CHERI defines new state and behavior for the privileged modes:

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 capability tag is an additional bit added to addressable memory and all YLEN-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 YLEN-bit register or YLEN-aligned memory location contains a valid capability. If the capability 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 YLEN bits wide with an additional hidden capability tag bit. These are referred to as being YLEN-bit in this specification.

The capability tag cannot be directly set by software; it is not a conventionally accessible bit of state. If the capability 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 capability tag will propagate through the instructions that modify, load or store the capability.

Therefore, whenever an instruction writes a capability with the capability tag set to a register:

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 capability tag to zero.

For a capability to be valid, the capability tag must be set, otherwise a capability is invalid.

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 capability tags are zero.

Every YLEN-bit register has a one-bit capability tag, indicating whether the capability in the register is valid to be dereferenced. This capability tag is set to 0 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.

Capability tags are tracked through the memory subsystem: every aligned YLEN-bit wide region has a non-addressable one-bit capability tag, which the hardware manages atomically with the data. The capability tag is set to zero if any byte in the YLEN/8 aligned memory region is ever written using an operation other than a store of a capability operand. For example, the SY instruction may set the capability tag to one if all the instruction’s prerequisites are met, but SW will always set the capability tag to zero.

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. One bounds encoding format based upon (Woodruff et al., 2019) is defined in Section 2.10.1.6.

Software can query the bounds of a capability held in a general-purpose register using the following instructions:

On system initialization, one or more Root capabilities are available; typically, these have bounds which cover all of memory and the maximum permissions set. All smaller capabilities are derived from these.

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

The YBNDSW, YBNDSWI and YBNDSRW instructions generate new capabilities from a source capability and a length operand (rs2 or imm). The resulting capability has its address set as the base bound and its length as requested, subject to encoding granularity constraints. These instructions write the newly generated capability to the destination register. The granularity constraints mean 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 2.10.1.6.

Software sometimes uses out-of-bounds pointers, for example, to represent a one-past-the end pointer to an array in C (arr + size). To support this pattern, CHERI must allow these out-of-bounds pointers to be held in capabilities while still protecting the bounds and integrity. Because the CHERI Concentrate (Woodruff et al., 2019) encoding scheme for memory bounds shares the upper bits of the address with the bounds, only a limited range of out-of-bounds pointers can be represented for any given set of bounds. This range is known as the representable region. The relationship between the bounds and the representable region is illustrated in Figure 2.

E, MW and R in the figure are all introduced in Section 2.10.1.6.2 along with the bounds decoding.

The maximum range of address values that the pointer can take without changing the interpretation of bounds is defined by the representable region.

Since deriving a new capability with a different address could change the meaning of the bounds, all such derived capabilities (e.g., deriving the next pc capability from the existing pc via control-flow instructions or sequential execution) and instructions that return valid derived capabilities, must check that the new address is within the representable region defined by the source capability. If the interpretation of bounds has changed, then the capability tag of the derived capability is set to zero, so that it is invalid for use.

Software can derive a capability with a new address using instructions such as YADDRW, YADD and YADDI.

A hart supporting RVY has a single byte-addressable address space of 2^XLEN bytes for all memory accesses. Each memory region capable of holding a capability also stores a capability tag bit for each naturally aligned YLEN bits (e.g., 16 bytes in RV64), so that capabilities with their capability tag set can only be stored in naturally aligned addresses. Capability tags must be atomically bound to the data they protect.

The memory address space is circular, so the byte at address 2^XLEN - 1 is adjacent to the byte at address zero. A capability’s Representable Range described in Section 2.10.1 is also circular, so address 0 is within the Representable Range of a capability where address 2^XLEN - 1 is within the bounds. However, the decoded top address of a capability is XLEN + 1 bits wide and does not wrap, so a capability with base 2^XLEN - 1 and top 2^XLEN + 1 is not a subset of the infinite capability and does not authorize access to the byte at address 0. Like malformed bounds (see Section 2.10.1.6.4), it is impossible for a CHERI core to generate a valid capability with top > 2^XLEN. If such a capability exists then it must have been caused by a logic or memory fault. Unlike malformed bounds, the top overflowing is not treated as a special case in the architecture: normal bounds check rules should be followed.

This metadata value indicates the type of the capability and determines which operations the capability authorizes. Which capability types a given CHERI platform supports is a function of the extensions and capability encoding format in use. The capability encoding specifies a mapping between some bits within the capability format (usually described as "the CT field") and the capability types.

The capability encoding must be able to encode type 0 (unsealed). If any other sealed type exists, then they can be used to provide different levels of control-flow integrity.

Given a capability with CT=0, deriving a capability with CT≠0 is termed sealing (or sealing with type x when a particular output CT=x is meant).

