwise as described in mtval.

If the hardware platform specifies that no exceptions set mtval to a non-zero value, then mtval is read-only zero for all CHERI exceptions.

The mtval2 register is required for CHERI machine mode.

When a CHERI fault, or CHERI PTE page fault, is taken into M-mode, mtval2 is written with additional CHERI-specific exception information with the format shown in Figure 18 to assist software in handling the trap.

If mtval is read-only zero for CHERI exceptions then mtval2 is also read-only zero for CHERI exceptions.

The TID bit in mstateen0 controls access to the stidc CSR.

The stvecc register extends stvec that is able to hold a capability. When the S-mode execution environment starts, the value is nominally the Infinite capability.

The handling of stvecc is otherwise identical to mtvecc, but in supervisor mode.

The sscratchc register extends sscratch to hold a capability.

At the start of the S-mode execution environment, the value of the valid tag of this CSR is zero and the values of the metadata and address fields are UNSPECIFIED.

It is not WARL, all capability fields must be implemented.

The sepcc register extends sepc to hold a capability. Its reset value is the Infinite capability.

As shown in Table 61, sepcc is a code capability, so it does not need to be able to hold all possible invalid addresses (see Invalid address conversion). Additionally, the capability in sepcc is unsealed when it is written to pcc on execution of an SRET (RV32Y/RV64Y) instruction. The handling of sepcc is otherwise identical to mepcc, but in supervisor mode.

The stval2 register is an SXLEN-bit read-write register, which is added as part of Sscheri when the implementation supports S-mode. Its CSR address is 0x14b.

stval2 is updated following the same rules as mtval2 for CHERI exceptions and CHERI PTE page faults which are delegated to HS-mode or S-mode. It is written to zero by the hardware for all other exceptions, except as listed otherwise by other future extensions.

The stidc register is used to identify the current software thread in supervisor mode, using the method defined in the section for the unprivileged utidc CSR. On reset the valid tag of stidc will be set to zero and the remainder of the data is UNSPECIFIED.

RV32Y/RV64Y adds a new exception code for CHERI exceptions that scause must be able to represent. The new exception code is listed in .Supervisor cause (scause) register values after trap. The behavior and usage of scause otherwise remains as described in scause.

See Section 6.2.2 for the new exceptions priorities when RV32Y/RV64Y is implemented.

stval is updated following the same rules as Section 6.2.4 for CHERI exceptions and CHERI PTE page faults which are delegated to HS-mode or S-mode.

The TID (thread ID) bit in sstateen0 controls access to the utidc CSR. See utidc for a description of the usage.