In the other direction, deriving a CT=0 capability from a CT≠0 capability is termed unsealing (or unsealing from type x when a particular input CT=x is meant).

Sentries can establish a form of control-flow integrity between mutually distrusting code. Because they are immutable, the jump target cannot be modified, ensuring that control flow can only enter at the specific address encoded in the capability and not in the middle of a function.

Any sentry type may be passed as the rs1 argument to JALR (RVY), and are unsealed on dereference. The returned rd value is also sealed as a sentry.

Sentry types may be restricted to forward-edge only and backward-edge only transitions to further improve control-flow integrity.

The standard capability type mapping is shown in Table 6, extensions and capability encoding formats may add more types.

¹ Zysentry defines a sentry capability of this type.

This metadata field encodes architecturally defined permissions of the capability. Permissions grant access subject to the capability 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 defined in RVY are listed in Table 7. All capability formats must support at least this set of permissions. Extensions building on top of RVY may define additional permissions. An example of such an extension is Zylevels1. The in-memory format of these permissions depends on the capability encoding.

Permissions can be cleared when deriving a new capability value (using YPERMC) but they can never be added.

In the unprivileged RVY ISA, the following are affected by ASR-permission:

In the privileged RVY ISA, the following are affected by ASR-permission:

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 YPERMC 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.

The XLEN-wide integer registers (e.g., x1, x2) are all extended to YLEN bits and associated capability tags, as shown in Figure 3.

The zero register (x0) is extended with zero metadata and a zero capability tag: this is called the NULL capability.

The pc is extended to be a capability. Extending the pc allows the range of branches, jumps and linear execution for currently executing code to be restricted. The pc 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 pc 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 a Root Executable capability to ensure all instructions are in bounds).

RVY adds the YLEN-bit CSR shown in Table 9.

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

RVY has three classes of CSRs:

When accessing CSRs these rules are followed:

The assembler pseudoinstruction to read a capability CSR csrr rd, csr, is encoded as csrrs rd, csr, x0.

In Table 10, 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.

Creating a new capability with a different address (i.e., updating the pointer) requires specific instructions instead of integer ADD/ADDI. These instructions all include a check that the resulting address can be represented exactly within the new capability.

For security, capabilities can only be modified in restricted ways. Special instructions are provided to copy capabilities or derive a new capability using manipulations such as shrinking the bounds (YBNDSW), reducing the permissions (YPERMC) or authorizing a capability with another one which has a superset (or identical) bounds and permissions (YBLD).

¹ YHIW is a pseudoinstruction for PACKY

The bounds describing the range of addresses the capability gives access to are stored in a compressed format. These instructions query the bounds and related information.

These instructions either directly read bit fields from the metadata or capability tag, or only apply simple transformations on the metadata.

New loads and stores are introduced to handle capability data, LY and SY. They atomically access YLEN bits of data and the associated capability tag.

All capability memory accesses check for C-permission in the authorizing capability in rs1.

If C-permission is granted then:

If C-permission is not granted then:

All capability data memory access instructions require YLEN-aligned addresses, and will take an access fault exception if this requirement is not met. They cannot be emulated.

All memory accesses, of any type, require permission from the authorizing capability in rs1.

Under some circumstances LY will modify the data loaded from memory before writing it back to the destination register. See LY for details.

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

All load and store instructions authorized by rs1 raise exceptions if any of these checks fail:

¹ All load/store encodings are reserved if rs1=x0 (since dereferencing NULL always faults).

All load instructions, except for the RVY LY, always zero the capability tag and metadata of the result register.

All store instructions, except for the RVY SY, always write zero to the capability tag or capability tags associated with the memory locations that are written to. Therefore, misaligned stores may clear up to two associated capability tag bits.

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

These rules affect the following base ISA instructions listed in Table 19, and also apply to instructions added by other extensions, e.g.,:

These rules affect the following base ISA instructions listed in Table 19, and also apply to instructions added by other extensions, e.g.:

The RISC-V base integer ISA frequently splits signed 32-bit constants across instructions as the addition of a signed 12-bit constant and a 20-bit constant shifted left by 12 bits. For example, the I-type instruction ADDI, with its 12-bit immediate, is to be combined with the U-type LUI instruction and its 20-bit immediate when values beyond the reach of a signed 12-bit value are needed. To reach a given value in this way involve "overshooting" the desired value: for example, to materialize 0xf01 (3841) into a register, one uses LUI to materialize 0x1000 (4096) and ADDI to subtract 0xff (255). Similarly, the U-type AUIPC instruction, with its 20-bit immediate, is designed to compose well with the signed 12-bit immediate operands of load (I-type) and store (S-type) instructions.

When manipulating addresses within capabilities, there is a risk that such two-step sequences could take the address out of bounds before attempting to bring it back within bounds. Many capability encodings, including those of RV64LYmw14rc1ps, have a representable range sufficient to ensure that any capability whose length is larger than 2 KiB (that is, those for which a signed 12-bit displacement might be insufficient) are able to represent at least 2 KiB on either side of their bounds. However, this is not an essential property of capability encodings, and so this specification allows the capability encoding to specify the shift used within address-manipulating instructions with shifted immediates. For AUIPC (RVY) specifically, we refer to this value as the AUIPC shift, and take it to be 12 unless the capability encoding sets it to another value. (Taking the shift to be 11 instead of 12 decreases the reach of AUIPC from ±2 GiB to ±1 GiB, but ensures that all values within that range can be obtained with the same sign bit in the AUIPC immediate and subsequent 12-bit immediate(s), thereby ensuring that in-bounds addresses can be reached without risk of the intermediate computation exceeding capability bounds.)

For beq and bne only, if rs1≤rs2 then the encoding is RESERVED.

If the target of a taken branch lies outside the bounds of pc, the next instruction fetch will raise an exception.

The encoding diagram above of the capability format includes some fields which depend upon the presence of extensions:

This capability encoding has the following properties that affect the observable behavior of RVY instructions such as YBNDSW and YPERMC:

The concept of the representability check was introduced in Section 2.3.7.

The definition of the check is:

The address a' is within the source capability’s representable range if b == b' && t == t'.

If the address a' is outside the representable range, then the derived capability has the capability tag set to zero.

The current CHERI Pointer Mode is controlled by the P-bit in the capability metadata of pc. The P-bit (P) is only architecturally relevant for capabilities granting X-permission, as it only affects execution state when installed into pc.

Capabilities lacking X-permission may not have a defined P-bit field in their encoding, and attempting to update this field may be a no-op. Zyhybrid requires a capability encoding that supports transport of the P-bit (e.g., RV64LYmw14rc1ps).

When executing YPERMC, if X-permission is removed while the P-bit is set to one, and the capability encoding still permits representing the P-bit, then the P-bit must be set to zero.

The P-bit of pc can be updated by the instructions listed in Table 30:

The P-bit of a X-permission-granting capability can be read and written by the instructions listed in Table 31:

For capabilities that do not grant X-permission, P-bit must always be interpreted and reported as 0 representing Capability Pointer Mode.

The effective CHERI Pointer Mode cannot be determined just by reading the P-bit from pc since it also depends on the execution environment. The following code sequence demonstrates how a program can observe the current, effective CHERI Pointer Mode. It will write, to x1, the value 1 for Capability Pointer Mode (wherein pc has a set capability tag) or 0 for Integral Pointer Mode (wherein pc is just an address and has a clear capability tag):

See YMODESWY.

ddc is a read-write, user mode accessible capability CSR. It does not require ASR-permission in pc for writes or reads. Similarly to pc 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 Integral Pointer Mode. On startup ddc bounds and permissions must be set such that the program can run successfully (e.g., by setting it to have sufficiently broad bounds and permissions, possibly a Root Data capability).

See CSRRCI (RVY).

See CSRRCI (RVY).

See CSRRCI (RVY).

See CSRRCI (RVY).

The Capability Global (GL) flag is a metadata bit used to track and control the propagation of capabilities. It works in conjunction with the LG-permission and SL-permission permissions to enforce information flow boundaries.

The Capability Global flag holds one of two values:

Like permissions, the Capability Global flag can be cleared when creating a new capability from an existing one, but it can never be set unless derived from a superset capability which has the Capability Global flag set.

Store Local Permission (SL) controls whether local capabilities can be stored to memory. Storing a local capability (one without the GL(obal) Flag set) using an authorizing capability that lacks SL-permission results in the stored capability having its capability tag set to zero.

SL-permission is dependent on both C-permission and W-permission. If either of these permissions is clear, SL-permission is ignored and does not need to be encodable in the capability format.

Load Global Permission (LG) controls whether global capabilities can be loaded from memory. Loading a capability using an authorizing capability that lacks LG-permission clears the GL(obal) Flag bit of the loaded capability, making it local. If the loaded capability is unsealed, its LG-permission is also cleared.

This behavior is similar to how LM-permission affects loaded capabilities (but note the difference in interaction with seals).

LG-permission is dependent on both C-permission and R-permission. If either of these permissions is clear, LG-permission is ignored and does not need to be encodable in the capability format.

YPERMC can produce a new capability with its GL(obal) Flag cleared, even if the source capability is sealed. This differs from architectural and software permissions. This applies to both the implicit clearing of permissions during memory loads and explicit YPERMC instructions.

As mentioned, the SL-permission and LG-permission permissions are dependent on base permissions. YPERMC operations (including implicit ones) and/or the capability encoding clear these permissions when their dependencies are cleared. Specifically, we add the following rules to those of Section 2.3.10.1: