RISC-V Specification for CHERI Extensions

This document is a specification snapshot built from github.com/riscv/riscv-cheri/commit/639b55e530aeec7b170125d0ea3f973f31d0f3f5 and is not a versioned release. The latest versioned PDF release can be downloaded from github.com/riscv/riscv-cheri/releases.

This document is in the Development state

Expect potential changes. This draft specification is likely to evolve before it is accepted as a standard. Implementations based on this draft may not conform to the future standard.

Copyright and license information

This specification is licensed under the Creative Commons Attribution 4.0 International License (CC-BY 4.0). The full license text is available at creativecommons.org/licenses/by/4.0/.

Contributors

This RISC-V specification has been contributed to directly or indirectly by:

Hesham Almatary <hesham.almatary@cl.cam.ac.uk>
Andres Amaya Garcia <andres.amaya@codasip.com>
John Baldwin <jhb61@cl.cam.ac.uk>
Paul Buxton <paul.buxton@codasip.com>
David Chisnall <david.chisnall@cl.cam.ac.uk>
Jessica Clarke <jessica.clarke@cl.cam.ac.uk>
Brooks Davis <brooks.davis@sri.com>
Nathaniel Wesley Filardo <nwf20@cam.ac.uk>
Franz A. Fuchs <franz.fuchs@cl.cam.ac.uk>
Timothy Hutt <timothy.hutt@codasip.com>
Alexandre Joannou <alexandre.joannou@cl.cam.ac.uk>
Martin Kaiser <martin.kaiser@codasip.com>
Tariq Kurd <tariq.kurd@codasip.com>
Ben Laurie <benl@google.com>
Marno van der Maas <mvdmaas@lowrisc.org>
Maja Malenko <maja.malenko@codasip.com>
A. Theodore Markettos <theo.markettos@cl.cam.ac.uk>
David McKay <david.mckay@codasip.com>
Jamie Melling <jamie.melling@codasip.com>
Stuart Menefy <stuart.menefy@codasip.com>
Simon W. Moore <simon.moore@cl.cam.ac.uk>
Peter G. Neumann <neumann@csl.sri.com>
Robert Norton <robert.norton@cl.cam.ac.uk>
Alexander Richardson <alexrichardson@google.com>
Michael Roe <mr101@cam.ac.uk>
Peter Rugg <peter.rugg@cl.cam.ac.uk>
Peter Sewell <peter.sewell@cl.cam.ac.uk>
Carl Shaw <carl.shaw@codasip.com>
Robert N. M. Watson <robert.watson@cl.cam.ac.uk>
Toby Wenman <toby.wenman@codasip.com>
Jonathan Woodruff <jonathan.woodruff@cl.cam.ac.uk>
Jason Zhijingcheng Yu <yu.zhi@comp.nus.edu.sg>

1. Introduction

1.1. CHERI Concepts and Terminology

Current CPU architectures (including RISC-V) allow memory access solely by specifying and dereferencing a memory address stored as an integer value in a register or in memory. Any accidental or malicious action that modifies such an integer value can result in unrestricted access to the memory that it addresses. Unfortunately, this weak memory protection model has resulted in the majority of software security vulnerabilities present in software today.

CHERI enables software to efficiently implement fine-grained memory protection and scalable software compartmentalization by providing strong, efficient hardware mechanisms to support software execution and enable it to prevent and mitigate vulnerabilities.

Design goals include incremental adoptability from current ISAs and software stacks, low performance overhead for memory protection, significant performance improvements for software compartmentalization, formal grounding, and programmer-friendly underpinnings. It has been designed to provide strong, non-probabilistic protection rather than depending on short random numbers or truncated cryptographic hashes that can be leaked and reinjected, or that could be brute forced.

CHERI enhances the CPU to add hardware memory access control. It has an additional memory access mechanism that protects references to code and data (pointers), rather than the location of code and data (integer addresses). This mechanism is implemented by providing a new primitive, called a capability, that software components can use to implement strongly protected pointers within an address space.

Capabilities are unforgeable and delegatable tokens of authority that grant software the ability to perform a specific set of operations. In CHERI, integer-based pointers can be replaced by capabilities to provide memory access control. In this case, a memory access capability contains an integer memory address that is extended with metadata to protect its integrity, limit how it is manipulated, and control its use. This metadata includes:

an out-of-band tag implementing strong integrity protection (differentiating valid and invalid capabilities) that prevents confusion between data and capabilities
bounds limiting the range of addresses that may be dereferenced
permissions controlling the specific operations that may be performed
sealing which is used to support higher-level software encapsulation

The CHERI model is motivated by the principle of least privilege, which argues that greater security can be obtained by minimizing the privileges accessible to running software. A second guiding principle is the principle of intentional use, which argues that, where many privileges are available to a piece of software, the privilege to use should be explicitly named rather than implicitly selected. While CHERI does not prevent the expression of vulnerable software designs, it provides strong vulnerability mitigation: attackers have a more limited vocabulary for attacks, and should a vulnerability be successfully exploited, they gain fewer rights, and have reduced access to further attack surfaces.

Protection properties for capabilities include the ISA ensuring that capabilities are always derived via valid manipulations of other capabilities (provenance), that corrupted in-memory capabilities cannot be dereferenced (integrity), and that rights associated with capabilities shall only ever be equal or less permissive (monotonicity). Tampering or modifying capabilities in an attempt to elevate their rights will yield an invalid capability as the tag will be cleared. Attempting to dereference via an invalid capability will result in a hardware exception.

CHERI capabilities may be held in registers or in memories, and are loaded, stored, and dereferenced using CHERI-aware instructions that expect capability operands rather than integer addresses. On hardware reset, initial capabilities are made available to software via capability registers. All other capabilities will be derived from these initial valid capabilities through valid capability transformations.

Developers can use CHERI to build fine-grained spatial and temporal memory protection into their system software and applications and significantly improve their security.

1.2. CHERI Extensions to RISC-V

This specification is based on publicly available documentation including (Watson et al., 2023) and (Woodruff et al., 2019). It defines the following extensions to support CHERI alongside RISC-V:

Zcheripurecap: Introduces key, minimal CHERI concepts and features to the RISC-V ISA. The resulting extended ISA is not backwards-compatible with RISC-V.
Zcherihybrid: Extends Zcheripurecap with features to ensure that the ISA extended with CHERI allows backwards binary compatibility with RISC-V. It also adds a mode bit in the encoding of capabilities to allow changing the current CHERI execution mode using indirect jump instructions.
Zcheripte: CHERI extension for RISC-V harts supporting page-based virtual-memory.
Zcherivectorcap: CHERI extension for the RISC-V Vector (V) extension. It adds support for storing CHERI capabilities in vector registers, intended for vectorised memory copying.
Zstid: Extension for supporting thread identifiers. This extension improves software compartmentalization on CHERI systems.

The extension names are provisional and subject to change.

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

If a standard vector extension is present (indicated in this document as "V", but it could equally be one of the subsets defined by a Zve* extension) then Zcherivectorcap may optionally be added in addition to Zcheripurecap.

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 Zcheripurecap. 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 Zcheripurecap and Zcherihybrid.

See Chapter 8 for compatibility with other RISC-V extensions.

1.3. Risks and Known Uncertainty

All extensions could be divided up differently in the future, including after ratification
The RISC-V Architecture Review Committee (ARC) are likely to update all encodings
The ARC are likely to update all CSR addresses
Instruction mnemonics may be renamed
- Any changes will affect assembly code, but assembler aliases can provide backwards compatibility
There is no clarity on how the new Page Table Entry (PTE) bits from Zcheripte will be implemented
- The PTE bits introduce a dependency between exceptions and the stored tag bit

1.3.1. Pending Extensions

The base RISC-V ISAs, along with most extensions, have been reviewed for compatibility with CHERI. However, the following extensions are yet to be reviewed:

"V" Standard Extension for Vector Operations
Core-Local Interrupt Controller (CLIC)

The list above is not complete!

1.3.2. Partially Incompatible 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:

RISC-V CFI specification
"J" Pointer Masking

The list above is not complete!

2. Anatomy of Capabilities in Zcheripurecap

RISC-V defines variants of the base integer instruction set characterized by the width of the integer registers and the corresponding size of the address space. There are two primary ISA variants, RV32I and RV64I, which provide 32-bit and 64-bit address spaces respectively. The term XLEN refers to the width of an integer register in bits (either 32 or 64). The value of XLEN may change dynamically at run-time depending on the values written to CSRs, so we define capability behavior in terms of MXLEN, which is the value of XLEN used in machine mode and the widest XLEN the implementation supports.

Zcheripurecap assumes a version of the privileged architecture which defines MXLEN as constant and requires higher privilege modes to have at least the same XLEN as lower privilege modes; these changes are present in the current draft and expected to be part of privileged architecture 1.13.

Zcheripurecap defines capabilities of size CLEN corresponding to 2 * MXLEN without including the tag bit. The value of CLEN is always calculated based on MXLEN regardless of the effective XLEN value.

We briefly note that the capability encoding described in this section could be replaced with an entirely different design without changing how CHERI integrates with the RISC-V ISA. In particular, this capability encoding specification was designed to run software initially ported to CHERIv9 while providing spatial safety, temporal safety and compartmentalization support alongside a good measure of compatibility with RISC-V software that is not aware of CHERI. Alternative capability encoding specifications must provide key primitives, such as permissions and bounds, from this specification while using a different encoding that, for example, changes the granularity of bounds or adds new features. For simplicity of expression, the text is written as if this was the only possible capability encoding possible for CHERI RISC-V.

2.1. Capability Encoding

The components of a capability, except the tag, are encoded as shown in Figure 1 for MXLEN=32 and Figure 2 for MXLEN=64. Each memory location or register able to hold a capability must also store the tag as out of band information that software cannot directly set or clear. The capability metadata is held in the most significant bits and the address is held in the least significant bits.

Figure 1. Capability encoding for MXLEN=32

Figure 2. Capability encoding for MXLEN=64

Reserved bits are available for future extensions to Zcheripurecap.

Reserved bits must be 0 in tagged capabilities.

2.2. Components of a Capability

Capabilities contain the software accessible fields described in this section.

2.2.1. Tag

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

The capability is invalid if the tag is clear. Using an invalid capability to dereference memory or authorize any operation gives rise to exceptions. All capabilities derived from invalid capabilities are themselves invalid i.e. their tags are 0.

All locations in registers or memory able to hold a capability are CLEN+1 bits wide including the tag bit. Those locations are referred as being CLEN-bit or capability wide in this specification.

2.2.2. Address

The byte-address of a memory location is encoded as MXLEN integer value.

Table 1. Address widths depending on MXLEN
MXLEN	Address width
32	32
64	64

2.2.3. Architectural Permissions (AP)

Description

This field encodes architecturally defined permissions of the capability. Permissions grant access subject to the tag being set, the capability being unsealed (see Section 2.2.5), and bounds checks (see Section 2.2.6). An 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 Zcheripurecap are listed below.

Read Permission (R): Allow reading integer data from memory. Tags are always read as zero when reading integer data.

Write Permission (W): Allow writing integer data to memory. Tags are always written as zero when writing integer data. Every CLEN aligned word in memory has a tag, if any byte is overwritten with integer data then the tag for all CLEN-bits is cleared.

Capability Permission (C): Allow reading capability data from memory if the authorising capability also grants R-permission. Allow writing capability data to memory if the authorising capability also grants W-permission.

Execute Permission (X): Allow instruction execution.

Load Mutable Permission (LM): Allow preserving the W-permission of capabilities loaded from memory. If a capability grants R-permission and C-permission, but no LM-permission, then a capability loaded via this authorizing capability will have W-permission and LM-permission removed provided that the loaded capability has its tag set and is not sealed; loaded capabilities that are sealed or untagged do not have their permissions changed. The rules specified by ACPERM are followed when W-permission and LM-permission are removed, so additional permissions may also be removed. Clearing a capability’s LM-permission and W-permission allows sharing a read-only version of a data structure (e.g. a tree or linked list) without making a copy.

Access System Registers Permission (ASR): Allow read and write access to all privileged (M-mode and S-mode) CSRs. If Zstid is supported the utid, utidc, stid, stidc, mtid, mtidc registers are all considered privileged for the purposes of writing and unprivileged for reading, and thus require ASR-permission for writes but not reads. In all cases a suitable privilege mode is required for access.

Permission Encoding

The bit width of the permissions field depends on the value of MXLEN as shown in Table 2. A 5-bit vector encodes the permissions when MXLEN=32. For this case, the legal encodings of permissions are listed in Table 3. 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.

Table 2. Permissions widths depending on MXLEN
MXLEN	AP field width	Comment
32	5	Encodes some combinations of 6 permission bits, including the M-bit if Zcherihybrid is supported.
64	6	Separate bits for each architectural permission.

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 3 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.

Table 3. Encoding of architectural permissions for MXLEN=32
Encoding[2:0]	R	W	C	LM	X	ASR	Mode¹	Notes
Quadrant 0: Non-capability data read/write
bit[2] - write, bit[1] - reserved (0), bit[0] - read
Reserved bits for future extensions are 0 so new permissions are not implicitly granted
0							N/A	No permissions
1	✔						N/A	Data RO
2-3	reserved
4		✔					N/A	Data WO
5	✔	✔					N/A	Data RW
6-7	reserved
Quadrant 1: Executable capabilities
bit[0] - M-bit (0-Capability Pointer Mode, 1-Integer Pointer Mode)
0-1	✔	✔	✔	✔	✔	✔	Mode¹	Execute + ASR (see Infinite)
2-3	✔		✔	✔	✔		Mode¹	Execute + Data & Cap RO
4-5	✔	✔	✔	✔	✔		Mode¹	Execute + Data & Cap RW
6-7	✔	✔			✔		Mode¹	Execute + Data RW
Quadrant 2: Restricted capability data read/write
bit[2] - write. R and C implicitly granted, LM dependent on W permission.
Reserved bits for future extensions must be 1 so they are implicitly granted
0-2	reserved
3	✔		✔				N/A	Data & Cap RO (no LM)
4-7	reserved
Quadrant 3: Capability data read/write
[2] - write. R and C implicitly granted.
Reserved bits for future extensions must be 1 so they are implicitly granted
0-2	reserved
3	✔		✔	✔			N/A	Data & Cap RO
4-6	reserved
7	✔	✔	✔	✔			N/A	Data & Cap RW

¹ Mode (M-bit) can only be set on a tagged capability when Zcherihybrid is supported. Despite being encoded here it is not an architectural permission.

When MXLEN=32 there are many reserved permission encodings (see Table 3). It is not possible for a tagged capability to have one of these values since ACPERM will never create it. It is possible for untagged capabilities to have reserved values. GCPERM will interpret reserved values as if it were 0b00000 (no permissions). Future extensions may assign meanings to the reserved bit patterns, in which case GCPERM is allowed to report a non-zero value.

A 6-bit vector encodes the permissions when MXLEN=64. In this case, there is a bit per permission as shown in Table 4. A permission is granted if its corresponding bit is set, otherwise the capability does not grant that permission.

Table 4. Encoding of architectural permissions for MXLEN=64
Bit	Name
0	C-permission
1	W-permission
2	R-permission
3	X-permission
4	ASR-permission
5	LM-permission

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

For MXLEN=64, the bit assigned to the M-bit must be zero if X-permission isn’t set.
For MXLEN=32, the M-bit is only encoded in quadrant 1 and does not exist in the other quadrants.

Permission Transitions

Executing ACPERM can result in sets of permissions which cannot be represented when MXLEN=32 (see Table 3) or permission combinations which are not useful for MXLEN=64, such as ASR-permission set without X-permission.

These cases are defined to return useful minimal sets of permissions, which may be no permissions. See ACPERM for these rules.

Future extensions may allow more combinations of permissions, especially for MXLEN=64.

2.2.4. Software-Defined Permissions (SDP)

A bit vector used by the kernel or application programs for software-defined permissions (SDP).

Software is completely free to define the usage of these bits. For example, a program may decide to use an SDP bit to indicate the "ownership" of objects. Therefore, a capability grants permission to free the memory it references if that SDP bit is set because it "owns" that object.

Table 5. SDP widths depending on MXLEN
MXLEN	SDPLEN
32	2
64	4

2.2.5. Capability Type (CT) Bit

This bit indicates the type of the capability: it is a sealed capability if the bit is 1 or unsealed if it is 0.

Sealed capabilities (CT ≠ 0 ) cannot be dereferenced to access memory and are immutable such that modifying any of its fields clears the tag of the output capability.

Sealed capabilities might be useful to software as tokens that can be passed around. The only way of clearing the type bit of a capability is by rebuilding it via a superset capability with CBLD. Zcheripurecap does not offer an unseal instruction.

For code capabilities, the sealing bit is used to implement immutable capabilities that describe function entry points, known as sealed entry (sentry) capabilities. Such capabilities can be leveraged to establish a form of control-flow integrity between mutually distrusting code. A program may jump to a sentry capability to begin executing the instructions it references. A JALR instruction with zero offset automatically unseals a sentry target capability and installs it in the program counter capability (see Section 3.2). The jump-and-link instructions also seal the return address capability which serves as an entry point the callee can return to but cannot use to authorize memory loads or stores.

2.2.6. Bounds (EF, T, TE, B, BE)

Concept

The bounds encode the base and top addresses that constrain memory accesses. The capability can be used to access any memory location A in the range base ≤ A < top. The bounds are encoded in compressed format, so it is not possible to encode any arbitrary combination of base and top addresses. An invalid capability with tag cleared is produced when attempting to construct a capability that is not representable because its bounds cannot be correctly encoded. The bounds are decoded as described in Section 2.1.

The bounds field has the following components:

T: Value substituted into the capability’s address to decode the top address
B: Value substituted into the capability’s address to decode the base address
E: Exponent that determines the position at which B and T are substituted into the capability’s address
EF: Exponent format flag indicating the encoding for T, B and E
- The exponent is stored in T and B if EF=0, so it is 'internal'
- The exponent is zero if EF=1

The bit width of T and B are defined in terms of the mantissa width (MW) which is set depending on the value of MXLEN as shown in Table 6.

Table 6. Mantissa width (MW) values depending on MXLEN
MXLEN	MW
32	10
64	14

The exponent E indicates the position of T and B within the capability’s address as described in Section 2.1. The bit width of the exponent (EW) is set depending on the value of MXLEN. The maximum value of the exponent is calculated as follows:

CAP_MAX_E = MXLEN - MW + 2

The possible values for EW and CAP_MAX_E are shown in Table 7.

Table 7. Exponent widths and CAP_MAX_E depending on MXLEN
MXLEN	EW	CAP_MAX_E
32	5	24
64	6	52

The address and bounds must be representable in valid capabilities i.e. when the tag is set (see Section 2.2.6.3).

Decoding

The metadata is encoded in a compressed format (Woodruff et al., 2019). It uses a floating point representation to encode the bounds relative to the capability address. The base and top addresses from the bounds are decoded as shown below.

TODO: The pseudo-code below does not have a formal notation. It is simply a place-holder while the Sail implementation is unavailable. In this notation, / means "integer division", [] are the bit-select operators, and arithmetic is signed.

EW        = (MXLEN == 32) ? 5 : 6
CAP_MAX_E = MXLEN - MW + 2

If EF = 1:
    E               = 0
    T[EW / 2 - 1:0] = TE
    B[EW / 2 - 1:0] = BE
    LCout           = (T[MW - 3:0] < B[MW - 3:0]) ? 1 : 0
    LMSB            = (MXLEN == 32) ? L8 : 0
else:
    E               = CAP_MAX_E - ( (MXLEN == 32) ? { L8, TE, BE } : { TE, BE } )
    T[EW / 2 - 1:0] = 0
    B[EW / 2 - 1:0] = 0
    LCout           = (T[MW - 3:EW / 2] < B[MW - 3:EW / 2]) ? 1 : 0
    LMSB            = 1

Reconstituting the top two bits of T:

T[MW - 1:MW - 2] = B[MW - 1:MW - 2] + LCout + LMSB

Decoding the bounds:

top:    t = { a[MXLEN - 1:E + MW] + ct, T[MW - 1:0]    , {E{1'b0}} }
base:   b = { a[MXLEN - 1:E + MW] + cb, B[MW - 1:0]    , {E{1'b0}} }

The corrections c_t and c_b are calculated as as shown below using the definitions in Table 8 and Table 9.

A = a[E + MW - 1:E]
R  = B - 2^MW-2

Table 8. Calculation of top address correction
A < R	T < R	c_t
false	false	0
false	true	+1
true	false	-1
true	true	0

Table 9. Calculation of base address correction
A < R	B < R	c_b
false	false	0
false	true	+1
true	false	-1
true	true	0

The base, b, and top, t, addresses are derived from the address by substituting a[E + MW - 1:E] with B and T respectively and clearing the lower E bits. The most significant bits of a may be adjusted up or down by 1 using corrections c_b and c_t to allow encoding memory regions that span alignment boundaries.

The EF bit selects between two cases:

EF = 1: The exponent is 0 for regions less than 2^MW-2 bytes long. L₈ is used to encode the MSB of the length and is added to B along with T[MW-3:0] to form the decoded top.
EF = 0: The exponent is internal with E stored in the lower bits of T and B along with L₈ when MXLEN=32. E is chosen so that the most significant non-zero bit of the length of the region aligns with T[MW - 2] in the decoded top. Therefore, the most significant two bits of T can be derived from B using the equality T = B + L, where L[MW - 2] is known from the values of EF and E and a carry out is implied if T[MW - 3:0] < B[MW - 3:0] since it is guaranteed that the top is larger than the base.

The compressed bounds encoding allows the address to roam over a large representable region while maintaining the original bounds. This is enabled by defining a lower boundary R from the out-of-bounds values that allows us to disambiguate the location of the bounds with respect to an out-of-bounds address. R is calculated relative to the base by subtracting 2^MW-2 from B. If B, T or a[E + MW - 1:E] is less than R, it is inferred that they lie in the 2^E+MW aligned region above R labelled space_U in Figure 3 and the corrections c_t and c_b are computed accordingly. The overall effect is that the address can roam 2^E+MW/4 bytes below the base address and at least 2^E+MW/4 bytes above the top address while still allowing the bounds to be correctly decoded.

Figure 3. Memory address bounds encoded within a capability

A capability has infinite bounds if its bounds cover the entire address space such that the base address b=0 and the top address t≥2^MXLEN, i.e. t is an MXLEN + 1 bit value. However, b is an MXLEN bit value and the size mismatch introduces additional complications when decoding, so the following condition is required to correct t for capabilities whose Representable Range wraps the edge of the address space:

if ( (E < (CAP_MAX_E - 1)) & (t[MXLEN: MXLEN - 1] - b[MXLEN - 1] > 1) )
    t[MXLEN] = !t[MXLEN]

That is, invert the most significant bit of t if the decoded length of the capability is larger than E.

A capability has infinite bounds if E=CAP_MAX_E and it is not malformed (see Section 2.2.6.3); this check is equivalent to b=0 and t≥2^MXLEN.

Malformed Capability Bounds

A capability is malformed if its bounds cannot be correctly decoded. The following check indicates whether a capability is malformed. enableL8 is true when MXLEN=32 and false otherwise, indicating whether the L8 bit is available for extra precision when EF=1.

malformedMSB =  (E == CAP_MAX_E     && B         != 0)
             || (E == CAP_MAX_E - 1 && B[MW - 1] != 0)
malformedLSB =  (E  < 0) || (E == 0 && enableL8)
malformed    =  !EF && (malformedMSB || malformedLSB)

The check is for malformed bounds, so it does not include reserved bits!

CHERI enforces the following invariants for all valid (i.e., tagged) capabilities:

The bounds are not malformed.
No reserved bit in the capability encoding is set.

A tagged capability that violates those invariants (i.e., a tagged but malformed capability or a tagged capability with any reserved bit set) can only possibly be caused by a logic or memory fault (e.g., bit flipping).

Capabilities with malformed bounds:

Return both base and top bounds as zero, which affects instructions like GCBASE.
Cause certain manipulation instructions like CADDI to always clear the tag of the result.

See specific instruction pages for full details of the effect of malformed capabilities.

2.3. Special Capabilities

2.3.1. NULL Capability

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.

Table 10. Field values of the NULL capability
Field	Value	Comment
Tag	zero	Capability is not valid
SDP	zeros	Grants no permissions
AP	zeros	Grants no permissions
M	zero	No meaning since non-executable (MXLEN=64 only)
CT	zero	Unsealed
EF	zero	Internal exponent format
L₈	zero	Top address reconstruction bit (MXLEN=32 only)
T	zeros	Top address bits
T_E	zeros	Exponent bits
B	zeros	Base address bits
B_E	zeros	Exponent bits
Address	zeros	Capability address
Reserved	zeros	All reserved fields

2.3.2. Infinite Capability

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.

The Infinite capability is also known as 'default', 'almighty', or 'root' capability.

Table 11. Field values of the Infinite capability
Field	Value	Comment
Tag	one	Capability is valid
SDP	ones	Grants all permissions
AP (MXLEN=32)	0x8/0x9¹ (see Table 3)	Grants all permissions
AP (MXLEN=64)	0x3F (see Table 4)	Grants all permissions
CT	zero	Unsealed
EF	zero	Internal exponent format
L₈	zero	Top address reconstruction bit (MXLEN=32 only)
T	zeros	Top address bits
T_E	zeros	Exponent bits
B	zeros	Base address bits
B_E	zeros	Exponent bits
Address	zeros	Capability address
Reserved	zeros	All reserved fields

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

For MXLEN=32, the M-bit is set to 1 in the AP field, giving the value 0x9
For MXLEN=64, the M-bit is set to 1 in a separate M field which is not shown in the table above.

2.4. Representable Range Check

2.4.1. Concept

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 addresses.

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:

Instructions such as CADD which include pointer arithmetic.
The SCADDR instruction which updates the capability address field.

2.4.2. Practical Information

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

Upper bits from the address
- This is only if the other sections do not fill the available bits (E + MW ≤ MXLEN)
Middle bits from T and B decoded from the metadata
Lower bits are set to zero
- This is only if there is an internal exponent (EF=0)

Table 12. Composition of the decoded top address bound
Configuration	Upper Section (if E + MW ≤ MXLEN)	Middle Section	Lower Section
EF=0	address[MXLEN:E + MW] + ct	T[MW - 1:0]	{E{1’b0}}
EF=1, i.e. E=0	address[MXLEN:MW] + ct	T[MW - 1:0]

The top described by Table 12 is MXLEN+1 bits wide to allow capabilities to span the whole address space. The address is zero-extended by one bit. The malformed check (see Section 2.2.6.3) ensures that the top never overflows into MXLEN+2 bits and that the base never overflows into MXLEN+1 bits.

The representable range defines the range of addresses which do not corrupt the bounds encoding. The encoding was first introduced in Section 2.1, and is repeated in a different form in Table 12 to aid this description.

For the address to be valid for the current bounds encoding, the value in the Upper Section of Table 12 must not change as this will change the meaning of the bounds.

This gives a range of s=2^E+MW, as shown in Figure 3.

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 - 2^MW-2 in Section 2.1. 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.

3. Integrating Zcheripurecap with the RISC-V Base Integer Instruction Set

Zcheripurecap is an extension to the RISC-V ISA. The extension adds a carefully selected set of instructions and CSRs that are sufficient to implement new security features in the ISA. To ensure compatibility, Zcheripurecap also requires some changes to the primary base integer variants: RV32I, providing 32-bit addresses with 64-bit capabilities, and RV64I, providing 64-bit addresses with 128-bit capabilities. The remainder of this chapter describes these changes for both the unprivileged and privileged components of the base integer RISC-V ISAs.

The changes described in this specification also ensure that Zcheripurecap is compatible with RV32E.

RV128 is not currently supported by any CHERI extension.

3.1. Memory

A hart supporting Zcheripurecap 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 tag bit for each naturally aligned CLEN bits (e.g. 16 bytes in RV64), so that capabilities with their tag set can only be stored in naturally aligned addresses. 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 2.1 is also circular, so address 0 is within the Representable Range of a capability where address 2^MXLEN - 1 is within the bounds. However, the decoded top field of a capability is MXLEN + 1 bits wide and does not wrap, so a capability with base 2^MXLEN - 1 and top 2^MXLEN + 1 is not a subset of the Infinite capability and does not authorise access to the byte at address 0. Like malformed bounds (see Section 2.2.6.3), it is impossible for a CHERI core to generate a tagged capability with top > 2^MXLEN. 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.

3.2. Programmer’s Model for Zcheripurecap

For Zcheripurecap, the 32 unprivileged x registers of the base integer ISA are extended so that they are able to hold a capability as well as renamed to c registers. Therefore, each c register is CLEN bits wide and has an out-of-band tag bit. The x notation refers to the address field of the capability in an unprivileged register while the c notation is used to refer to the full capability (i.e. address, metadata and tag) held in the same unprivileged register.

The tag of the unprivileged c registers must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED for all unprivileged c registers except c0.

Register c0 is hardwired with all bits, including the capability metadata and tag, equal to 0. In other words, c0 is hardwired to the NULL capability.

3.2.1. PCC - The Program Counter Capability

An authorising capability with appropriate permissions is required to execute instructions in Zcheripurecap. Therefore, the unprivileged program counter (pc) register is extended so that it is able to hold a capability. The extended register is called the program counter capability (pcc). The pcc address field is effectively the pc in the base RISC-V ISA so that the hardware automatically increments as instructions are executed. The pcc's metadata and tag are reset to the Infinite capability metadata and tag with the address field set to the core boot address.

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 causes a CHERI exception.

The tag must be set
The capability must not be sealed
The capability must grant execute permission
All bytes of the instruction must be in bounds

Operations that update pcc, such as changing privilege or executing jump instructions, unseal capabilities prior to writing. Therefore, implementations do not need to check that that pcc is unsealed when executing each instruction. However, this property has not yet been formally verified and may not hold if additional CHERI extensions beyond Zcheripurecap are implemented.

It is common for implementations to not allow executing pc relative instructions, such as AUIPC or JAL, in debug mode.

Figure 4. Program Counter Capability

pcc is an executable vector, so it need not be able to hold all possible invalid addresses.

3.3. Capability Instructions

Zcheripurecap introduces new instructions to the base RISC-V integer ISA to inspect and operate on capabilities held in registers.

3.3.1. Capability Inspection Instructions

These instructions allow software to inspect the fields of a capability held in a c register. The output is an integer value written to an x register representing the decoded field of the capability, such as the permissions or bounds. These instructions do not cause exceptions.

GCTAG: inspects the tag of the input capability. The output is 1 if the tag is set and 0 otherwise
GCPERM: outputs the architectural (AP) and software-defined (SDP) permission fields of the input capability
GCTYPE: outputs the type (e.g. unsealed or sentry) of the input capability
GCBASE: outputs the expanded base address of the input capability
GCLEN: outputs the length of the input capability. Length is defined as top - base. The output is 2^MXLEN-1 when the capability’s length is 2^MXLEN
CRAM: outputs the nearest bounds alignment that a valid capability can represent
GCHI: outputs the compressed capability metadata
SCEQ: compares two capabilities including tag, metadata and address
SCSS: tests whether the bounds and permissions of a capability are a subset of those from another capability

GCBASE and GCLEN output 0 when a capability with malformed bounds is provided as an input (see Section 2.2.6.3).

3.3.2. Capability Manipulation Instructions

These instructions allow software to manipulate the fields of a capability held in a c register. The output is a capability written to a c register with its fields modified. The output capability has its tag set to 0 if the input capability did not have a tag set, the output capability has more permissions or larger bounds compared to the input capability, or the operation results in a capability with malformed bounds. These instructions do not give rise to exceptions.

SCADDR: set the address of a capability to an arbitrary address
CADD, CADDI: increment the address of the input capability by an arbitrary offset
SCHI: replace a capability’s metadata with an arbitrary value. The output tag is always 0
ACPERM: bitwise AND of a mask value with a bit map representation of the architectural (AP) and software-defined (SDP) permissions fields
SCBNDS: set the base and length of a capability. The tag is cleared, if the encoding cannot represent the bounds exactly
SCBNDSR: set the base and length of a capability. The base will be rounded down and/or the length will be rounded up if the encoding cannot represent the bounds exactly
SENTRY: seal capability as a sentry capability
CBLD: replace the base, top, address, permissions and mode fields of a capability with the fields from another capability
CMV: move a capability from a c register to another c register

3.3.3. Capability Load and Store Instructions

A load capability instruction, LC, reads CLEN bits from memory together with its tag and writes the result to a c register. The capability authorising the memory access is provided in a c source register, so the effective address is obtained by incrementing that capability with the sign-extended 12-bit offset.

A store capability instruction, SC, writes CLEN bits and the tag in a c register to memory. The capability authorising the memory access is provided in a c source register, so the effective address is obtained by incrementing that capability with the sign-extended 12-bit offset.

LC and SC instructions cause CHERI exceptions if the authorising capability fails any of the following checks:

The tag is zero
The capability is sealed
At least one byte of the memory access is outside the capability’s bounds
For loads, the read permission must be set in AP
For stores, the write permission must be set in AP

Capability load and store instructions also cause load or store/AMO address misaligned exceptions if the address is not naturally aligned to a CLEN boundary.

Misaligned capability loads and stores are errors. Implementations must generate exceptions for misaligned capability loads and stores even if they allow misaligned integer loads and stores to complete normally. Execution environments must report misaligned capability loads and stores as errors and not attempt to emulate them using byte access. The Zicclsm extension does not affect capability loads and stores. Software which uses capability loads and stores to copy data other than capabilities must ensure that addresses are aligned.

Since there is only one tag per aligned CLEN bit block in memory, it is not possible to represent a capability value complete with its tag at an address not aligned to CLEN. Therefore, LC and SC give rise to misaligned address fault exceptions when the effective address to access is misaligned, even if the implementation supports Zicclsm. To transfer CLEN misaligned bits without a tag, use integer loads and stores.

For loads, the tag of the capability loaded from memory is cleared if the authorising capability does not grant permission to read capabilities (i.e. both R-permission and C-permission must be set in AP). For stores, the tag of the capability written to memory is cleared if the authorising capability does not grant permission to write capabilities (i.e. both W-permission and C-permission must be set in AP).

TODO: these cases may cause exceptions in the future - we need a way for software to discover and/or control the behaviour

3.4. Existing RISC-V Instructions

The operands or behavior of some instructions in the base RISC-V ISA changes in Zcheripurecap.

3.4.1. Integer Computational Instructions

Most integer computational instructions operate on XLEN bits of values held in x registers. Therefore, these instructions only operate on the address field if the input register of the instruction holds a capability. The output is XLEN bits written to an x register; the tag and capability metadata of that register are zeroed.

The add upper immediate to pcc instruction (AUIPC) is used to build pcc-relative capabilities. AUIPC forms a 32-bit offset from the 20-bit immediate and filling the lowest 12 bits with zeros. The pcc address is then incremented by the offset and a representability check is performed so the capability’s tag is cleared if the new address is outside the pcc's Representable Range. The resulting CLEN value along with the new tag are written to a c register.

3.4.2. Control Transfer Instructions

Control transfer instructions operate as described in the base RISC-V ISA. They also may cause metadata updates and/or cause exceptions in addition to the base behaviour as described below.

Unconditional Jumps

JAL sign-extends the offset and adds it to the address of the jump instruction to form the target address. The target address is installed in the address field of pcc. The capability with the address of the instruction following the jump is sealed and written to a c register.

JALR allows unconditional, indirect jumps to a target capability. The target capability is obtained by incrementing the capability in the c register operand by the sign-extended 12-bit offset, then setting the least significant bit of the result to zero. The target capability is unsealed if it is a sentry with zero offset. The capability with the address of the instruction following the jump is sealed and written to a c register.

All jumps cause CHERI exceptions when a minimum sized instruction at the target address is not within the bounds of the pcc.

JALR causes a CHERI exception when:

The target capability’s tag is zero
The target capability is sealed and the immediate is not zero
A minimum sized instruction at the target capability’s address is not within bounds
The target capability does not grant execute permission

JAL and JALR can also cause instruction address misaligned exceptions following the standard RISC-V rules.

Conditional Branches

Branch instructions (see Conditional branches (BEQ, BNE, BLT[U], BGE[U])) encode signed offsets in multiples of 2 bytes. The offset is sign-extended and added to the address of the branch instruction to form the target address.

Branch instructions compare two x registers as described in the base RISC-V ISA, so the metadata and tag values are disregarded in the comparison if the operand registers hold capabilities. If the comparison evaluates to true, then the target address is installed in the pcc's address field. These instructions cause CHERI exceptions when a minimum sized instruction at the target address is not within the pcc's bounds.

3.4.3. Integer Load and Store Instructions

Integer load and store instructions transfer the amount of integer data described in the base RISC-V ISA between the registers and memory. For example, LD and LW load 64-bit and 32-bit values respectively from memory into an x register. However, the address operands for load and store instructions are interpreted differently in Zcheripurecap: the capability authorising the access is in the c register operand and the memory address is given by incrementing the address of that capability by the sign-extended 12-bit immediate offset.

All load and store instructions cause CHERI exceptions if the authorising capability fails any of the following checks:

The tag is set
The capability is unsealed
All bytes of accessed memory are inside the capability’s bounds
For loads, the read permission must be set in AP
For stores, the write permission must be set in AP

Integer load instructions always zero the tag and metadata of the result register.

Integer stores write zero to the tag associated with the memory locations that are naturally aligned to CLEN. Therefore, misaligned stores may clear up to two tag bits in memory.

3.5. Zicsr, Control and Status Register (CSR) Instructions

Zcheripurecap requires that RISC-V CSRs intended to hold addresses, like mtvec, are now able to hold capabilities. Therefore, such registers are renamed and extended to CLEN-bit in Zcheripurecap.

Reading or writing any part of a CLEN-bit CSR may cause side effects. For example, the CSR’s tag bit may be cleared if a new address is outside the Representable Range of a CSR capability being written.

This section describes how the CSR instructions operate on these CSRs in Zcheripurecap.

The CLEN-bit CSRs are summarised in Chapter 10.

3.5.1. CSR Instructions

All CSR instructions atomically read-modify-write a single CSR. If the CSR accessed is of capability size then the capability’s tag, metadata and address are all accessed atomically.

When the CSRRW instruction is accessing a capability width CSR, then the source and destination operands are c registers and it atomically swaps the values in the whole CSR with the CLEN width register operand.

There are special rules for updating specific CLEN-wide CSRs as shown in Table 44.

When CSRRS and CSRRC instructions are accessing a capability width CSR, such as mtvecc, then the destination operand is a c register and the source operand is an x register. Therefore, the instructions atomically read CLEN bits from the CSR, calculate the final address using standard RISC-V behaviour (set bits, clear bits, etc.), and that final address is written to the CSR capability’s address field. The update typically uses the semantics of a SCADDR instruction which clears the tag if the capability is sealed, or if the updated address is not representable. Table 44 shows the exact action taken for each capability width CSR.

The CSRRWI, CSRRSI and CSRRCI variants are similar to CSRRW, CSRRS, and CSRRC respectively, when accessing a capability width CSR except that they update the capability’s address only using an XLEN-bit value obtained by zero-extending a 5-bit unsigned immediate field.

All CSR instructions cause CHERI exceptions if the pcc does not grant ASR-permission and the CSR accessed is privileged.

3.6. Control and Status Registers (CSRs)

Zcheripurecap extends the CSRs listed in Table 13, Table 14, Table 15, Table 16 and Table 17 from the base RISC-V ISA and its extensions. The CSRs are renamed to reflect the fact that they are extended to CLEN+1 bits wide, as the x registers are renamed to c registers.

Table 13. Renamed debug-mode CSRs in Zcheripurecap
Zcheripurecap CSR	Address	Extended CSR	Prerequisites	Permissions	Description
dpcc	0x7b1	dpc	Sdext	DRW	Debug Program Counter Capability
dscratch0c	0x7b2	dscratch0	Sdext	DRW	Debug Scratch Capability 0
dscratch1c	0x7b3	dscratch1	Sdext	DRW	Debug Scratch Capability 1

Table 14. Renamed machine-mode CSRs in Zcheripurecap
Zcheripurecap CSR	Address	Extended CSR	Prerequisites	Permissions	Description
mtvecc	0x305	mtvec	M-mode	MRW, ASR-permission	Machine Trap-Vector Base-Address Capability
mscratchc	0x340	mscratch	M-mode	MRW, ASR-permission	Machine Scratch Capability
mepcc	0x341	mepc	M-mode	MRW, ASR-permission	Machine Exception Program Counter Capability
mtidc	0x780	mtid	Zstid	Read: M, Write: M, ASR-permission	Machine thread ID

Table 15. Renamed supervisor-mode CSRs in Zcheripurecap
Zcheripurecap CSR	Address	Extended CSR	Prerequisites	Permissions	Description
stvecc	0x105	stvec	S-mode	SRW, ASR-permission	Supervisor Trap-Vector Base-Address Capability
sscratchc	0x140	sscratch	S-mode	SRW, ASR-permission	Supervisor Scratch Capability
sepcc	0x141	sepc	S-mode	SRW, ASR-permission	Supervisor Exception Program Counter Capability
stidc	0x580	stid	Zstid	Read: S, Write: S, ASR-permission	Supervisor thread ID

Table 16. Renamed virtual supervisor-mode CSRs in Zcheripurecap
Zcheripurecap CSR	Address	Extended CSR	Prerequisites	Permissions	Description
vstvecc	0x205	vstvec	H	HRW, ASR-permission	Virtual Supervisor Trap-Vector Base-Address Capability
vsscratchc	0x240	vsscratch	H	HRW, ASR-permission	Virtual Supervisor Scratch Capability
vsepcc	0x241	vsepc	H	HRW, ASR-permission	Virtual Supervisor Exception Program Counter Capability

Table 17. Renamed user-mode CSRs in Zcheripurecap
Zcheripurecap CSR	Address	Extended CSR	Prerequisites	Permissions	Description
jvtc	0x017	jvt	Zcmt	URW	Jump Vector Table Capability
utidc	0x480	utid	Zstid	Read: U, Write: U, ASR-permission	User thread ID

3.7. Machine-Level CSRs

Zcheripurecap extends some M-mode CSRs to hold capabilities or otherwise add new functions. pcc must grant ASR-permission to access M-mode CSRs regardless of the RISC-V privilege mode.

3.7.1. Machine Status Registers (mstatus and mstatush)

The mstatus and mstatush registers operate as described in (RISC-V, 2023) except for the SXL and UXL fields that control the value of XLEN for S-mode and U-mode, respectively, and the MBE, SBE, and UBE fields that control the memory system endianness for M-mode, S-mode, and U-mode, respectively.

The encoding of the SXL and UXL fields is the same as the MXL field of misa. Only 1 and 2 are supported values for SXL and UXL and the fields must be read-only in implementations supporting Zcheripurecap. The effective XLEN in S-mode and U-mode are termed SXLEN and UXLEN, respectively.

The MBE, SBE, and UBE fields determine the endianness of memory accesses other than instruction fetches performed from M-mode, S-mode, or U-mode, respectively. xBE=0 indicates little endian and xBE=1 is big endian. MBE must be read-only. SBE and UBE must be read only and equal to MBE, if S-mode or U-mode, respectively, is implemented, or read-only zero otherwise.

A further CHERI extension, Zcherihybrid, optionally makes SXL, UXL, MBE, SBE, and UBE writeable, so implementations that support multiple base ISAs must support both Zcheripurecap and Zcherihybrid.

3.7.2. Machine Trap Vector Base Address Register (mtvec)

The mtvec register is as defined in (RISC-V, 2023). It is an MXLEN-bit register used as the executable vector jumped to when taking traps into machine mode. It is extended into mtvecc.

Figure 5. Machine-mode trap-vector base-address register

3.7.3. Machine Trap Vector Base Address Capability Register (mtvecc)

The mtvecc register is a renamed extension of mtvec that holds a capability. Its reset value is the Infinite capability. The capability represents an executable vector.

Figure 6. Machine-mode trap-vector base-capability register

The metadata is WARL as not all fields need to be implemented, for example the reserved fields will always read as zero.

When interpreting mtvecc as a capability, as for mtvec, address bits [1:0] are always zero (as they are reused by the MODE field).

When MODE=Vectored, all synchronous exceptions into machine mode cause the pcc to be set to the capability, whereas interrupts cause the pcc to be set to the capability with its address incremented by four times the interrupt cause number.

Capabilities written to mtvecc also include writing the MODE field in mtvecc.address[1:0]. As a result, a representability and sealing check is performed on the capability with the legalized (WARL) MODE field included in the address. The tag of the capability written to mtvecc is cleared if either check fails.

Additionally, when MODE=Vectored the capability has its tag bit cleared if the capability address + 4 x HICAUSE is not within the representable bounds. HICAUSE is the largest exception cause value that the implementation can write to mcause when an interrupt is taken.

When MODE=Vectored, it is only required that address + 4 x HICAUSE is within representable bounds instead of the capability’s bounds. This ensures that software is not forced to allocate a capability granting access to more memory for the trap-vector than necessary to handle the trap causes that actually occur in the system.

3.7.4. Machine Scratch Register (mscratch)

The mscratch register is as defined in (RISC-V, 2023). It is an MXLEN-bit read/write register dedicated for use by machine mode. Typically, it is used to hold a pointer to a machine-mode hart-local context space and swapped with a user register upon entry to an M-mode trap handler. mscratch is extended into mscratchc.

Figure 7. Machine-mode scratch register

3.7.5. Machine Scratch Capability Register (mscratchc)

The mscratchc register is a renamed extension of mscratch that is able to hold a capability.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

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

Figure 8. Machine-mode scratch capability register

3.7.6. Machine Exception Program Counter (mepc)

The mepc register is as defined in (RISC-V, 2023). It is extended into mepcc.

Figure 9. Machine exception program counter register

3.7.7. Machine Exception Program Counter Capability (mepcc)

The mepcc register is a renamed extension of mepc that is able to hold a capability. Its reset value is the Infinite capability.

Figure 10. Machine exception program counter capability register

Capabilities written to mepcc must be legalised by implicitly zeroing bit mepcc[0]. Additionally, if an implementation allows IALIGN to be either 16 or 32, then whenever IALIGN=32, the capability read from mepcc must be legalised by implicitly zeroing mepcc[1]. Therefore, the capability read or written has its tag bit cleared if the legalised address is not within the Representable Range or if the legalisation changes the address and the capability is sealed.

When reading or writing a sealed capability in mepcc, the tag is not cleared if the original address equals the legalized address.

When a trap is taken into M-mode, mepcc is written with the pcc including the virtual address of the instruction that was interrupted or that encountered an exception. Otherwise, mepcc is never written by the implementation, though it may be explicitly written by software.

As shown in Table 46, mepcc is an executable vector, so it does not need to be able to hold all possible invalid addresses. Additionally, the capability in mepcc is unsealed when it is installed in pcc on execution of an MRET instruction.

3.7.8. Machine Cause Register (mcause)

Zcheripurecap 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 Table 18 and Table 19 respectively. The behavior and usage of mcause otherwise remains as described in (RISC-V, 2023).

Figure 11. Machine cause register

Table 18. Machine cause register (mcause) values after trap. Entries added in Zcheripurecap are in **bold**
Interrupt	Exception Code	Description
1 1 1 1	0 1 2 3	Reserved Supervisor software interrupt Reserved Machine software interrupt
1 1 1 1	4 5 6 7	Reserved Supervisor timer interrupt Reserved Machine timer interrupt
1 1 1 1	8 9 10 11	Reserved Supervisor external interrupt Reserved Machine external interrupt
1 1	12-15 ≥16	Reserved Designated for platform use
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0	0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16-23 24-27 28 29-31 32-47 48-63 ≥64	Instruction address misaligned Instruction access fault Illegal instruction Breakpoint Load address misaligned Load access fault Store/AMO address misaligned Store/AMO access fault Environment call from U-mode Environment call from S-mode Reserved Environment call from M-mode Instruction page fault Load page fault Reserved Store/AMO page fault Reserved Designated for custom use CHERI fault Designated for custom use Reserved Designated for custom use Reserved

Table 19. Synchronous exception priority in decreasing priority order. Entries added in Zcheripurecap are in **bold**
Priority	Exc.Code	Description
Highest	3	Instruction address breakpoint
	28	Prior to instruction address translation: CHERI fault due to PCC checks (tag, execute permission, invalid address and bounds)
	12, 1	During instruction address translation: First encountered page fault or access fault
	1	With physical address for instruction: Instruction access fault
	2 0 8,9,11 3 3	Illegal instruction Instruction address misaligned Environment call Environment break Load/store/AMO address breakpoint
	28	CHERI faults due to: PCC ASR-permission clear Branch/jump target address checks (tag, execute permissions, invalid address and bounds)
	28	Prior to address translation for an explicit memory access: CHERI fault due to capability checks (tag, permissions, invalid address and bounds)
	4,6	Load/store/AMO capability address misaligned Optionally: Load/store/AMO address misaligned
	13, 15, 5, 7	During address translation for an explicit memory access: First encountered page fault or access fault
	5,7	With physical address for an explicit memory access: Load/store/AMO access fault
Lowest	4,6	If not higher priority: Load/store/AMO address misaligned

The full details of the CHERI exceptions are in Table 23.

3.7.9. Machine Trap Delegation Register (medeleg)

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

3.7.10. Machine Trap Value Register (mtval)

The mtval register is an MXLEN-bit read-write register. When a CHERI fault is taken into M-mode, mtval is written with additional CHERI-specific exception information with the format shown in Figure 12 to assist software in handling the trap.

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

Figure 12. Machine trap value register

TYPE is a CHERI-specific fault type that caused the exception while CAUSE is the cause of the fault. The possible CHERI types and causes are encoded as shown in Table 20 and Table 21 respectively.

Table 20. Encoding of TYPE field
CHERI Type Code	Description
0	CHERI instruction access fault
1	CHERI data fault due to load, store or AMO
2	CHERI jump or branch fault
3-15	Reserved

Table 21. Encoding of CAUSE field
CHERI Cause Code	Description
0	Tag violation
1	Seal violation
2	Permission violation
3	Invalid address violation
4	Length violation
5-15	Reserved

CHERI violations have the following order in priority:

Tag violation (Highest)
Seal violation
Permission violation
Invalid address violation
Length violation (Lowest)

3.8. Supervisor-Level CSRs

Zcheripurecap extends some of the existing RISC-V CSRs to be able to hold capabilities or with other new functions. pcc must grant ASR-permission to access S-mode CSRs regardless of the RISC-V privilege mode.

3.8.1. Supervisor Trap Vector Base Address Register (stvec)

The stvec register is as defined in (RISC-V, 2023). It is an SXLEN-bit register used as the executable vector jumped to when taking traps into supervisor mode. It is extended into stvecc.

Figure 13. Supervisor trap-vector base-address register

3.8.2. Supervisor Trap Vector Base Address Capability Register (stvecc)

The stvec register is an SXLEN-bit WARL read/write register that holds the trap vector configuration, consisting of a vector base address (BASE) and a vector mode (MODE). The stvecc register is a renamed extension of stvec that is able to hold a capability. Its reset value is the Infinite capability.

Figure 14. Supervisor trap-vector base-capability register

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

3.8.3. Supervisor Scratch Register (sscratch)

The sscratch register is as defined in (RISC-V, 2023). It is an MXLEN-bit read/write register dedicated for use by supervisor mode. Typically, it is used to hold a pointer to a supervisor-mode hart-local context space and swapped with a user register upon entry to an S-mode trap handler. sscratch is extended into sscratchc.

Figure 15. Supervisor-mode scratch register

3.8.4. Supervisor Scratch Capability Register (sscratchc)

The sscratchc register is a renamed extension of sscratch that is able to hold a capability.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

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

Figure 16. Supervisor scratch capability register

3.8.5. Supervisor Exception Program Counter (sepc)

The sepc register is as defined in (RISC-V, 2023). It is extended into sepcc.

Figure 17. Supervisor exception program counter register

3.8.6. Supervisor Exception Program Counter Capability (sepcc)

The sepcc register is a renamed extension of sepc that is able to hold a capability. Its reset value is the Infinite capability.

As shown in Table 46, sepcc is an executable vector, so it need not be able to hold all possible invalid addresses. Additionally, the capability in sepcc is unsealed when it is installed in pcc on execution of an SRET instruction. The handling of sepcc is otherwise identical to mepcc, but in supervisor mode.

Figure 18. Supervisor exception program counter capability register

3.8.7. Supervisor Cause Register (scause)

Zcheripurecap adds a new exception code for CHERI exceptions that scause must be able to represent. The new exception code and its priority are listed in Table 22 and Table 19 respectively. The behavior and usage of scause otherwise remains as described in (RISC-V, 2023).

Figure 19. Supervisor cause register

Table 22. Supervisor cause register (scause) values after trap. Causes added in Zcheripurecap are in **bold**
Interrupt	Exception Code	Description
1 1 1 1 1 1 1 1	0 1 2-4 5 6-8 9 10-15 ≥16	Reserved Supervisor software interrupt Reserved Supervisor timer interrupt Reserved Supervisor external interrupt Reserved Designated for platform use
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0	0 1 2 3 4 5 6 7 8 9 10-11 12 13 14 15 16-23 24-27 28 29-31 32-47 48-63 ≥64	Instruction address misaligned Instruction access fault Illegal instruction Breakpoint Load address misaligned Load access fault Store/AMO address misaligned Store/AMO access fault Environment call from U-mode Environment call from S-mode Reserved Instruction page fault Load page fault Reserved Store/AMO page fault Reserved Designated for custom use CHERI fault Designated for custom use Reserved Designated for custom use Reserved

3.8.8. Supervisor Trap Value Register (stval)

The stval register is an SXLEN-bit read-write register. When a CHERI fault is taken into S-mode, stval is written with additional CHERI-specific exception information with the format shown in Figure 20 to assist software in handling the trap.

Figure 20. Supervisor trap value register

TYPE is a CHERI-specific fault type that caused the exception while CAUSE is the cause of the fault. The possible CHERI types and causes are encoded as shown in Table 20 and Table 21 respectively.

3.9. Unprivileged CSRs

Unlike machine and supervisor level CSRs, Zcheripurecap does not require pcc to grant ASR-permission to access unprivileged CSRs.

3.10. CHERI Exception handling

auth_cap is ddc for Integer Pointer Mode and cs1 for Capability Pointer Mode

Table 23. Valid CHERI exception combination description
Instructions	Xcause	Xtval. TYPE	Xtval. CAUSE	Description	Check
All instructions have these exception checks first
All	28	0	0	pcc tag	not(pcc.tag)
All	28	0	1	pcc seal	isCapSealed(pcc)¹
All	28	0	2	pcc permission	not(pcc.X-permission)
All	28	0	3	pcc invalid address	pcc holds an invalid address
All	28	0	4	pcc length	Any byte of current instruction out of pcc bounds
CSR/Xret additional exception check
CSR*, MRET, SRET	28	0	2	pcc permission	not(pcc.ASR-permission) when required for CSR access or execution of MRET/SRET
direct jumps additional exception check
JAL, Conditional branches (BEQ, BNE, BLT[U], BGE[U])	28	2	4	pcc length	any byte of minimum length instruction at target out of pcc bounds
indirect jumps additional exception checks
indirect jumps	28	2	0	`cs1` tag	not(`cs1.tag`)
indirect jumps	28	2	1	`cs1` seal	isCapSealed(`cs1`) and imm12 != 0
indirect jumps	28	2	2	`cs1` permission	not(`cs1`.X-permission)
indirect jumps	28	2	3	`cs1` invalid address	target address is an invalid address
indirect jumps	28	2	4	`cs1` length	any byte of minimum length instruction at target out of `cs1` bounds
Load additional exception checks
all loads	28	1	0	`auth_cap` tag	not(`auth_cap.tag`)
all loads	28	1	1	`auth_cap` seal	isCapSealed(`auth_cap`)
all loads	28	1	2	`auth_cap` permission	not(`auth_cap`.R-permission)
all loads	28	1	3	`auth_cap` invalid address	Address is invalid (see Invalid address conversion)
all loads	28	1	4	`auth_cap` length	Any byte of load access out of `auth_cap` bounds
capability loads	4	N/A	N/A	load address misaligned	Misaligned capability load
Store/atomic/cache-block-operation additional exception checks
all stores, all atomics, all cbos	28	1	0	`auth_cap` tag	not(`auth_cap.tag`)
all stores, all atomics, all cbos	28	1	1	`auth_cap` seal	isCapSealed(`auth_cap`)
all atomics, CBO.INVAL*	28	1	2	`auth_cap` permission	not(`auth_cap`.R-permission)
all stores, all atomics, CBO.INVAL, CBO.ZERO	28	1	2	`auth_cap` permission	not(`auth_cap`.W-permission)
CBO.CLEAN, CBO.FLUSH	28	1	2	`auth_cap` permission	not(`auth_cap`.R-permission) and not(`auth_cap`.W-permission)
all stores, all atomics, all cbos	28	1	3	`auth_cap` invalid address	Address is invalid (see Invalid address conversion)
all stores, all atomics	28	1	4	`auth_cap` length	any byte of access out of `auth_cap` bounds
CBO.ZERO, CBO.INVAL	28	1	4	`auth_cap` length	any byte of cache block out of `auth_cap` bounds
CBO.CLEAN, CBO.FLUSH	28	1	4	`auth_cap` length	all bytes of cache block out of `auth_cap` bounds
CBO.INVAL*	28	0	2	pcc permission	not(pcc.ASR-permission)
capability stores	6	N/A	N/A	capability alignment	Misaligned capability store

¹ This check is architecturally required, but is impossible to encounter so may not required in an implementation.

Indirect branches are JALR, conditional branches are Conditional branches (BEQ, BNE, BLT[U], BGE[U]).

CBO.ZERO issues as a cache block wide store. All CMOs operate on the cache block which contains the address. Prefetches check that the capability is tagged, not sealed, has the permission (R-permission, W-permission, X-permission) corresponding to the instruction, and has bounds which include at least one byte of the cache block; if any check fails, the prefetch is not performed but no exception is generated.

3.11. CHERI Exceptions and speculative execution

CHERI adds architectural guarantees that can prove to be microarchitecturally useful. Speculative-execution attacks can — among other factors — rely on instructions that fail CHERI permission checks not to take effect. When implementing any of the extensions proposed here, microarchitects need to carefully consider the interaction of late-exception raising and side-channel attacks.

3.12. Physical Memory Attributes (PMA)

Typically, the entire memory space need not support tagged data. Therefore, it is desirable that harts supporting Zcheripurecap extend PMAs with a taggable attribute indicating whether a memory region allows storing tagged data.

Data loaded from memory regions that are not taggable will always have the tag cleared. When the hart attempts to store data with the tag set to memory regions that are not taggable, the implementation may:

Cause an access fault exception
Implicitly set the stored tag to 0

3.13. Page-Based Virtual-Memory Systems

RISC-V’s page-based virtual-memory management is generally orthogonal to CHERI. In Zcheripurecap, capability addresses are interpreted with respect to the privilege level of the processor in line with RISC-V’s handling of integer addresses. In machine mode, capability addresses are generally interpreted as physical addresses; if the mstatus MPRV flag is asserted, then data accesses (but not instruction accesses) will be interpreted as if performed by the privilege mode in mstatus’s MPP. In supervisor and user modes, capability addresses are interpreted as dictated by the current satp configuration: addresses are virtual if paging is enabled and physical if not.

Zcheripurecap requires that the pcc grants the ASR-permission to change the page-table root satp and other virtual-memory parameters as described in Section 3.8.

3.13.1. Invalid Address Handling

When address translation is in effect and XLEN=64, the upper bits of virtual memory addresses must match for the address to be valid:

For Sv39, bits [63:39] must equal bit 38
For Sv48, bits [63:48] must equal bit 47
For Sv57, bits [63:57] must equal bit 56

RISC-V permits that CSRs holding addresses, such as mtvec and mepc (see Table 46) as well as pc, need not hold all possible invalid addresses. Implementations may convert an invalid address into some other invalid address that the register is capable of holding. Therefore, implementations often support area and power optimizations by compressing invalid addresses in a lossy fashion.

Where compressed addresses are implemented, there must be also sufficient address bits to represent all valid physical addresses. The following description is for both virtual and physical addresses.

Compressing invalid addresses allows implementations to reduce the number of flip-flops required to hold some CSRs, such as mtvec. In CHERI, invalid addresses may also be used to reduce the number of bits to compare during a bounds check, for example, to 40 bits if using Sv39, assuming that this also covers all valid physical addresses.

Care needs to be taken not to truncate physical addresses to the implemented number of physical addresses bits without also checking that the capability is still valid following the rules in this section, as the capability bounds and representable range always cover the entire MXLEN-bit address bits, but the address is likely not to.

However, the bounds encoding of capabilities in Zcheripurecap depends on the address value, so implementations must not convert invalid addresses to other arbitrary invalid address in an unrestricted manner. The remainder of this section describes how invalid address handling must be supported in Zcheripurecap when accessing CSRs, branching and jumping, and accessing memory.

Accessing CSRs

The following procedure must be used when executing instructions, such as CSRRW, that write a capability A to a CSR that cannot hold all invalid addresses:

If A’s address is invalid and A does not have infinite bounds (see Section 2.1), then A’s tag is set to 0.
Write the final (potentially modified) version of capability A to the CSR e.g. mtvecc, mepcc, etc.

Branches and Jumps

Control transfer instructions jump or branch to a capability A which can be:

pcc for branches, direct jumps and any branch when in Integer Pointer Mode (see Chapter 5).
The capability in the c input register of a jump when in Capability Pointer Mode (see Chapter 5).

The following procedure must be used when jumping or branching to the target capability A if the pcc cannot hold all invalid addresses:

Calculate the effective target address T of the jump or branch as required by the instruction’s behavior.
If T is invalid and A does not have infinite bounds (see Section 2.1), then the instruction gives rise to a CHERI fault; the CHERI jump or branch fault is reported in the TYPE field and invalid address violation is reported in the CAUSE field of mtval or stval.
If T is invalid and A has infinite bounds (see Section 2.1), then A’s tag is unchanged and T is written into A’s address field. Attempting to execute the instruction at address T gives rise to an instruction access fault or page fault as is usual in RISC-V.
Otherwise T is valid and the instruction behaves as normal.

RISC-V harts that do not support Zcheripurecap normally raise an instruction access fault or page fault after jumping or branching to an invalid address. Therefore, Zcheripurecap aims to preserve that behavior to ensure that harts supporting Zcheripurecap and Zcherihybrid are fully compatible with RISC-V harts provided that pcc and ddc are set to the Infinite capability.

Memory Accesses

The following procedure must be used while loading or storing to memory with a capability A when the implementation supports invalid address optimizations:

Calculate the effective address range R of the memory access as required by the instruction’s behavior.
If any byte in R is invalid and A does not have infinite bounds (see Section 2.1), then the instruction gives rise to a CHERI fault; the CHERI data fault is reported in the TYPE field and invalid address violation is reported in the CAUSE field of mtval or stval.
If any byte in R is invalid and A has infinite bounds (see Section 2.1), the hart will raise an access fault or page fault as is usual in RISC-V.
Otherwise all bytes in R are valid and the instruction behaves as normal.

3.14. Integrating Zcheripurecap with Sdext

This section describes changes to integrate the Sdext ISA and Zcheripurecap. It must be implemented to make external debug compatible with Zcheripurecap. Modifications to Sdext are kept to a minimum.

This section is preliminary as no-one has yet built debug support for CHERI-RISC-V so change is likely.

The following features, which are optional in Sdext, must be implemented for use with Zcheripurecap:

The hartinfo register must be implemented.
All harts which support Zcheripurecap must provide hartinfo.nscratch of at least 1 and implement the dscratch0c register.
All harts which support Zcheripurecap must provide hartinfo.datasize of at least 1 and hartinfo.dataaccess of 0.
The program buffer must be implemented, with abstractcs.progbufsize of at least 4 if dmstatus.impebreak is 1, or at least 5 if dmstatus.impebreak is 0.

These requirements allow a debugger to read and write capabilities in integer registers without disturbing other registers. These requirements may be relaxed if some other means of accessing capabilities in integer registers, such as an extension of the Access Register abstract command, is added. The following sequences demonstrate how a debugger can read and write a capability in c1 if MXLEN is 64, hartinfo.dataaccess is 0, hartinfo.dataaddr is 0xBF0, hartinfo.datasize is 1, dmstatus.impebreak is 0, and abstractcs.progbufsize is 5:

# Read the high MXLEN bits into data0-data1
csrrw  c2, dscratch0c, c2
gchi   x2, c1
csrw   0xBF0, x2
csrrw  c2, dscratch0c, c2
ebreak

# Read the tag into data0
csrrw  c2, dscratch0c, c2
gctag  x2, c1
csrw   0xBF0, x2
csrrw  c2, dscratch0c, c2
ebreak

# Write the high MXLEN bits from data0-data1
csrrw  c2, dscratch0c, c2
csrr   x2, 0xBF0
schi   c1, c1, x2
csrrw  c2, dscratch0c, c2
ebreak

# Write the tag (if nonzero)
csrrw   c2, dscratch0c, c2
csrr    c2, dinfc
cbld    c1, c2, c1
csrrw   c2, dscratch0c, c2
ebreak

The low MXLEN bits of a capability are read and written using normal Access Register abstract commands. If dscratch0c were known to be preserved between abstract commands, it would be possible to remove the requirements on hartinfo.datasize, hartinfo.dataaccess, and abstractcs.progbufsize, however there is no way to discover the former property.

3.14.1. Debug Mode

When executing code due to an abstract command, the hart stays in debug mode and the rules outlined in Section 4.1 of (RISC-V, 2022) apply.

3.14.2. Core Debug Registers

Zcheripurecap renames and extends debug CSRs that are designated to hold addresses to be able to hold capabilities. The renamed debug CSRs are listed in Table 13.

The pcc must grant ASR-permission to access debug CSRs. This permission is automatically provided when the hart enters debug mode as described in the dpcc section. The pcc metadata can only be changed if the implementation supports executing control transfer instructions from the program buffer — this is an optional feature according to (RISC-V, 2022).

3.14.3. Debug Program Counter (dpc)

The dpc register is as defined in (RISC-V, 2022). It is a DXLEN-bit register used as the PC saved when entering debug mode. dpc is extended into dpcc.

Figure 21. Debug program counter

3.14.4. Debug Program Counter Capability (dpcc)

The dpcc register is a renamed extension to dpc that is able to hold a capability.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Figure 22. Debug program counter capability

Upon entry to debug mode, (RISC-V, 2022), does not specify how to update the PC, and says PC relative instructions may be illegal. This concept is extended to include any instruction which reads or updates pcc, which refers to all jumps, conditional branches and AUIPC. The exception is MODESW which is supported if Zcherihybrid is implemented, see dinfc for details.

As a result, the value of pcc is UNSPECIFIED in debug mode according to this specification. The pcc metadata has no architectural effect in debug mode. Therefore ASR-permission is implicitly granted for access to all CSRs and no PCC faults are possible.

dpcc (and consequently dpc) are updated with the capability in pcc whose address field is set to the address of the next instruction to be executed as described in (RISC-V, 2022) upon debug mode entry.

When leaving debug mode, the capability in dpcc is unsealed and written into pcc. A debugger may write dpcc to change where the hart resumes and its mode, permissions, sealing or bounds.

The legalisation of dpcc follows the same rules described for mepcc.

3.14.5. Debug Scratch Register 0 (dscratch0)

The dscratch0 register is as defined in (RISC-V, 2022). It is an optional DXLEN-bit scratch register that can be used by implementations which need it. dscratch0 is extended into dscratch0c.

Figure 23. Debug scratch 0 register

3.14.6. Debug Scratch Register 0 Capability (dscratch0c)

The dscratch0c register is a CLEN-bit plus tag bit renamed extension to dscratch0 that is able to hold a capability.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Figure 24. Debug scratch 0 capability register

3.14.7. Debug Scratch Register 1 (dscratch1)

The dscratch1 register is as defined in (RISC-V, 2022). It is an optional DXLEN-bit scratch register that can be used by implementations which need it. dscratch1 is extended into dscratch1c.

Figure 25. Debug scratch 1 register

3.14.8. Debug Scratch Register 1 Capability (dscratch1c)

The dscratch1c register is a CLEN-bit plus tag bit renamed extension to dscratch1 that is able to hold a capability.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Figure 26. Debug scratch 1 capability register

3.14.9. Debug Infinite Capability Register (dinfc)

The dinfc register is a CLEN-bit plus tag bit CSR only accessible in debug mode.

The reset value is the Infinite capability with the M-bit set to 0, regardless of whether Zcherihybrid (see Section 5.1) is implemented:

dinfc is read/write but with no writeable fields, and so writes are ignored.

A future version of this specification may add writeable fields to allow creation of other capabilities, if, for example, a future extension requires multiple formats for the Infinite capability.

Figure 27. Debug infinite capability register

3.15. Integrating Zcheripurecap with Sdtrig

The Sdtrig extension is generally orthogonal to Zcheripurecap. However, the priority of synchronous exceptions and where triggers fit is adjusted as shown in Table 24.

Table 24. Synchronous exception priority (including triggers) in decreasing priority order. Entries added in Zcheripurecap are in **bold**
Priority	Exc.Code	Description	Trigger
Highest	3 3 3 3		etrigger icount itrigger mcontrol/mcontrol6 after (on previous instruction)
	3	Instruction address breakpoint	mcontrol/mcontrol6 execute address before
	28	Prior to instruction address translation: CHERI fault due to PCC checks (tag, execute permission, invalid address and bounds)
	12, 1	During instruction address translation: First encountered page fault or access fault
	1	With physical address for instruction: Instruction access fault
	3		mcontrol/mcontrol6 execute data before
	2 0 8,9,11 3	Illegal instruction Instruction address misaligned Environment call Environment break
	3	Load/store/AMO address breakpoint	mcontrol/mcontrol6 load/store address before
	3		mcontrol/mcontrol6 store data before
	28	CHERI faults due to: PCC ASR-permission clear Branch/jump target address checks (tag, execute permissions, invalid address and bounds)
	28	Prior to address translation for an explicit memory access: Load/store/AMO capability address misaligned CHERI fault due to capability checks (tag, permissions, invalid address and bounds)
	4,6	Optionally: Load/store/AMO address misaligned
	13, 15, 5, 7	During address translation for an explicit memory access: First encountered page fault or access fault
	5,7	With physical address for an explicit memory access: Load/store/AMO access fault
	4,6	If not higher priority: Load/store/AMO address misaligned
Lowest	3		mcontrol/mcontrol6 load data before

4. "Zcheripte" Extension for CHERI Page-Based Virtual-Memory Systems

CHERI is a security mechanism that is generally orthogonal to page-based virtual-memory management as defined in (RISC-V, 2023). However, it is helpful in CHERI harts to extend RISC-V’s virtual-memory management to control the flow of capabilities in memory at the page granularity. For this reason, the Zcheripte extension adds new bits to RISC-V’s Page Table Entry (PTE) format.

4.1. Extending the Page Table Entry Format

The page table entry format remains unchanged for Sv32. However, two new bits, Capability Write (CW) and Capability Dirty (CD), are added to leaf PTEs in Sv39, Sv48 and Sv57 as shown in Figure 28, Figure 29 and Figure 30 respectively.

Figure 28. Sv39 page table entry

Figure 29. Sv48 page table entry

Figure 30. Sv57 page table entry

The CW bit indicates whether writing capabilities with tag set to the virtual page is permitted. Two schemes to manage the CW bit are permitted:

A store page fault exception is raised when a capability store or AMO instruction is executed, the authorizing capability grants W-permission and C-permission, and the store address corresponds to a virtual page with the CW bit clear.
When a capability store or AMO instruction is executed, the implementation clears the tag bit of the capability written to a virtual page with the CW bit clear.

The implementation of the CW bit does not force a dependency on the tag bit’s value of the capability written, so implementations must support the CW bit.

The CD bit indicates that a capability with tag set has been written to the virtual page since the last time the CD bit was cleared. Implementations are strongly encouraged, but not required, to support CD. If supported, two schemes to manage the CD bit are permitted:

A store page fault exception is raised when a capability store or AMO instruction is executed, the authorizing capability grants W-permission and C-permission, the tag bit of the capability being written is set and the address written corresponds to a virtual page with the CD bit clear.
When a capability store or AMO instruction is executed, the authorizing capability grants W-permission and C-permission, the tag bit of the capability being written is set and the store address corresponds to a virtual page with the CD bit clear, the implementation sets the corresponding bit in the PTE. The PTE update must be atomic with respect to other accesses to the PTE, and must atomically check that the PTE is valid and grants sufficient permissions. Updates to the CD bit must be exact (i.e. not speculative), and observed in program order by the local hart. Furthermore, the PTE update must appear in the global memory order no later than the explicit memory access, or any subsequent explicit memory access to that virtual page by the local hart. The ordering on loads and stores provided by FENCE instructions and the acquire/release bits on atomic instructions also orders the PTE updates associated with those loads and stores as observed by remote harts.

The PTE update is not required to be atomic with respect to the explicit memory access that caused the update, and the sequence is interruptible. However, the hart must not perform explicit memory access before the PTE update is globally visible.

The behavior of the CW bit takes priority over the CD bit. Therefore, implementations must not take action to change or raise an exception related to the CD bit when the CW bit is clear.

4.2. Extending the Machine Environment Configuration Register (menvcfg)

The menvcfg register is extended to allow discovering whether the implementation supports the CD bit.

The menvcfg register operates as described in (RISC-V, 2023). Zcheripurecap adds a new enable bit as shown in Figure 31 when XLEN=64.

Figure 31. Machine environment configuration register (menvcfg)

The Capability Dirty Enable (CDE) bit controls whether the Capability Dirty (CD) bit is available for use in S-mode address translation. When CDE=1, the CD bit is available for S-mode address translation. When CDE=0, the implementation behaves as though the CD bit were not implemented. If CD is not implemented, CDE is read-only zero. If CD is implemented although not configurable, CDE is read-only one.

5. "Zcherihybrid" Extension for CHERI Integer Pointer Mode

Zcherihybrid is an optional extension to Zcheripurecap. Implementations that support Zcheripurecap and Zcherihybrid define a variant of the CHERI ISA that is fully binary compatible with existing RISC-V code.

Key features in Zcherihybrid include a definition of a CHERI execution mode, a new unprivileged register, additional instructions and extensions to some existing CSRs enabling CHERI features. The remainder of this section describes these features in detail as well as their integration with the primary base integer variants of the RISC-V ISA (RV32I and RV64I).

5.1. CHERI Execution Mode

Zcherihybrid adds CHERI execution modes to ensure backwards compatibility with the base RISC-V ISA while saving instruction encoding space. There are two execution modes: Capability Pointer Mode and Integer Pointer Mode. Additionally, there is a new unprivileged register: the default data capability, ddc, that is used to authorise all data memory accesses when in Integer Pointer Mode.

The current CHERI execution mode is given by the M-bit field of pcc that is encoded as described in Section 5.1.

The CHERI execution mode impacts the instruction set in the following ways:

The authorising capability used to execute memory access instructions. In Integer Pointer Mode, ddc is implicitly used. In Capability Pointer Mode, the authorising capability is supplied as an explicit c operand register to the instruction.
The set of instructions that is available for execution. Some instructions are available in Integer Pointer Mode but not Capability Pointer Mode and vice-versa (see Chapter 8).

The implication is that the CHERI execution mode is always Capability Pointer Mode on implementations that support Zcheripurecap, but not Zcherihybrid.

The CHERI execution mode is effectively an extension to some RISC-V instruction encodings. For example, the encoding of an instruction like LW remains unchanged, but the mode indicates whether the capability authorising the load is the register operand cs1 (Capability Pointer Mode). The mode is shown in the assembly syntax.

The CHERI execution mode is key in providing backwards compatibility with the base RISC-V ISA. RISC-V software is able to execute unchanged in implementations supporting both Zcheripurecap and Zcherihybrid provided that the Infinite capability is installed in ddc and pcc (with M=1, i.e. in Integer Pointer Mode). Setting both registers to Infinite ensures that:

All permissions are granted
The bounds authorise accesses to the entire address space i.e base is 0 and top is 2^MXLEN

5.2. CHERI Execution Mode Encoding

Zcherihybrid adds a new CHERI execution Mode field (M) to the capability format, which is only valid for code capabilities, i.e. when the X-permission is set.

When MXLEN=32, the Mode is encoded in bit 0 of quadrant 1 from the AP field even though it is not a permission as shown in Table 3.
- Only quadrant 1 represents executable capabilities, and so it’s the only one which encodes the Mode.
When MXLEN=64, the Mode is encoded separately; a new M-bit field is added to the capability format as shown in Table 4. The M-bit is only valid for code capabilities, otherwise the field is reserved.

Mode is encoded with permissions for MXLEN=32, but is not a permission. It is orthogonal to permissions as it can vary arbitrarily using SCMODE.

In both encodings:

Mode (M)=0 indicates Capability Pointer Mode.
Mode (M)=1 indicates Integer Pointer Mode.

The current CHERI execution mode is given by the M-bit of the pcc and the CHERI register access settings as follows:

The Mode is Capability Pointer Mode when the M-bit of the pcc is 0, and CHERI register access is enabled for the current privilege.
Otherwise the Mode is Integer Pointer Mode.

When the M-bit can be set, the rules defined by ACPERM must be followed.

5.2.1. Observing the CHERI Execution Mode

The effective CHERI execution mode is given by the values of some CSRs and the M-bit from the PCC. The following code sequences demonstrate how a program can observe the current, effective CHERI execution mode depending on the machine’s privilege mode.

In debug mode, the following sequence executed from the program buffer will write 0 for Capability Pointer Mode and 1 for Integer Pointer Mode to x1:

csrr  c1, dinfc
gctag x1, c1

In any other privilege mode, the following sequence will write 0 for Capability Pointer Mode and 1 for Integer Pointer Mode to x1:

auipc c1, 0
gctag x1, c1

5.3. Zcherihybrid Instructions

Zcherihybrid introduces a small number of new mode-switching and capability manipulation instructions to the base RISC-V integer ISA, as shown in Table 39. Additionally, the behavior of some existing instructions changes depending on the current CHERI execution mode.

5.3.1. Capability Load and Store Instructions

The load and store capability instructions change behaviour depending on the CHERI execution mode although the instruction’s encoding remains unchanged.

The load capability instruction is LC. When the CHERI execution mode is Capability Pointer Mode; the instruction behaves as described in Section 3.3. In Integer Pointer Mode, the capability authorising the memory access is ddc, so the effective address is obtained by adding the x register to the sign-extended offset.

The store capability instruction is SC. When the CHERI execution mode is Capability Pointer Mode; the instruction behaves as described in Section 3.3. In Integer Pointer Mode, the capability authorising the memory access is ddc, so the effective address is obtained by adding the x register to the sign-extended offset.

5.3.2. Capability Manipulation Instructions

A new SCMODE instruction allows setting a capability’s CHERI execution mode to the indicated value. The output is written to an unprivileged c register, not pcc.

A new GCMODE instruction allows decoding the CHERI execution mode from an arbitrary capability held in an x register. The output is written to an unprivileged x register.

5.3.3. Mode Change Instructions

A new CHERI execution mode switch (MODESW) instruction allows software to toggle the hart’s current CHERI execution mode. If the current mode in the pcc is Integer Pointer Mode, then the mode after executing MODESW is Capability Pointer Mode and vice-versa. This instruction effectively writes the CHERI execution mode bit M of the capability currently installed in the pcc.

5.4. Existing RISC-V Instructions

The CHERI execution mode introduced in Zcherihybrid affects the behaviour of instructions that have at least one memory address operand. When in Capability Pointer Mode, the address input or output operands may include c registers. When in Integer Pointer Mode, the address input or output operands are x/f/v registers; the tag and metadata of that register are implicitly set to 0.

5.4.1. Control Transfer Instructions

The unconditional jump instructions change behaviour depending on the CHERI execution mode although the instruction’s encoding remains unchanged.

The jump and link instruction JAL when the CHERI execution mode is Capability; behaves as described in Section 3.4. When the mode is Integer Pointer Mode. In this case, the address of the instruction following the jump (pc + 4) is written to an x register; that register’s tag and capability metadata are zeroed.

The jump and link register instruction is JALR when the CHERI execution mode is Capability Pointer Mode; behaves as described in Section 3.4. When the mode is Integer Pointer Mode. In this case, the target address is obtained by adding the sign-extended 12-bit immediate to the x register operand, then setting the least significant bit of the result to zero. The target address is then written to the pcc address and a representability check is performed. The address of the instruction following the jump (pc + 4) is written to an x register; that register’s tag and capability metadata are zeroed.

Zcherihybrid allows changing the current CHERI execution mode when executing JALR from Capability Pointer Mode.

JAL and JALR cause CHERI exceptions when a minimum sized instruction at the target address is not within the bounds of the pcc. An instruction address misaligned exception is raised when the target address is misaligned.

5.4.2. Conditional Branches

The behaviour is as shown in Section 3.4.2.2.

5.4.3. Load and Store Instructions

Load and store instructions change behavior depending on the CHERI execution mode although the instruction’s encoding remains unchanged.

Loads and stores behave as described in Section 3.4 when in Capability Pointer Mode. In Integer Pointer Mode, the instructions behave as described in the RISC-V base ISA and rely on x operands only. The capability authorising the memory access is ddc and the memory address is given by sign-extending the 12-bit immediate offset and adding it to the base address in the x register operand.

The exception cases remain as described in Section 3.4 regardless of the CHERI execution mode.

5.4.4. CSR Instructions

Zcherihybrid adds the concept of CSRs which contain a capability where the address field is visible in Integer Pointer Mode (e.g. mtvec) and the full capability is visible in Capability Pointer Mode through a different name (e.g. mtvecc). These are referred to as extended CSRs. Also, Zcherihybrid adds the new capability CSRs listed in Table 25.

Extended CSRs have only one address; the access width is determined by the execution mode.

When CSRRW is executed on an extended CSR in Integer Pointer Mode:

The register operand is an x register.
Only XLEN bits from the x source are written to the capability address field.
- The tag and metadata are updated as specified in Table 44.
Only XLEN bits are read from the capability address field, which are extended to MXLEN bits according to (RISC-V, 2023) (3.1.6.2. Base ISA Control in mstatus Register) and are then written to the destination x register.

When CSRRW is executed on an extended CSR in Capability Pointer Mode, or on a new capability CSR regardless of the CHERI execution mode:

The register operand is a c register.
The full capability in the c register source is written to the CSR.
- The capability may require modification before the final written value is determined (see Table 44).
The full capability is written to destination c register.

When an extended CSR or a new capability CSR is used with another CSR instruction (CSRRWI, CSRRC, CSRRCI, CSRRS, CSRRSI):

The final address is calculated according to the standard RISC-V CSR rules (set bits, clear bits etc).
The final address is updated as specified in Table 44 for an XLEN write.
When accessing an extended CSR:
- In Integer Pointer Mode, XLEN bits are read from the capability address field and written to an output x register.
- In Capability Pointer Mode, CLEN bits are read from the CSR and written to an output c register.
When accessing a new capability CSR:
- CLEN bits are read from the CSR and written to an output c register.

All CSR instructions cause CHERI exceptions if the pcc does not grant ASR-permission and the CSR accessed is not user-mode accessible.

5.5. Integrating Zcherihybrid with Sdext

A new debug default data capability (dddc) CSR is added at the CSR number shown in Table 25.

Zcherihybrid optionally allows MODESW to execute in debug mode.

When entering debug mode, the core always enters Capability Pointer Mode. Implementations may optionally support switching CHERI execution mode by executing the MODESW from the program buffer.

5.6. Debug Default Data Capability (dddc)

dddc is a register that is able to hold a capability. The address is shown in Table 25.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Figure 32. Debug default data capability

Upon entry to debug mode, ddc is saved in dddc. ddc's metadata is set to the Infinite capability’s metadata (with tag set) and ddc's address remains unchanged.

When debug mode is exited by executing DRET, the hart’s ddc is updated to the capability stored in dddc. A debugger may write dddc to change the hart’s context.

As shown in Table 46, dddc is a data pointer, so it does not need to be able to hold all possible invalid addresses.

5.7. Disabling CHERI Registers

Zcherihybrid includes functions to disable explicit access to CHERI registers. The following occurs when executing code in a privilege mode that has CHERI register access disabled:

The CHERI instructions in Section 3.3 and Section 9.5 cause illegal instruction exceptions
Executing CSR instructions accessing any CSR added by Zcherihybrid (see Table 25) causes an illegal instruction exception
Executing CSR instructions accessing any extended CSR (see Section 3.6) only allows XLEN access.
All allowed instructions execute as if the CHERI execution mode is Integer Pointer Mode. The mode bit in pcc is treated as if it was zero while CHERI register access is disabled.

CHERI register access is disabled if

XLEN in the current mode is less than MXLEN, or
the endianness in the current mode is not the reset value of mstatus.MBE, or
the effective CRE for the current privilege is 0.

The effective CRE for the current privilege is:

Machine: mseccfg.CRE
Supervisor: mseccfg.CRE & menvcfg.CRE
User: mseccfg.CRE & menvcfg.CRE & senvcfg.CRE

The effective CRE is always 1 in debug mode.

Disabling CHERI register access has no effect on implicit accesses or security checks. The last capability installed in pcc and ddc before disabling CHERI register access will be used to authorise instruction execution and data memory accesses.

Disabling CHERI register access prevents low-privileged Integer Pointer Mode software from interfering with the correct operation of higher-privileged Integer Pointer Mode software that do not perform ddc switches on trap entry and return.

5.8. Added CLEN-wide CSRs

Zcherihybrid adds the CLEN-wide CSRs shown in Table 25.

Table 25. CLEN-wide CSRs added in Zcherihybrid
CLEN CSR	Address	Prerequisites	Permissions	Description
dddc	0x7bc	Zcherihybrid, Sdext	DRW	Debug Default Data Capability (saved/restored on debug mode entry/exit)
mtdc	0x74c	Zcherihybrid, M-mode	MRW, ASR-permission	Machine Trap Data Capability (scratch register)
stdc	0x163	Zcherihybrid, S-mode	SRW, ASR-permission	Supervisor Trap Data Capability (scratch register)
vstdc	0x245	Zcherihybrid, H	HRW, ASR-permission	Virtual Supervisor Trap Data Capability (scratch register)
ddc	0x416	Zcherihybrid	URW	User Default Data Capability

5.8.1. Machine Status Registers (mstatus and mstatush)

Zcherihybrid eliminates some restrictions for SXL and UXL imposed in Zcheripurecap to allow implementations supporting multiple base ISAs. Namely, the SXL and UXL fields may be writable.

Setting the SXL or UXL field to a value that is not MXLEN disables most CHERI features and instructions, as described in Section 5.7, while in that privilege mode.

If CHERI register access must be disabled in a mode for security reasons, software should set CRE to 0 regardless of the SXL and UXL fields.

Whenever XLEN in any mode is set to a value less than MXLEN, standard RISC-V rules from (RISC-V, 2023) are followed. This means that all operations must ignore source operand register bits above the configured XLEN, and must sign-extend results to fill all MXLEN bits in the destination register. Similarly, pc bits above XLEN are ignored, and when the pc is written, it is sign-extended to fill MXLEN. The integer writing rule from CHERI is followed, so that every register write also zeroes the metadata and tag of the destination register.

However, CHERI operations and security checks will continue using the entire hardware register (i.e. CLEN bits) to correctly decode capability bounds.

Zcherihybrid eliminates some restrictions for MBE, SBE, and UBE imposed in Zcheripurecap to allow implementations supporting multiple endiannesses. Namely, the MBE, SBE, and UBE fields may be writable if the corresponding privilege mode is implemented.

Setting the MBE, SBE, or UBE field to a value that is not the reset value of MBE disables most CHERI features and instructions, as described in Section 5.7, while in that privilege mode.

5.8.2. Machine Trap Default Capability Register (mtdc)

The mtdc register is a capability width read/write register dedicated for use by machine mode. Typically, it is used to hold a data capability to a machine-mode hart-local context space, to load into ddc.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Access to this CSR is illegal if CHERI register access is disabled for the current privilege.

Figure 33. Machine-mode trap data capability register

5.8.3. Machine Security Configuration Register (mseccfg)

Zcherihybrid adds a new enable bit to mseccfg as shown in Figure 34.

Figure 34. Machine security configuration register (mseccfg)

The CHERI Register Enable (CRE) bit controls whether M-mode and lower privilege levels have access to capability registers and instructions. When mseccfg.CRE=1, all CHERI instructions and registers can be accessed. When mseccfg.CRE=0, CHERI register and instruction access is prohibited for M-mode and lower privilege levels as described in Section 5.7.

The reset value is 0.

5.8.4. Machine Environment Configuration Register (menvcfg)

Zcherihybrid adds a new enable bit to menvcfg as shown in Figure 35.

Figure 35. Machine environment configuration register (menvcfg)

The CHERI Register Enable (CRE) bit controls whether less privileged levels can perform explicit accesses to CHERI registers. When menvcfg.CRE=1 and mseccfg.CRE=1, CHERI registers can be read and written by less privileged levels. When menvcfg.CRE=0, CHERI registers are disabled in less privileged levels as described in Section 5.7.

The reset value is 0.

5.8.5. Supervisor Trap Default Capability Register (stdc)

The stdc register is a capability width read/write register dedicated for use by supervisor mode. Typically, it is used to hold a data capability to a supervisor-mode hart-local context space, to load into ddc.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Access to this CSR is illegal if CHERI register access is disabled for the current privilege.

Figure 36. Supervisor trap data capability register (stdc)

5.8.6. Supervisor Environment Configuration Register (senvcfg)

The senvcfg register operates as described in the RISC-V Privileged Specification. Zcherihybrid adds a new enable bit as shown in Figure 37.

Figure 37. Supervisor environment configuration register (senvcfg)

The CHERI Register Enable (CRE) bit controls whether U-mode can perform explicit accesses to CHERI registers. When senvcfg.CRE=1 and menvcfg.CRE=1 and mseccfg.CRE=1 CHERI registers can be read and written by U-mode. When senvcfg.CRE=0, CHERI registers are disabled in U-mode as described in Section 5.7.

The reset value is 0.

5.8.7. Default Data Capability (ddc)

The ddc CSR is a read-write capability register implicitly used as an operand to authorise all data memory accesses when the current CHERI mode is Integer Pointer Mode. This register must be readable in any implementation. Its reset value is the Infinite capability.

Access to this CSR is illegal if CHERI register access is disabled for the current privilege.

CRE is not required for the implicit access required by checking memory accesses against ddc

As shown in Table 46, ddc is a data pointer, so it does not need to be able to hold all possible invalid addresses.

Figure 38. Unprivileged default data capability register

6. Integrating Zcheripurecap and Zcherihybrid with the Hypervisor Extension

The RISC-V hypervisor (H) extension virtualizes the supervisor-level architecture to support the efficient hosting of guest operating systems atop a type-1 or type-2 hypervisor (RISC-V, 2023). The hypervisor extension is generally orthogonal to CHERI; the main requirements, when integrating with Zcheripurecap and Zcherihybrid, is that address CSRs added for hypervisors are extended to CLEN size so that they are able to hold capabilities. The remainder of this chapter describes these changes in detail.

6.1. Hypervisor Status Register (hstatus)

The hstatus register operates as described in (RISC-V, 2023) except for the VSXL field that controls the value of XLEN for VS-mode (known as VSXLEN).

The encoding of the VSXL field is the same as the MXL field of misa. Only 1 and 2 are supported values for VSXL. When the implementation supports Zcheripurecap (but not Zcherihybrid), then hstatus's VSXL must be read-only as described in mstatus for mstatus.SXL. When the implementation supports both Zcheripurecap and Zcherihybrid, then VSXL behaves as described in Section 5.8.1 for mstatus.SXL.

The VSBE field determines controls the endianness of explicit memory accesses from VS-mode and implicit memory accesses to VS-level memory management data structures. VSBE=0 indicates little endian and VSBE=1 is big endian. VSBE must be read-only and equal to MBE when the implementation only supports Zcheripurecap. VSBE is optionally writeable when Zcherihybrid is also supported.

6.2. Hypervisor Environment Configuration Register (henvcfg)

The henvcfg register operates as described in the RISC-V Privileged Specification. A new enable bit is added to henvcfg when the implementation supports Zcherihybrid as shown in Figure 39.

Figure 39. Hypervisor environment configuration register (henvcfg)

The CHERI Register Enable (CRE) bit controls whether explicit access to CHERI registers is permitted when V=1. When henvcfg.CRE=1 and menvcfg.CRE=1 and mseccfg.CRE=1, CHERI registers can be read and written by VS-mode and VU-mode. When henvcfg.CRE=0, CHERI registers are disabled in VS-mode and VU-mode as described in Section 5.7.

The reset value is 0.

6.3. Hypervisor Trap Value Register (htval)

The htval register operates as described in (RISC-V, 2023). Additionally, htval may be written with the exception codes described in mtval when a CHERI exception occurs.

Figure 40. Hypervisor trap value register

6.4. Virtual Supervisor Status Register (vsstatus)

The vsstatus register operates as described in (RISC-V, 2023) except for the UXL field that controls the value of XLEN for VU-mode.

The encoding of the UXL field is the same as the MXL field of misa. Only 1 and 2 are supported values for UXL. When the implementation supports Zcheripurecap (but not Zcherihybrid), then vsstatus.UXL must be read-only as described in mstatus for mstatus.UXL. When the implementation supports both Zcheripurecap and Zcherihybrid, then UXL behaves as described in Section 5.8.1 for mstatus.UXL.

6.5. Virtual Supervisor Trap Vector Base Address Register (vstvec)

The vstvec register is as defined in (RISC-V, 2023). It is the VSXLEN-bit read/write register that is the VS mode’s version of the supervisor register stvec.

Figure 41. Virtual supervisor trap vector base address register

6.6. Virtual Supervisor Trap Vector Base Address Capability Register (vstvecc)

The vstvecc register is a renamed extension of vstvec that is able to hold a capability. Its reset value is the Infinite capability.

Figure 42. Virtual supervisor trap vector base address capability register

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

6.7. Virtual Supervisor Scratch Register (vsscratch)

The vsscratch register is as defined in (RISC-V, 2023). It is a VSXLEN read/write register that is VS-mode’s version of supervisor register sscratch. vsscratch is extended into vsscratchc.

Figure 43. Virtual supervisor scratch register

6.8. Virtual Supervisor Scratch Register (vsscratchc)

The vsscratchc register is a renamed version of vsscratch that is able to hold a capability.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

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

Figure 44. Virtual supervisor scratch capability register

6.9. Virtual Supervisor Exception Program Counter (vsepc)

The vsepc register is as defined in (RISC-V, 2023). It is extended into vsepcc.

Figure 45. Virtual supervisor exception program counter

6.10. Virtual Supervisor Exception Program Counter Capability (vsepcc)

The vsepcc register is a renamed extension of vsepc that is able to hold a capability. Its reset value is the Infinite capability.

As shown in Table 46, vsepcc is an executable vector, so it need not be able to hold all possible invalid addresses. Additionally, the capability in vsepcc is unsealed when it is installed in pcc on execute of an SRET instruction. The handling of vsepcc is otherwise identical to mepcc, but in virtual supervisor mode.

Figure 46. Virtual supervisor exception program counter capability

6.11. Virtual Supervisor Cause Register (vscause)

The vscause register is as defined in (RISC-V, 2023). It must additionally support the new exception code for CHERI exceptions that scause supports.

6.12. Virtual Supervisor Trap Default Capability Register (vstdc)

The vstdc register is a capability width read/write register that is VS-mode’s version of supervisor register stdc. This register is only present when the implementation supports Zcherihybrid.

The tag of the CSR must be reset to zero. The reset values of the metadata and address fields are UNSPECIFIED.

Access to this CSR is illegal if CHERI register access is disabled for the current privilege.

Figure 47. Virtual supervisor trap default capability register

6.13. Existing Hypervisor Load and Store Instructions

The hypervisor extension defines several integer load and store instructions (such as HLV.W, HSV.W and HLVX.WU) that transfer the amount of integer data described in (RISC-V, 2023) between the registers and memory as though V=1. These instructions change behaviour depending on the CHERI execution mode although the instruction’s encoding remains unchanged.

When in Capability Pointer Mode, the hypervisor load and store instructions behave as described in Section 3.4. In Integer Pointer Mode, the instructions behave as described in (RISC-V, 2023) and rely on an x register operand providing the effective address for the memory access; the capability authorising the memory access is ddc.

The exception cases remain as described in Section 3.4 regardless of the CHERI execution mode.

6.14. Hypervisor Load and Store Capability Instructions

Hypervisor virtual-machine load (HLV.C) and store (HSV.C) capability instructions read or write CLEN bits from memory as though V=1. These instructions change behaviour depending on the CHERI execution mode although the instruction’s encoding remains unchanged.

When in Capability Pointer Mode, the hypervisor load and store capability instructions behave as described in Section 3.4. In Integer Pointer Mode, the instructions behave as rely on an x register operand providing the effective address for the memory access and the capability authorising the memory access is ddc.

7. "Zstid" Extension for Thread Identification

Zstid is an optional extension to the RISC-V base ISA. Implementations that support Zcheripurecap and Zstid define a variant of the CHERI ISA that allows for more efficient software compartmentalization of CHERI programs.

7.1. Control and Status Registers (CSRs)

Zstid adds two new CSRs to implement a trusted thread identifier (TID) used in compartmentalization. These CSRs are listed in Table 26, Table 27, Table 28 and Table 29.

Table 26. Added machine-mode CSRs in Zstid
Zstid CSR	Address	Prerequisites	Read-Permission	Write-Permission	Description
mtid	0x780	M-mode	M	M, ASR-permission	Machine Thread Identifier

Table 27. Added supervisor-mode CSRs in Zstid
Zstid CSR	Address	Prerequisites	Read-Permission	Write-Permission	Description
stid	0x580	S-mode	S	S, ASR-permission	Supervisor Thread Identifier

Table 28. Added virtual supervisor-mode CSRs in Zstid
Zstid CSR	Address	Prerequisites	Read-Permission	Write-Permission	Description
vstid	0xA80	VS-mode	S	H, ASR-permission	Virtual Supervisor Thread Identifier

Table 29. Added user-mode CSRs in Zstid
Zstid CSR	Address	Prerequisites	Read-Permission	Write-Permission	Description
utid	0x480	U-mode	U	U, ASR-permission	User Thread Identifier

7.2. Machine-Level, Supervisor-Level and Unprivileged CSRs

7.2.1. Machine Thread Identifier (mtid)

The mtid register is an MXLEN-bit read-write register. It is used to identify the current thread in machine mode. The reset value of this register is UNSPECIFIED.

Figure 48. Supervisor thread identifier register

7.2.2. Supervisor Thread Identifier (stid)

The stid register is an SXLEN-bit read-write register. It is used to identify the current thread in supervisor mode. The reset value of this register is UNSPECIFIED.

Figure 49. Supervisor thread identifier register

7.2.3. Virtual Supervisor Thread Identifier (vstid)

The vstid register is a VSLEN-bit read-write register. It is used to identify the current thread in virtual supervisor mode. The reset value of this register is UNSPECIFIED.

Figure 50. Virtual supervisor thread identifier register

7.2.4. User Thread Identifier (utid)

The utid register is an UXLEN-bit read-write register. It is used to identify the current thread in user mode. The reset value of this register is UNSPECIFIED.

Figure 51. User thread identifier register

When Zcheripurecap is implemented, the Zstid CSRs are extended as follows:

7.2.5. Machine Thread Identifier Capability (mtidc)

The mtidc register is an CLEN-bit read-write capability register. It is the capability extension of the mtid register. It is used to identify the current thread in machine mode. On reset the tag of mtidc will be set to 0 and the remainder of the data is UNSPECIFIED.

Figure 52. Machine thread identifier capability register

7.2.6. Supervisor Thread Identifier Capability (stidc)

The stidc register is an CLEN-bit read-write capability register. It is the capability extension of the stid register. It is used to identify the current thread in supervisor mode. On reset the tag of stidc will be set to 0 and the remainder of the data is UNSPECIFIED.

Figure 53. Supervisor thread identifier capability register

7.2.7. Virtual Supervisor Thread Identifier Capability (vstidc)

The vstidc register is a CLEN-bit read-write capability register. It is the capability extension of the vstid register. It is used to identify the current thread in virtual supervisor mode. On reset the tag of vstidc will be set to 0 and the remainder of the data is UNSPECIFIED.

Figure 54. Virtual supervisor thread identifier capability register

7.2.8. User Thread Identifier Capability (utidc)

The utidc register is an CLEN-bit read-write capability register. It is the capability extension of the utid register. It is used to identify the current thread in user mode. On reset the tag of utidc will be set to 0 and the remainder of the data is UNSPECIFIED.

Figure 55. User thread identifier capability register

7.3. "Smstateen/Ssstateen" Integration

The TID bit controls access to the CSRs in Table 27, Table 28 and Table 29 provided by the Zstid extension.

Figure 56. Machine State Enable 0 Register (mstateen0)

Figure 57. Hypervisor State Enable 0 Register (hstateen0)

Figure 58. Supervisor State Enable 0 Register (sstateen0)

7.4. CHERI Compartmentalization

This section describes how this specification enables support for compartmentalization for CHERI systems. Compartmentalization seeks to separate the privileges between different protection units, e.g., two or more libraries. Code can be separated by sentries, which allow for giving out code capabilities to untrusted code where the untrusted code can only call the code capability, but not modify it. Sentries can be called from different threads and thus there needs to be a way of identifying the current thread. While identifying the current thread can be done by privileged code, e.g., the kernel, the implied performance overhead of this is not bearable for CHERI systems with many compartments.

The RISC-V ABI includes a thread pointer (tp) register, which is not usable for the purpose of reliably identifying the current thread because the tp register is a general purpose register and can be changed arbitrarily by untrusted code. Therefore, this specification offers three additional CSRs that facilitate a trusted source for the thread ID. All registers are readable from their respective privilege levels and writeable with ASR-permission.

This extension extends mtid, stid, vstid and utid to their respective capability variants mtidc, stidc, vstidc and utidc. This presents software with the freedom to still use these registers with capabilities or leave the metadata untouched and only use the registers to storage integers.

8. RISC-V Instructions and Extensions Reference

These instruction pages are for the new CHERI instructions, and some existing RISC-V instructions where the effect of CHERI needs specific details.

For existing RISC-V instructions, note that:

In Integer Pointer Mode, every byte of each memory access is bounds checked against ddc
In Integer Pointer Mode, a minimum length instruction at the target of all indirect jumps is bounds checked against pcc
In Capability Pointer Mode a minimum length instruction at the target of all indirect jumps is bounds checked against cs1 (e.g. JALR)
A minimum length instruction at the taken target of all direct jumps and conditional branches is bounds checked against pcc regardless of CHERI execution mode

Not all RISC-V extensions have been checked against CHERI. Compatible extensions will eventually be listed in a CHERI profile.

8.1. "Zcheripurecap" and "Zcherihybrid" Extensions for CHERI

8.1.1. CMV

Synopsis: Capability move
Mnemonic: cmv cd, cs1
Suggested assembly syntax: mv cd, cs1

the suggested assembly syntax distinguishes from integer mv by operand type.

Encoding

CMV is encoded as CADD with rs2=x0.

Description: The contents of capability register cs1 are written to capability register cd. CMV unconditionally moves the whole capability to cd .

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.2. MODESW

Synopsis: Switch CHERI execution mode
Mnemonic: modesw
Encoding

Description

Toggle the hart’s current CHERI execution mode in pcc.

If the current mode in pcc is Integer Pointer Mode (1), then the M-bit in pcc is set to Capability Pointer Mode (0).
If the current mode is Capability Pointer Mode (0), then the M-bit in pcc is set to Integer Pointer Mode (1).

The effective CHERI exection mode is give by the value of some CSRs and the pcc's M-bit, so executing MODESW does not necessarily change the machine’s current mode. The current, effective CHERI execution mode can be observed as described in Observing the CHERI Execution Mode.

Implementations may optionally support executing C.MODESW from the program buffer while in debug mode.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcherihybrid
Operation

TODO

8.1.3. CADDI

See CADD.

8.1.4. CADD

Synopsis: Capability pointer increment
Mnemonic: cadd cd, cs1, rs2
caddi cd, cs1, imm
Suggested assembly syntax: add cd, cs1, rs2
add cd, cs1, imm

the suggested assembly syntax distinguishes from integer add by operand type.

Encoding

CADD with rs2=x0 is decoded as CMV instead, the key difference being that tagged capabilities cannot have their tag cleared by CMV.

Description: Increment the address field of the capability cs1 and write the result to cd . The tag bit of the output capability is 0 if cs1 did not have its tag set to 1, the incremented address is outside cs1 's Representable Range or cs1 is sealed.

For CADD, the address is incremented by the value in rs2 .
For CADDI, the address is incremented by the immediate value imm.

This instruction sets cd.tag=0 if cs1 's bounds are malformed, or if any of the reserved fields are set.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation (CADD): TODO
Operation (CADDI): TODO

8.1.5. SCADDR

Synopsis: Capability set address
Mnemonic: scaddr cd, cs1, rs2
Encoding

Description: Set the address field of capability cs1 to rs2 and write the output capability to cd. The tag bit of the output capability is 0 if cs1 did not have its tag set to 1, rs2 is outside the Representable Range of cs1 or if cs1 is sealed.

This instruction sets cd.tag=0 if cs1 's bounds are malformed, or if any of the reserved fields are set.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.6. ACPERM

Synopsis: Mask capability permissions
Mnemonics: acperm cd, cs1, rs2
Encoding

Description

ACPERM performs the following operations:

Convert the AP and SDP fields of capability cs1 into the format shown above
1. SDPLEN is defined in Table 5
Calculate the bitwise AND of the bit field with the mask rs2.
If the AP and M-bit field in cs1 could not have been produced by ACPERM then clear all AP permissions and the M-bit, and skip the next step
Clear AP permissions as required to meet the rules below.
Encode the AP permissions for MXLEN=32 according to Table 3.
Copy cs1 to cd, and update the AP and SDP fields with the newly calculated versions.
Set cd.tag=0 if cs1 is sealed or if any reserved fields of cs1 are set.

Some combinations of permissions cannot be encoded for MXLEN=32, and are not useful when MXLEN=64. These cases are defined to return useful minimal sets of permissions, which may be no permissions.

Future extensions may allow more combinations of permissions, especially for MXLEN=64.

The common rules are:

ASR-permission cannot be set without X-permission being set
1. Clear ASR-permission unless X-permission is set
C-permission cannot be set without at least one of R-permission or W-permission being set.
1. Clear C-permission unless R-permission or W-permission are set.
M-bit cannot be set without X-permission being set
1. Clear M-bit unless X-permission is set
LM-permission cannot be set without C-permission being set
1. Clear LM-permission unless C-permission is set.

The combination of X-permission clear and M-bit set is reserved for future extensions.

The MXLEN=32 additional rules are:

Clear ASR-permission unless all other permissions are set
Clear C-permission and X-permission if R-permission is not set
Clear W-permission if C-permission is set, but LM-permission is not set.
Clear X-permission if X-permission and R-permission are set, but C-permission and W-permission are not set.

Exceptions

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites

Zcheripurecap

Operation

TODO: Sail does not have the new encoding of the permissions field.

8.1.7. SCMODE

Synopsis: Capability set CHERI execution mode
Mnemonic: scmode cd, cs1, rs2
Encoding

Description

Copy cs1 to cd. Clear cd.tag if cs1 is sealed. Update the M-bit of cd to the least significant bit of rs2 if the two following conditions are met, otherwise do not update it:

X-permission is set
The existing permissions can be produced by ACPERM

Exceptions

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites

Zcherihybrid

Operation

TODO

8.1.8. SCHI

Synopsis: Capability set metadata
Mnemonic: schi cd, cs1, rs2
Encoding

Description: Copy cs1 to cd , replace the capability metadata (i.e. bits [CLEN-1:MXLEN]) with rs2 and set cd.tag to 0.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.9. SCEQ

Synopsis: Set if Capabilities are EQual
Mnemonic: sceq rd, cs1, cs2
Encoding

Description: rd is set to 1 if all bits (i.e. CLEN bits and the tag) of capabilities cs1 and cs2 are equal, otherwise rd is set to 0.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.10. SENTRY

Synopsis: Seal capability as sealed entry.
Mnemonic: sentry cd, cs1
Encoding

Description: Capability cd is written with the capability in cs1 with its type bit set to 1. Attempting to seal an already sealed capability will lead to the tag of cd being set to 0.

The SENTRY instruction may give rise to an illegal instruction fault when the implementation does not support capability type 1 (unrestricted sentry; see Section 2.2.5). This is not the case when the implementation supports the capability encoding described in Chapter 2.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.11. SCSS

Synopsis: Capability test subset
Mnemonic: scss rd, cs1, cs2
Encoding

Description: rd is set to 1 if the tag of capabilities cs1 and cs2 are equal and the bounds and permissions of cs2 are a subset of those of cs1.

If either cs1 or cs2:

Have bounds which are malformed, or
Have any bits set in reserved fields, or
Have permissions that could not have been legally produced by ACPERM

then the instruction returns zero.

The implementation of this instruction is similar to CBLD, although SCSS does not include the sealed bit in the check.

Prerequisites: Zcheripurecap
Operation: TODO

8.1.12. CBLD

Synopsis: Capability build
Mnemonic: cbld cd, cs1, cs2
Encoding

Description

Copy cs2 to cd and set cd.tag to 1 if

cs1.tag is set, and
cs1 's bounds are not malformed, and all reserved fields are zero, and
cs1 's permissions could have been legally produced by ACPERM, and
cs1 is not sealed, and
cs2 's permissions and bounds are equal to or a subset of cs1 's, and
cs2 's bounds are not malformed, and all reserved fields are zero, and
cs2 's permissions could have been legally produced by ACPERM, and
All reserved bits in cs2 's metadata are 0;

Otherwise, copy cs2 to cd and clear cd 's tag.

CBLD is typically used alongside SCHI to build capabilities from integer values.

When cs1 is c0 this will copy cs2 to cd and clear cd.tag. However this may change in future extensions, and so software should not assume cs1==0 to be a pseudo instruction for tag clearing.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Simplified Operation TODO not debugged much easier to read than the existing SAIL

let cs1_val = C(cs1);
let cs2_val = C(cs2) [with tag=1];
//isCapSubset includes derivability checks on both operands
let subset  = isCapSubset(cs1_val, cs2_val);
//Clear cd.tag if cs2 isn't a subset of cs1, or if
//cs1 is untagged or sealed, or if either is underivable
C(cd)       = clearTagIf(cs2_val, not(subset) |
                                  not(cs1_val.tag) |
                                  isCapSealed(cs1_val));
RETIRE_SUCCESS

Operation: TODO: Original Sail looks at otype field, etc that don’t exist

8.1.13. GCTAG

Synopsis: Capability get tag
Mnemonic: gctag rd, cs1
Encoding

Description: Zero extend the value of cs1.tag and write the result to rd.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.14. GCPERM

Synopsis: Capability get permissions
Mnemonic: gcperm rd, cs1
Encoding

Description: If MXLEN=32 unpack permissions from the format in Table 3.

Convert the unpacked AP permissions, and the SDP fields of capability cs1 into a bit field, as shown below, and write the result to rd. A bit set to 1 in the bit field indicates that cs1 grants the corresponding permission.

If the AP field cannot be produced by ACPERM then all architectural permission bits in rd are set to 0.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO: The encoding of permissions changed.

8.1.15. GCHI

Synopsis: Capability get metadata
Mnemonic: gchi rd, cs1
Encoding

Description: Copy the metadata (bits [CLEN-1:MXLEN]) of capability cs1 into rd.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.16. GCBASE

Synopsis: Capability get base address
Mnemonic: gcbase rd, cs1
Encoding

Description: Decode the base integer address from cs1 's bounds and write the result to rd. It is not required that the input capability cs1 has its tag set to 1.

If cs1 's bounds are malformed then the bounds decode as zero, which causes this instruction to return zero.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.17. GCLEN

Synopsis: Capability get length
Mnemonic: gclen rd, cs1
Encoding

Description: Calculate the length of cs1 's bounds and write the result in rd. The length is defined as the difference between the decoded bounds' top and base addresses i.e. top - base. It is not required that the input capability cs1 has its tag set to 1. GCLEN outputs 0 if cs1 's bounds are malformed (see Section 2.2.6.3), and 2^MXLEN-1 if the length of cs1 is 2^MXLEN.

If cs1 's bounds are malformed then the bounds decode as zero, which causes this instruction to return zero.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.18. GCMODE

Synopsis: Capability get CHERI execution mode
Mnemonic: gcmode rd, cs1
Encoding

Description: Decode the CHERI execution mode from the capability in cs1 and write the result to rd. The output in rd is 0 if the CHERI execution mode of the capability in cs1 is Capability Pointer Mode and 1 if the mode is Integer Pointer Mode. It is not required that cs1 has its tag set to 1.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcherihybrid
Operation

TODO

8.1.19. GCTYPE

Synopsis: Capability get type
Mnemonic: gctype rd, cs1
Encoding

Description: Decode the architectural capability type from cs1 and write the result to rd. It is not required that the input capability cs1 has its tag set to 1.

While the architectural capability type maps directly to the value of the CT capability bit in Zcheripurecap, future extensions may define an alternate mapping. Therefore, software should always use GCTYPE to obtain the capability type rather than directly reading the high bits of the capability using GCHI.

Table 30. Capability types in Zcheripurecap
Type	Hardware interpretation
0	Unsealed capability
1	Sentry capability

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.20. SCBNDSI

See SCBNDS.

8.1.21. SCBNDS

Synopsis: Capability set bounds
Mnemonics: scbnds cd, cs1, rs2
scbndsi cd, cs1, uimm
Encoding

Description: Capability register cd is set to capability register cs1 with the base address of its bounds replaced with the value of cs1.address and the length of its bounds set to rs2 (or imm). If the resulting capability cannot be represented exactly then set cd.tag to 0. In all cases, cd.tag is set to 0 if its bounds exceed cs1 's bounds, cs1 's tag is 0 or cs1 is sealed.

SCBNDSI uses the s bit to scale the immediate by 4 places

immediate = ZeroExtend(s ? uimm<<4 : uimm)

This instruction sets cd.tag=0 if cs1 's bounds are malformed, or if any of the reserved fields are set.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation for SCBNDS: TODO
Operation for SCBNDSI: TODO

8.1.22. SCBNDSR

Synopsis: Capability set bounds, rounding up if necessary
Mnemonic: scbndsr cd, cs1, rs2
Encoding

Description: Capability register cd is set to capability register cs1 with the base address of its bounds replaced with the value of cs1.address field and the length of its bounds set to rs2. The base is rounded down and the length is rounded up by the smallest amount needed to form a representable capability covering the requested bounds. In all cases, cd.tag is set to 0 if its bounds exceed cs1 's bounds, cs1 's tag is 0 or cs1 is sealed.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.

This instruction sets cd.tag=0 if cs1 's bounds are malformed, or if any of the reserved fields are set.

Prerequisites: Zcheripurecap
Operation for SCBNDSR: TODO

8.1.23. CRAM

Synopsis: Get Capability Representable Alignment Mask (CRAM)
Mnemonic: cram rd, rs1
Encoding

Description: Integer register rd is set to a mask that can be used to round addresses down to a value that is sufficiently aligned to set exact bounds for the nearest representable length of rs1.
Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: Zcheripurecap
Operation: TODO

8.1.24. LC

The RV64 encoding is intended to also allocate the encoding for LQ for RV128.

Synopsis: Load capability
Capability Pointer Mode Mnemonic: lc cd, offset(cs1)
Integer Pointer Mode Mnemonic: lc cd, offset(rs1)

These instructions have different encodings for RV64 and RV32.

Encoding

Capability Pointer Mode Description: Load a CLEN+1 bit value from memory and writes it to cd. The capability in cs1 authorizes the operation. The effective address of the memory access is obtained by adding the address of cs1 to the sign-extended 12-bit offset.
Integer Pointer Mode Description: Loads a CLEN+1 bit value from memory and writes it to cd. The capability authorising the operation is ddc. The effective address of the memory access is obtained by adding rs1 to the sign-extended 12-bit offset.
Resulting value of cd: The tag value written to cd is 0 if the tag of the memory location loaded is 0 or the authorizing capability (ddc or cs1) does not grant C-permission.

If the authorizing capability does not grant LM-permission, and the tag of cd is 1 and cd is not sealed, then an implicit ACPERM clearing W-permission and LM-permission is performed to obtain the final permissions on cd.

Missing LM-permission does not affect untagged values since this could result in surprising bit patterns when copying non-capability data. Similarly, sealed capabilities are not modified as they are not directly dereferenceable.

While the implicit ACPERM introduces a dependency on the loaded data, microarchitectures can avoid this by deferring the actual masking of permissions until the loaded capability is dereferenced or the metadata bits are inspected using GCPERM or GCHI.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions

Misaligned address fault exception when the effective address is not aligned to CLEN/8.

CHERI fault exception when the authorising capability fails one of the checks listed below; in this case, CHERI data fault is reported in the mtval or stval TYPE field and the corresponding code is written to CAUSE.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites for Capability Pointer Mode

Zcheripurecap

Prerequisites for Integer Pointer Mode

Zcherihybrid

LC Operation

TODO

8.1.25. SC

The RV64 encoding is intended to also allocate the encoding for SQ for RV128.

Synopsis: Store capability
Capability Pointer Mode Mnemonic: sc cs2, offset(cs1)
Integer Pointer Mode Mnemonic: sc cs2, offset(rs1)

These instructions have different encodings for RV64 and RV32.

Encoding

Capability Pointer Mode Description: Store the CLEN+1 bit value in cs2 to memory. The capability in cs1 authorizes the operation. The effective address of the memory access is obtained by adding the address of cs1 to the sign-extended 12-bit offset. The capability written to memory has the tag set to 0 if the tag of cs2 is 0 or cs1 does not grant C-permission.
Integer Pointer Mode Description: Store the CLEN+1 bit value in cs2 to memory. The capability authorising the operation is ddc. The effective address of the memory access is obtained by adding rs1 to the sign-extended 12-bit offset. The capability written to memory has the tag set to 0 if cs2 's tag is 0 or ddc does not grant C-permission.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions

Misaligned address fault exception when the effective address is not aligned to CLEN/8.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites for Capability Pointer Mode

Zcheripurecap

Prerequisites for Integer Pointer Mode

Zcherihybrid

SC Operation

TODO

8.2. RV32I/E and RV64I/E Base Integer Instruction Sets

8.2.1. AUIPC

Synopsis: Add upper immediate to pc/pcc
Capability Pointer Mode Mnemonic: auipc cd, imm
Integer Pointer Mode Mnemonic: auipc rd, imm
Encoding

Capability Pointer Mode Description: Form a 32-bit offset from the 20-bit immediate filling the lowest 12 bits with zeros. Increment the address of the AUIPC instruction’s pcc by the 32-bit offset, then write the output capability to cd. The tag bit of the output capability is 0 if the incremented address is outside the pcc's Representable Range.
Integer Pointer Mode Description: Form a 32-bit offset from the immediate, filling in the lowest 12 bits with zeros, adds this offset to the address of the AUIPC instruction, then places the result in register rd.

The instructions on this page are either PC relative or may update the pcc. Therefore an implementation may make them illegal in debug mode. If they are supported then the value of the pcc in debug mode is UNSPECIFIED by this document.

Prerequisites for Capability Pointer Mode: Zcheripurecap
Prerequisites for Integer Pointer Mode: Zcherihybrid
Operation for AUIPC: TODO

8.2.2. BEQ, BNE, BLT[U], BGE[U]

Synopsis: Conditional branches (BEQ, BNE, BLT[U], BGE[U])
Mnemonics: beq rs1, rs2, imm
bne rs1, rs2, imm
blt rs1, rs2, imm
bge rs1, rs2, imm
bltu rs1, rs2, imm
bgeu rs1, rs2, imm
Encoding

Description: Compare two integer registers rs1 and rs2 according to the indicated opcode as described in (RISC-V, 2023). The 12-bit immediate encodes signed offsets in multiples of 2 bytes. The offset is sign-extended and added to the address of the branch instruction to give the target address. Then the target address is written into the address field of pcc.
Exceptions: When the target address is not within the pcc's bounds, and the branch is taken, a CHERI jump or branch fault is reported in the TYPE field and Length Violation is reported in the CAUSE field of mtval or stval:

Operation: TODO

8.2.3. JR

Expands to JALR following the expansion rule from (RISC-V, 2023).

8.2.4. JALR

Synopsis: Jump and link register
Capability Pointer Mode Mnemonic: jalr cd, cs1, offset
Integer Pointer Mode Mnemonic: jalr rd, rs1, offset
Encoding

Capability Pointer Mode Description: JALR allows unconditional, indirect jumps to a target capability. The target capability is unsealed if the offset is zero. The target address is obtained by adding the sign-extended 12-bit offset to cs1.address, then setting the least-significant bit of the result to zero. The target capability may have Invalid address conversion performed and is then installed in pcc. The pcc of the next instruction following the jump is sealed and written to cd.
Integer Pointer Mode Description: JALR allows unconditional, indirect jumps to a target address. The target address is obtained by adding the sign-extended 12-bit immediate to rs1, then setting the least-significant bit of the result to zero. The target address is installed in the address field of the pcc which may require Invalid address conversion. The address of the instruction following the jump is written to rd.
Exceptions: When these instructions cause CHERI exceptions, CHERI jump or branch fault is reported in the TYPE field and the following codes may be reported in the CAUSE field of mtval or stval:

CAUSE Integer Pointer Mode Capability Pointer Mode Reason

Tag violation

✔

cs1 has tag set to 0, or has any reserved bits set

Seal violation

✔

cs1 is sealed and the immediate is not 0

Permission violation

✔

cs1 does not grant X-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

✔

The target address is invalid according to Invalid address conversion

Length violation

✔

Minimum length instruction is not within the target capability’s bounds, which will fail if cs1 has malformed bounds in Capability Pointer Mode.

Prerequisites Capability Pointer Mode: Zcheripurecap
Prerequisites Integer Pointer Mode: Zcherihybrid
Operation: TBD

8.2.5. J

Expands to JAL following the expansion rule from (RISC-V, 2023).

8.2.6. JAL

Synopsis: Jump and link
Capability Pointer Mode Mnemonic: jal cd, offset
Integer Pointer Mode Mnemonic: jal rd, offset
Encoding

Capability Pointer Mode Description: JAL’s immediate encodes a signed offset in multiple of 2 bytes. The pcc is incremented by the sign-extended offset to form the jump target capability. The target capability is written to pcc. The pcc of the next instruction following the jump is sealed and written to cd.
Integer Pointer Mode Description: JAL’s immediate encodes a signed offset in multiple of 2 bytes. The sign-extended offset is added to the pcc's address to form the target address which is written to the pcc's address field. The address of the instruction following the jump is written to rd.
Exceptions

CAUSE

Integer Pointer Mode

Capability Pointer Mode

Reason

Invalid address violation

✔

The target address is invalid according to Invalid address conversion

Length violation

✔

Minimum length instruction is not within the target capability’s bounds.

Prerequisites for Capability Pointer Mode: Zcheripurecap
Prerequisites for Integer Pointer Mode: Zcherihybrid
Operation: TODO

8.2.7. LD

See LB.

8.2.8. LWU

See LB.

8.2.9. LW

See LB.

8.2.10. LHU

See LB.

8.2.11. LH

See LB.

8.2.12. LBU

See LB.

8.2.13. LB

Synopsis: Load (LD, LW[U], LH[U], LB[U])
Capability Pointer Mode Mnemonics (RV64): ld rd, offset(cs1)
lw[u] rd, offset(cs1)
lh[u] rd, offset(cs1)
lb[u] rd, offset(cs1)
Integer Pointer Mode Mnemonics (RV64): ld rd, offset(rs1)
lw[u] rd, offset(rs1)
lh[u] rd, offset(rs1)
lb[u] rd, offset(rs1)
Capability Pointer Mode Mnemonics (RV32): lw rd, offset(cs1)
lh[u] rd, offset(cs1)
lb[u] rd, offset(cs1)
Integer Pointer Mode Mnemonics (RV32): lw rd, offset(rs1)
lh[u] rd, offset(rs1)
lb[u] rd, offset(rs1)
Encoding

Capability Pointer Mode Description

Load integer data of the indicated size (byte, halfword, word, double-word) from memory. The effective address of the load is obtained by adding the sign-extended 12-bit offset to the address of cs1. The authorising capability for the operation is cs1. A copy of the loaded value is written to rd.

Integer Pointer Mode Description

Load integer data of the indicated size (byte, halfword, word, double-word) from memory. The effective address of the load is obtained by adding the sign-extended 12-bit offset to rs1. The authorising capability for the operation is ddc. A copy of the loaded value is written to rd.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode LD

RV64, Zcheripurecap

Prerequisites for Integer Pointer Mode LD

RV64, Zcherihybrid

Prerequisites for Capability Pointer Mode LW[U], LH[U], LB[U]

Zcheripurecap, OR
Zcherihybrid

Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TODO

8.2.14. SD

See SB

8.2.15. SW

See SB

8.2.16. SH

See SB

8.2.17. SB

Synopsis: Stores (SD, SW, SH, SB)
Capability Pointer Mode Mnemonics (RV64): sd rs2, offset(cs1)
sw rs2, offset(cs1)
sh rs2, offset(cs1)
sb rs2, offset(cs1)
Integer Pointer Mode Mnemonics (RV64): sd rs2, offset(rs1)
sw rs2, offset(rs1)
sh rs2, offset(rs1)
sb rs2, offset(rs1)
Capability Pointer Mode Mnemonics (RV32): sw rs2, offset(cs1)
sh rs2, offset(cs1)
sb rs2, offset(cs1)
Integer Pointer Mode Mnemonics (RV32): sw rs2, offset(rs1)
sh rs2, offset(rs1)
sb rs2, offset(rs1)
Encoding

Capability Pointer Mode Description

Store integer data of the indicated size (byte, halfword, word, double-word) to memory. The effective address of the store is obtained by adding the sign-extended 12-bit offset to the address of cs1. The authorising capability for the operation is cs1. A copy of rs2 is written to memory at the location indicated by the effective address and the tag bit of each block of memory naturally aligned to CLEN/8 is cleared.

Integer Pointer Mode Description

Store integer data of the indicated size (byte, halfword, word, double-word) to memory. The effective address of the store is obtained by adding the sign-extended 12-bit offset to rs1. The authorising capability for the operation is ddc. A copy of rs2 is written to memory at the location indicated by the effective address and the tag bit of each block of memory naturally aligned to CLEN/8 is cleared.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode SD

RV64, Zcheripurecap

Prerequisites for Integer Pointer Mode SD

RV64, Zcherihybrid

Prerequisites for Capability Pointer Mode SW, SH, SB

Zcheripurecap

Prerequisites for Integer Pointer Mode SW, SH, SB

Zcherihybrid

Operation

TBD

8.2.18. SRET

See MRET.

8.2.19. MRET

Synopsis: Trap Return (MRET, SRET)
Mnemonics: mret
sret
Encoding

Description: Return from machine mode (MRET) or supervisor mode (SRET) trap handler as defined by (RISC-V, 2023). MRET unseals mepcc and writes the result into pcc. SRET unseals sepcc and writes the result into pcc.
Exceptions: CHERI fault exceptions occur when pcc does not grant ASR-permission because MRET and SRET require access to privileged CSRs. When that exception occurs, CHERI instruction access fault is reported in the TYPE field and the Permission Violation codes is reported in the CAUSE field of mtval or stval.
Operation

TBD

8.2.20. DRET

Synopsis: Debug Return (DRET)
Mnemonic: dret
Encoding

Description: DRET return from debug mode. It unseals dpcc and writes the result into pcc.

The DRET instruction is the recommended way to exit debug mode. However, it is a pseudo instruction to return that technically does not execute from the program buffer or memory. It currently does not require the pcc to grant ASR-permission so it never excepts.

Prerequisites: Sdext
Operation

TBD

8.3. "A" Standard Extension for Atomic Instructions

8.3.1. AMO<OP>.W

See AMO<OP>.D.

8.3.2. AMO<OP>.D

Synopsis: Atomic Operations (AMO<OP>.W, AMO<OP>.D), 32-bit encodings
Capability Pointer Mode Mnemonics (RV64): amo<op>.[w|d] rd, rs2, offset(cs1)
Capability Pointer Mode Mnemonics (RV32): amo<op>.w rd, rs2, offset(cs1)
Integer Pointer Mode Mnemonics (RV64): amo<op>.[w|d] rd, rs2, offset(rs1)
Integer Pointer Mode Mnemonics (RV32): amo<op>.w rd, rs2, offset(rs1)
Encoding

Capability Pointer Mode Description: Standard atomic instructions, authorised by the capability in cs1.
Integer Pointer Mode Description: Standard atomic instructions, authorised by the capability in ddc.
Permissions: Requires R-permission and W-permission in the authorising capability.

Requires all bytes of the access to be in capability bounds.
Exceptions: All misaligned atomics cause a store/AMO address misaligned exception to allow software emulation (if the Zam extension is supported, see (RISC-V, 2023)), otherwise they take a store/AMO access fault exception.

When these instructions cause CHERI exceptions, CHERI data fault is reported in the TYPE field and the following codes may be reported in the CAUSE field of mtval or stval:

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission or W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode AMO<OP>.W, AMO<OP>.D: Zcheripurecap, and A
Prerequisites for Integer Pointer Mode AMO<OP>.W, AMO<OP>.D: Zcherihybrid, and A
Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation: TODO

8.3.3. AMOSWAP.C

The RV64 encoding is intended to also allocate the encoding for AMOSWAP.Q for RV128.

Synopsis: Atomic Operation (AMOSWAP.C), 32-bit encoding

These instructions have different encodings for RV64 and RV32.

Capability Pointer Mode Mnemonic: amoswap.c cd, cs2, offset(cs1)
Integer Pointer Mode Mnemonic: amoswap.c cd, cs2, offset(rs1)
Encoding

Capability Pointer Mode Description: Atomic swap of capability type, authorised by the capability in cs1.
Integer Pointer Mode Description: Atomic swap of capability type, authorised by the capability in ddc.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Permissions: Requires the authorizing capability to be tagged and not sealed.

Requires R-permission and W-permission in the authorising capability.

If C-permission is not granted then store the memory tag as zero, and load cd.tag as zero.

If the authorizing capability does not grant LM-permission, and the tag of cd is 1 and cd is not sealed, then an implicit ACPERM clearing W-permission and LM-permission is performed to obtain the final permissions on cd (see LC).

+ Requires all bytes of the access to be in capability bounds.
Exceptions: All misaligned atomics cause a store/AMO address misaligned exception to allow software emulation (if the Zam extension is supported, see (RISC-V, 2023)), otherwise they take a store/AMO access fault exception.

When these instructions cause CHERI exceptions, CHERI data fault is reported in the TYPE field and the following codes may be reported in the CAUSE field of mtval or stval:

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission or W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites for Capability Pointer Mode AMOSWAP.C: Zcheripurecap, and A
Prerequisites for Integer Pointer Mode AMOSWAP.C: Zcherihybrid, and A
Operation: TODO

8.3.4. LR.D

See LR.B.

8.3.5. LR.W

See LR.B.

8.3.6. LR.H

See LR.B.

8.3.7. LR.B

Synopsis: Load Reserved (LR.D, LR.W, LR.H, LR.B), 32-bit encodings
Capability Pointer Mode Mnemonics (RV64): lr.[d|w|h|b] rd, 0(cs1)
Capability Pointer Mode Mnemonics (RV32): lr.[w|h|b] rd, 0(cs1)
Integer Pointer Mode Mnemonics (RV64): lr.[d|w|h|b] rd, 0(rs1)
Integer Pointer Mode Mnemonics (RV32): lr.[w|h|b] rd, 0(rs1)
Encoding

Capability Pointer Mode Description: Load reserved instructions, authorised by the capability in cs1.
Integer Pointer Mode Description: Load reserved instructions, authorised by the capability in ddc.

Exceptions

All misaligned load reservations cause a load address misaligned exception to allow software emulation (if the Zam extension is supported, see (RISC-V, 2023)), otherwise they take a load access fault exception.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode LR.D

RV64, Zcheripurecap, and A

Prerequisites for Capability Pointer Mode LR.W

Zcheripurecap, and A

Prerequisites for Capability Pointer Mode LR.H, LR.B

Zabhlrsc, and Zcheripurecap

Prerequisites for LR.D

RV64, Zcherihybrid, and A

Prerequisites for LR.W

Zcherihybrid, and A

Prerequisites for LR.H, LR.B

Zabhlrsc, Zcherihybrid

Operation

TBD

8.3.8. LR.C

The RV64 encoding is intended to also allocate the encoding for LR.Q for RV128.

Synopsis: Load Reserved Capability (LR.C), 32-bit encodings

These instructions have different encodings for RV64 and RV32.

Capability Pointer Mode Mnemonic: lr.c cd, 0(cs1)
Integer Pointer Mode Mnemonic: lr.c cd, 0(rs1)
Encoding

Capability Pointer Mode Description: Load reserved instructions, authorised by the capability in cs1. All misaligned load reservations cause a load address misaligned exception to allow software emulation (Zam extension, see (RISC-V, 2023)).
Integer Pointer Mode Description: Load reserved instructions, authorised by the capability in ddc. All misaligned load reservations cause a load address misaligned exception to allow software emulation (Zam extension, see (RISC-V, 2023)).
Resulting value of cd: The tag value written to cd is 0 if the tag of the memory location loaded is 0 or the authorizing capability (ddc or cs1) does not grant C-permission.

If the authorizing capability does not grant LM-permission, and the tag of cd is 1 and cd is not sealed, then an implicit ACPERM clearing W-permission and LM-permission is performed to obtain the final permissions on cd.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites for Capability Pointer Mode

Zcheripurecap, and A

Prerequisites for Integer Pointer Mode

Zcherihybrid, and A

Operation

TBD

8.3.9. SC.D

See SC.B.

8.3.10. SC.W

See SC.B.

8.3.11. SC.H

See SC.B.

8.3.12. SC.B

Synopsis: Store Conditional (SC.D, SC.W, SC.H, SC.B), 32-bit encodings
Capability Pointer Mode Mnemonics (RV64): sc.[d|w|h|b] rd, rs2, 0(cs1)
Capability Pointer Mode Mnemonics (RV32): sc.[w|h|b] rd, rs2, 0(cs1)
Integer Pointer Mode Mnemonics (RV64): sc.[d|w|h|b] rd, rs2, 0(rs1)
Integer Pointer Mode Mnemonics (RV32): sc.[w|h|b] rd, rs2, 0(rs1)
Encoding

Capability Pointer Mode Description: Store conditional instructions, authorised by the capability in cs1.
Integer Pointer Mode Description: Store conditional instructions, authorised by the capability in ddc.

Exceptions

All misaligned store conditionals cause a store/AMO address misaligned exception to allow software emulation (if the Zam extension is supported, see (RISC-V, 2023)), otherwise they take a store/AMO access fault exception.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode SC.D

RV64, and Zcheripurecap, and A

Prerequisites for Integer Pointer Mode SC.D

RV64, and Zcherihybrid, and A

Prerequisites for Capability Pointer Mode SC.W

Zcheripurecap, and A

Prerequisites for Integer Pointer Mode SC.W

Zcherihybrid, and A

Prerequisites for Capability Pointer Mode SC.H, SC.B

Zcheripurecap, and Zabhlrsc

Prerequisites for Integer Pointer Mode SC.H, SC.B

Zcherihybrid, and Zabhlrsc

Operation

TBD

8.3.13. SC.C

The RV64 encoding is intended to also allocate the encoding for SC.Q for RV128.

Synopsis: Store Conditional (SC.C), 32-bit encoding

These instructions have different encodings for RV64 and RV32.

Capability Pointer Mode Mnemonic: sc.c rd, cs2, 0(cs1)
Integer Pointer Mode Mnemonic: sc.c rd, cs2, 0(rs1)
Encoding

Capability Pointer Mode Description: Store conditional instructions, authorised by the capability in cs1. All misaligned store conditionals cause a store/AMO address misaligned exception to allow software emulation (Zam extension, see (RISC-V, 2023)).
Integer Pointer Mode Description: Store conditional instructions, authorised by the capability in ddc. All misaligned store conditionals cause a store/AMO address misaligned exception to allow software emulation (Zam extension, see (RISC-V, 2023)).

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites for Capability Pointer Mode

Zcheripurecap, and A

Prerequisites for Integer Pointer Mode

Zcherihybrid, and A

Operation

TBD

8.4. "Zicsr", Control and Status Register (CSR) Instructions

8.4.1. CSRRW

Synopsis: CSR access (CSRRW) 32-bit encodings
Mnemonic for accessing capability CSRs in Capability Pointer Mode: csrrw cd, csr, cs1
Mnemonic for accessing XLEN-wide CSRs or extended CSRs in Integer Pointer Mode: csrrw rd, csr, rs1
Encoding

Description: This is a standard RISC-V CSR instructions with extended functionality for accessing CLEN-wide CSRs, such as mtvec/mtvecc.

See Table 43 for a list of CLEN-wide CSRs and Table 44 for the action taken on writing each one.

CSRRW writes cs1 to extended CSRs in Capability Pointer Mode, and reads a full capability into cd.

CSRRW writes rs1 to extended CSRs in Integer Pointer Mode, and reads the address field into rd.

If cd is c0 (or rd is x0), then the instruction shall not read the CSR and shall not cause any of the side effects that might occur on a CSR read.

The assembler pseudo-instruction to write a capability CSR in Capability Pointer Mode, csrw csr, cs1, is encoded as csrrw c0, csr, cs1.

Access to XLEN-wide CSRs from other extensions is as specified by RISC-V.

When writing cs1, if the bounds are malformed, any reserved bits are set or the permission could not have been produced by ACPERM then clear the tag before writing to the CSR.

Permissions: Accessing privileged CSRs require ASR-permission, including existing RISC-V CSRs, as described in Section 3.5.1. The list of privileged and unprivileged CSRs is shown in (RISC-V, 2023).
Prerequisites for Capability Pointer Mode: Zcheripurecap
Prerequisites for Integer Pointer Mode: Zcherihybrid
Operation

TBD

8.4.6. CSRRCI

Synopsis: CSR access (CSRRWI, CSRRS, CSRRSI, CSRRC, CSRRCI) 32-bit encodings
Mnemonics for accessing capability CSRs in Capability Pointer Mode: csrrs cd, csr, rs1
csrrc cd, csr, rs1
csrrwi cd, csr, imm
csrrsi cd, csr, imm
csrrci cd, csr, imm
Mnemonics for accessing XLEN-wide CSRs or extended CSRs in Integer Pointer Mode: csrrs rd, csr, rs1
csrrc rd, csr, rs1
csrrwi rd, csr, imm
csrrsi rd, csr, imm
csrrci rd, csr, imm
Encoding

Description: These are standard RISC-V CSR instructions with extended functionality for accessing capability CSRs, such as mtvec/mtvecc.

For capability CSRs, the full capability is read into cd in Capability Pointer Mode. In Integer Pointer Mode, the address field is instead read into rd.

Unlike CSRRW, these instructions only update the address field and the tag as defined in Table 44 when writing capability CSRs regardless of the execution mode. The final address to write to the capability CSR is determined as defined by RISC-V for these instructions.

See Table 43 for a list of capability CSRs and Table 44 for the action taken on writing an XLEN-wide value to each one.

If cd is c0 (or rd is x0), then CSRRWI shall not read the CSR and and shall not cause any of the side effects that might occur on a CSR read. If rs1 is x0 for CSRRS and CSRRC, or imm is 0 for CSRRSI and CSRRCI, then the instruction will not write to the CSR at all, and so shall not cause any of the side effects that might otherwise occur on a CSR write.

The assembler pseudoinstruction to read a capability CSR in Capability Mode, csrr cd, csr, is encoded as csrrs cd, csr, x0.

Access to XLEN-wide CSRs is as specified by RISC-V.

If the CSR accessed is a capability, and rs1 is x0 for CSRRS and CSRRC, or imm is 0 for CSRRSI and CSRRCI, then the CSR is not written so no representability check is needed in this case.

Permissions: Accessing privileged CSRs requires ASR-permission, including existing RISC-V CSRs, as described in Section 3.5.1. The list of privileged and unprivileged CSRs is shown in (RISC-V, 2023).
Prerequisites for Capability Pointer Mode: Zcheripurecap
Prerequisites for Integer Pointer Mode: Zcherihybrid
Operation

TBD

8.5. "Zfh", "Zfhmin", "F" and "D" Standard Extension for Floating-Point

8.5.1. FLD

See FLH.

8.5.2. FLW

See FLH.

8.5.3. FLH

Synopsis: Floating point loads (FLD, FLW, FLH), 32-bit encodings
Capability Pointer Mode Mnemonics: fld frd, offset(cs1)
flw frd, offset(cs1)
flh frd, offset(cs1)
Integer Pointer Mode Mnemonics: fld rd, offset(rs1)
flw rd, offset(rs1)
flh rd, offset(rs1)
Encoding

Capability Pointer Mode Description: Standard floating point load instructions, authorised by the capability in cs1.
Integer Pointer Mode Description: Standard floating point load instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode FLD

Zcheripurecap, and D

Prerequisites for Integer Pointer Mode FLD

Zcherihybrid, and D

Prerequisites for Capability Pointer Mode FLW

Zcheripurecap, and F

Prerequisites for Integer Pointer Mode FLW

Zcherihybrid, and F

Prerequisites for Capability Pointer Mode FLH

Zcheripurecap, and Zfhmin or Zfh

Prerequisites for Integer Pointer Mode FLH

Zcherihybrid, and Zfhmin or Zfh

Operation

TODO

8.5.4. FSD

See FSH.

8.5.5. FSW

See FSH.

8.5.6. FSH

Synopsis: Floating point stores (FSD, FSW, FSH), 32-bit encodings
Capability Pointer Mode Mnemonics: fsd fs2, offset(cs1)
fsw fs2, offset(cs1)
fsh fs2, offset(cs1)
Integer Pointer Mode Mnemonics: fsd fs2, offset(rs1)
fsw fs2, offset(rs1)
fsh fs2, offset(rs1)
Encoding

Capability Pointer Mode Description

Standard floating point store instructions, authorised by the capability in cs1.

Integer Pointer Mode Description

Standard floating point store instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode FSD

Zcheripurecap, and D

Prerequisites for Integer Pointer Mode FSD

Zcherihybrid, and D

Prerequisites for Capability Pointer Mode FSW

Zcheripurecap, and F

Prerequisites for Integer Pointer Mode FSW

Zcherihybrid, and F

Prerequisites for Capability Pointer Mode FSH

Zcheripurecap, and Zfh or Zfhmin

Prerequisites for Integer Pointer Mode FSH

Zcherihybrid, and Zfh or Zfhmin

Operation

TBD

8.6. "C" Standard Extension for Compressed Instructions

One group of 16-bit encodings are remapped to different instructions dependant upon the CHERI execution mode, MXLEN and which extensions are supported.

Zcf and Zilsd are incompatible

Zcd and Zcmp/Zcmt incompatible

8.6.1. RV32

Table 31. 16-bit instruction remapping in *Integer Pointer Mode*
Encoding		Supported Extensions
[15:13]	[1:0]	Zca	Zcf	Zcd	Zcmp/ Zcmt	Zilsd
111	00	N/A	C.FSW	N/A	N/A	C.SD
011	00	N/A	C.FLW	N/A	N/A	C.LD
111	10	N/A	C.FSWSP	N/A	N/A	C.SDSP
011	10	N/A	C.FLWSP	N/A	N/A	C.LDSP
101	00	N/A	N/A	C.FSD	reserved¹	N/A
001	00	N/A	N/A	C.FLD	reserved¹	N/A
101	10	N/A	N/A	C.FSDSP	Zcmp/Zcmt	N/A
001	10	N/A	N/A	C.FLDSP	reserved¹	N/A

¹ reserved for future standard Zcm extensions

Table 32. 16-bit instruction remapping in *Capability Pointer Mode*
Encoding		Supported Extensions
[15:13]	[1:0]	Zca	Zcf	Zcd	Zcmp/ Zcmt	Zilsd
111	00	C.SC
011	00	C.LC
111	10	C.SCSP
011	10	C.LCSP
101	00	N/A	N/A	C.FSD	reserved¹	N/A
001	00	N/A	N/A	C.FLD	reserved¹	N/A
101	10	N/A	N/A	C.FSDSP	Zcmp/Zcmt	N/A
001	10	N/A	N/A	C.FLDSP	reserved¹	N/A

¹ reserved for future standard Zcm extensions

8.6.2. RV64

Table 33. 16-bit instruction remapping in *Integer Pointer Mode*
Encoding		Supported Extensions
[15:13]	[1:0]	Zca	Zcf	Zcd	Zcmp/ Zcmt	Zilsd
111	00	C.SD	N/A	N/A	N/A	N/A
011	00	C.LD	N/A	N/A	N/A	N/A
111	10	C.SDSP	N/A	N/A	N/A	N/A
011	10	C.LDSP	N/A	N/A	N/A	N/A
101	00	N/A	N/A	C.FSD	reserved¹	N/A
001	00	N/A	N/A	C.FLD	reserved¹	N/A
101	10	N/A	N/A	C.FSDSP	Zcmp/Zcmt	N/A
001	10	N/A	N/A	C.FLDSP	reserved¹	N/A

Table 34. 16-bit instruction remapping in *Capability Pointer Mode*
Encoding		Supported Extensions
[15:13]	[1:0]	Zca	Zcf	Zcd	Zcmp/ Zcmt	Zilsd
111	00	C.SD	N/A	N/A	N/A	N/A
011	00	C.LD	N/A	N/A	N/A	N/A
111	10	C.SDSP	N/A	N/A	N/A	N/A
011	10	C.LDSP	N/A	N/A	N/A	N/A
101	00	C.SC
001	00	C.LC
101	10	C.SCSP
001	10	C.LCSP

8.6.3. C.BEQZ, C.BNEZ

Synopsis: Conditional branches (C.BEQZ, C.BNEZ), 16-bit encodings
Mnemonics: c.beqz rs1', offset
c.bnez rs1', offset
Expansions: beq rs1′, x0, offset
bne rs1′, x0, offset
Encoding

Exceptions: When the target address is not within the pcc's bounds, and the branch is taken, a CHERI jump or branch fault is reported in the TYPE field and Length Violation is reported in the CAUSE field of mtval or stval:

Prerequisites: C or Zca
Operation (after expansion to 32-bit encodings): See Conditional branches (BEQ, BNE, BLT[U], BGE[U])

8.6.4. C.MV

Synopsis: Capability move (C.MV), 16-bit encoding
Capability Pointer Mode Mnemonic: c.mv cd, cs2
Capability Pointer Mode Expansion: cmv cd, cs2
Suggested assembly syntax: mv rd, rs2
mv cd, cs2

the suggested assembly syntax distinguishes from integer mv by operand type.

Integer Pointer Mode Mnemonic: c.mv rd, rs2
Integer Pointer Mode Expansion: add rd, x0, rs2
Encoding

Capability Pointer Mode Description: Capability register cd is replaced with the contents of cs2.
Integer Pointer Mode Description: Standard RISC-V C.MV instruction.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid
Capability Pointer Mode Operation (after expansion to 32-bit encodings): See CMV

8.6.5. C.ADDI16SP

Synopsis: Stack pointer increment in blocks of 16 (C.ADDI16SP), 16-bit encodings
Capability Pointer Mode Mnemonic: c.addi16sp imm
Capability Pointer Mode Expansion: cadd csp, csp, imm
Integer Pointer Mode Mnemonic: c.addi16sp imm
Integer Pointer Mode Expansion: add sp, sp, imm
Encoding

Capability Pointer Mode Description: Add the non-zero sign-extended 6-bit immediate to the value in the stack pointer (csp=c2), where the immediate is scaled to represent multiples of 16 in the range (-512,496). Clear the tag if the resulting capability is unrepresentable or csp is sealed.
Integer Pointer Mode Description: Add the non-zero sign-extended 6-bit immediate to the value in the stack pointer (sp=x2), where the immediate is scaled to represent multiples of 16 in the range (-512,496).
Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid
Capability Pointer Mode Operation: TODO

8.6.6. C.ADDI4SPN

See C.ADDI4SPN.

Synopsis: Stack pointer increment in blocks of 4 (C.ADDI4SPN), 16-bit encoding
Capability Pointer Mode Mnemonic: c.addi4spn cd', uimm
Capability Pointer Mode Expansion: cadd cd', csp, uimm
Integer Pointer Mode Mnemonic: c.addi4spn rd', uimm
Integer Pointer Mode Expansion: add rd', sp, uimm
Encoding

Capability Pointer Mode Description: Add a zero-extended non-zero immediate, scaled by 4, to the stack pointer, csp, and writes the result to cd'. This instruction is used to generate pointers to stack-allocated variables. Clear the tag if the resulting capability is unrepresentable or csp is sealed.
Integer Pointer Mode Description: Add a zero-extended non-zero immediate, scaled by 4, to the stack pointer, sp, and writes the result to rd'. This instruction is used to generate pointers to stack-allocated variables.
Prerequisites for C.ADDI4SPN: C or Zca, Zcheripurecap
Prerequisites for C.ADDI4SPN: C or Zca, Zcherihybrid
Capability Pointer Mode Operation: TODO

8.6.7. C.MODESW

Synopsis: Capability/Integer Pointer Mode switching (C.MODESW), 16-bit encoding
Mnemonic: c.modesw
Expansion: modesw
Encoding

Description

Toggle the hart’s current CHERI execution mode in pcc.

If the current mode in pcc is Integer Pointer Mode (1), then the M-bit in pcc is set to Capability Pointer Mode (0).
If the current mode is Capability Pointer Mode (0), then the M-bit in pcc is set to Integer Pointer Mode (1).

Implementations may optionally support executing C.MODESW from the program buffer while in debug mode.

Exceptions: This instruction is illegal if the CHERI register access is disabled for the current privilege.
Prerequisites: C or Zca, Zcherihybrid
Operation (after expansion to 32-bit encodings): See MODESW

8.6.8. C.JALR

Synopsis: Jump register with link, 16-bit encodings
Capability Pointer Mode Mnemonic: c.jalr c1, cs1
Capability Pointer Mode Expansion: jalr c1, 0(cs1)
Integer Pointer Mode Mnemonic: c.jalr x1, rs1
Integer Pointer Mode Expansion: jalr x1, 0(rs1)
Encoding

Capability Pointer Mode Description: See JALR for execution of the expanded instruction as shown above. Note that the offset is zero in the expansion.
Integer Pointer Mode Description: See JALR for execution of the expanded instruction as shown above. Note that the offset is zero in the expansion.
Exceptions: See JALR

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid
Operation (after expansion to 32-bit encodings): See JALR

8.6.9. C.JR

Synopsis: Jump register without link, 16-bit encodings
Capability Pointer Mode Mnemonic: c.jr cs1
Capability Pointer Mode Expansion: jalr c0, 0(cs1)
Integer Pointer Mode Mnemonic: c.jr rs1
Integer Pointer Mode Expansion: jalr x0, 0(rs1)
Encoding

Capability Pointer Mode Description: See JALR for execution of the expanded instruction as shown above. Note that the offset is zero in the expansion.
Integer Pointer Mode Description: See JALR for execution of the expanded instruction as shown above. Note that the offset is zero in the expansion.
Exceptions: See JALR

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid
Operation (after expansion to 32-bit encodings): See JALR

8.6.10. C.JAL

Synopsis: Jump with link, 16-bit encodings
Capability Pointer Mode Mnemonic (RV32): c.jal c1, offset
Capability Pointer Mode Expansion (RV32): jal c1, offset
Integer Pointer Mode Mnemonic (RV32): c.jal x1, offset
Integer Pointer Mode Expansion (RV32): jal x1, offset
Encoding (RV32)

Capability Pointer Mode Description: Link the next linear pcc to cd and seal. Jump to pcc.address+offset.
Integer Pointer Mode Description: Set the next PC and link to rd according to the standard JAL definition.
Exceptions: See JAL

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid
Operation (after expansion to 32-bit encodings): See JAL

8.6.11. C.J

Synopsis: Jump without link, 16-bit encodings
Mnemonic: c.j offset
Capability Pointer Mode Expansion: jal c0, offset
Integer Pointer Mode Expansion: jal x0, offset
Encoding

Description: Set the next PC following the standard JAL definition.

There is no difference in Capability Pointer Mode or Integer Pointer Mode execution for this instruction.
Exceptions: See JAL

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid
Operation (after expansion to 32-bit encodings): See JAL

8.6.12. C.LD

See C.LW.

8.6.13. C.LW

Synopsis: Load (C.LD, C.LW), 16-bit encodings
Capability Pointer Mode Mnemonics (RV64): c.ld rd', offset(cs1')
c.lw rd', offset(cs1')
Capability Pointer Mode Expansions (RV64): ld rd', offset(cs1')
lw rd', offset(cs1')
Integer Pointer Mode Mnemonics (RV64): c.ld rd', offset(rs1')
c.lw rd', offset(rs1')
Integer Pointer Mode Expansions (RV64): ld rd', offset(rs1')
lw rd', offset(rs1')
Capability Pointer Mode Mnemonic (RV32): c.lw rd', offset(cs1')
Capability Pointer Mode Expansion (RV32): lw rd', offset(cs1')
Integer Pointer Mode Mnemonic (RV32): c.lw rd', offset(rs1')
Integer Pointer Mode Expansion (RV32): lw rd', offset(rs1')
Encoding

Capability Pointer Mode Description

Standard load instructions, authorised by the capability in cs1.

Integer Pointer Mode Description

Standard load instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode C.LD

RV64, and C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.LD

RV64, C or Zca, Zcherihybrid

Prerequisites Capability Pointer Mode C.LW

C or Zca, Zcheripurecap

Prerequisites Integer Pointer Mode C.LW

C or Zca, Zcherihybrid

Operation (after expansion to 32-bit encodings)

See LD, LW

8.6.14. C.LWSP

See C.LDSP.

8.6.15. C.LDSP

Synopsis: Load (C.LWSP, C.LDSP), 16-bit encodings
Capability Pointer Mode Mnemonics (RV64): c.ld/c.lw rd, offset(csp)
Capability Pointer Mode Expansions (RV64): ld/lw rd, offset(csp)
Integer Pointer Mode Mnemonics (RV64): c.ld/c.lw rd, offset(sp)
Integer Pointer Mode Expansions (RV64): ld/lw rd, offset(sp)
Capability Pointer Mode Mnemonic (RV32): c.lw rd, offset(csp)
Capability Pointer Mode Expansion (RV32): lw rd, offset(csp)
Integer Pointer Mode Mnemonic (RV32): c.lw rd, offset(sp)
Integer Pointer Mode Expansion (RV32): lw rd, offset(sp)
Encoding

Capability Pointer Mode Description

Standard stack pointer relative load instructions, authorised by the capability in csp.

Integer Pointer Mode Description

Standard stack pointer relative load instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode C.LDSP

RV64, and C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.LDSP

RV64, and C or Zca, Zcherihybrid

Prerequisites for Capability Pointer Mode C.LWSP

C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.LWSP

C or Zca, Zcherihybrid

Operation (after expansion to 32-bit encodings)

See LW, LD

8.6.16. C.FLW

See C.FLWSP.

8.6.17. C.FLWSP

Synopsis: Floating point load (C.FLW, C.FLWSP), 16-bit encodings
Integer Pointer Mode Mnemonics (RV32): c.flw rd', offset(rs1'/sp)
Integer Pointer Mode Expansions (RV32): flw rd', offset(rs1'/sp)
Encoding (RV32)

Integer Pointer Mode Description: Standard floating point load instructions, authorised by the capability in ddc.

These instructions are available in RV32 Integer Pointer Mode only. In Capability Pointer Mode they are remapped to C.LC/C.LCSP.

In Integer Pointer Mode, these instructions may be remapped to other encodings by future RV32 only extensions such as Zilsd. If this is the case, then the Zilsd encodings will be valid in Integer Pointer Mode only. In Capability Pointer Mode the instructions will still be C.LC/C.LCSP.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, and Zcf or F

Operation (after expansion to 32-bit encodings)

See FLW

8.6.18. C.FLD

See C.FLDSP

8.6.19. C.FLDSP

Synopsis: Double precision floating point loads (C.FLD, C.FLDSP), 16-bit encodings
Capability Pointer Mode Mnemonic (RV32): c.fld frd', offset(cs1'/csp)
Capability Pointer Mode Expansion (RV32): fld frd', offset(csp)
Integer Pointer Mode Mnemonic: c.fld fs2, offset(rs1'/sp)
Integer Pointer Mode Expansion: fld fs2, offset(rs1'/sp)
Encoding

Integer Pointer Mode Description: Standard floating point stack pointer relative load instructions, authorised by the capability in ddc.

These instructions are available in RV64 Integer Pointer Mode only. In RV64 Capability Pointer Mode they are remapped to C.LC/C.LCSP.

These encodings may be remapped by future code-size Zcm standard extensions, similar to Zcmp and Zcmt. The rule is that in RV64 Capability Pointer Mode they are always remapped to C.SC/C.SCSP.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode (RV32 only)

Zcheripurecap, C and D; or
Zcheripurecap, Zca and Zcd

Prerequisites for Integer Pointer Mode

Zcherihybrid, C and D; or
Zcherihybrid, Zca and Zcd

Operation (after expansion to 32-bit encodings)

See FLD

8.6.20. C.LC

see C.LCSP.

8.6.21. C.LCSP

Synopsis: Capability loads (C.LC, C.LCSP), 16-bit encodings
Capability Pointer Mode Mnemonics: c.lc cd', offset(cs1')
c.lc cd', offset(csp)
Capability Pointer Mode Expansions: lc cd', offset(cs1')
lc cd', offset(csp)
Encoding

Capability Pointer Mode Description: Load capability instruction, authorised by the capability in cs1. Take a load address misaligned exception if not naturally aligned.

These mnemonics do not exist in Integer Pointer Mode.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites

C or Zca, Zcheripurecap

Operation (after expansion to 32-bit encodings)

See LC

8.6.22. C.SD

See C.SW.

8.6.23. C.SW

Synopsis: Stores (C.SD, C.SW), 16-bit encodings
Capability Pointer Mode Mnemonics (RV64): c.sd rs2', offset(cs1')
c.sw rs2', offset(cs1')
Capability Pointer Mode Expansions (RV64): sd rs2', offset(cs1')
sw rs2', offset(cs1')
Integer Pointer Mode Mnemonics (RV64): c.sd rs2', offset(rs1')
c.sw rs2', offset(rs1')
Integer Pointer Mode Expansions (RV64): sd rs2', offset(rs1')
sw rs2', offset(rs1')
Capability Pointer Mode Mnemonic (RV32): c.sw rs2', offset(cs1')
Capability Pointer Mode Expansion (RV32): sw rs2', offset(cs1')
Integer Pointer Mode Mnemonic (RV32): c.sw rs2', offset(rs1')
Integer Pointer Mode Expansion (RV32): sw rs2', offset(rs1')
Encoding

Capability Pointer Mode Description

Standard store instructions, authorised by the capability in cs1.

Integer Pointer Mode Description

Standard store instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode C.SD

RV64, and C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.SD

RV64, and C or Zca, Zcherihybrid

Prerequisites for Capability Pointer Mode C.SW

C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.SW

C or Zca, Zcherihybrid

Operation (after expansion to 32-bit encodings)

See SD, SW

8.6.24. C.SWSP

See C.SDSP.

8.6.25. C.SDSP

Synopsis: Stack pointer relative stores (C.SWSP, C.SDSP), 16-bit encodings
Capability Pointer Mode Mnemonics (RV64): c.sd rs2, offset(csp)
c.sw rs2, offset(csp)
Capability Pointer Mode Expansions (RV64): sd rs2, offset(csp)
sw rs2, offset(csp)
Integer Pointer Mode Mnemonics (RV64): c.sd rs2, offset(sp)
c.sw rs2, offset(sp)
Integer Pointer Mode Expansions (RV64): sd rs2, offset(sp)
sw rs2, offset(sp)
Capability Pointer Mode Mnemonic (RV32): c.sw rs2, offset(csp)
Capability Pointer Mode Expansion (RV32): sw rs2, offset(csp)
Integer Pointer Mode Mnemonic (RV32): c.sw rs2, offset(sp)
Integer Pointer Mode Expansion (RV32): sw rs2, offset(sp)
Encoding

Capability Pointer Mode Description

Standard stack pointer relative store instructions, authorised by the capability in csp.

Integer Pointer Mode Description

Standard stack pointer relative store instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode C.SDSP

RV64, and C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.SDSP

RV64, and C or Zca, Zcherihybrid

Prerequisites for Capability Pointer Mode C.SWSP

C or Zca, Zcheripurecap

Prerequisites for Integer Pointer Mode C.SWSP

C or Zca, Zcherihybrid

Operation (after expansion to 32-bit encodings)

See SD, SW

8.6.26. C.FSW

See C.FSWSP.

8.6.27. C.FSWSP

Synopsis: Floating point stores (C.FSW, C.FSWSP), 16-bit encodings
Integer Pointer Mode Mnemonics (RV32): c.fsw rs2', offset(rs1')
c.fsw rs2', offset(sp)
Integer Pointer Mode Expansions (RV32): fsw rs2', offset(rs1')
fsw rs2', offset(sp)
Encoding (RV32)

Integer Pointer Mode Description: Standard floating point store instructions, authorised by the capability in ddc.

These instructions are available in RV32 Integer Pointer Mode only. In Capability Pointer Mode they are remapped to C.SC/C.SCSP.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites

C or Zca, Zcherihybrid, Zcf or F

Operation (after expansion to 32-bit encodings)

See FSW

8.6.28. C.FSD

See C.FSDSP.

8.6.29. C.FSDSP

Synopsis: Double precision floating point stores (C.FSD, C.FSDSP), 16-bit encodings
Capability Pointer Mode Mnemonics (RV32): c.fsd fs2, offset(cs1')
c.fsd fs2, offset(csp)
Capability Pointer Mode Expansions (RV32): fsd fs2, offset(cs1')
fsd fs2, offset(csp)
Integer Pointer Mode Mnemonics: c.fsd fs2, offset(rs1')
c.fsd fs2, offset(sp)
Integer Pointer Mode Expansions: fsd fs2, offset(rs1)
fsd fs2, offset(sp)
Encoding

Capability Pointer Mode Description: Standard floating point stack pointer relative store instructions, authorised by the capability in cs1 or csp.
Integer Pointer Mode Description: Standard floating point stack pointer relative store instructions, authorised by the capability in ddc.

These instructions are available in RV64 Integer Pointer Mode only. In RV64 Capability Pointer Mode they are remapped to C.SC/C.SCSP.

C.FSDSP may be remapped by the Zcmp, Zcmt standard extensions. C.FSD may be remapped by future code-size reduction extensions. The rule is that in RV64 Capability Pointer Mode they are always remapped to C.LC/C.LCSP.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode C.FSD, C.FSDSP (RV32 only)

Zcheripurecap, C and D; or
Zcheripurecap, Zca and Zcd

Prerequisites for Integer Pointer Mode C.FSD, C.FSDSP

Zcherihybrid, C and D; or
Zcherihybrid, Zca and Zcd

Operation (after expansion to 32-bit encodings)

See FSD

8.6.30. C.SC

see C.SCSP.

8.6.31. C.SCSP

Synopsis: Stores (C.SC, C.SCSP), 16-bit encodings

These instructions have different encodings for RV64 and RV32.

Capability Pointer Mode Mnemonics: c.sc cs2', offset(cs1')
c.sc cs2', offset(csp)
Capability Pointer Mode Expansions: sc cs2', offset(cs1')
sc cs2', offset(csp)
Encoding

Capability Pointer Mode Description: Store capability instruction, authorised by the capability in cs1. Take a store/AMO address misaligned exception if not naturally aligned.

These mnemonics do not exist in Integer Pointer Mode.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites

C or Zca, Zcheripurecap

Operation (after expansion to 32-bit encodings)

See SC

8.7. "Zicbom", "Zicbop", "Zicboz" Standard Extensions for Base Cache Management Operations

8.7.1. CBO.CLEAN

Synopsis: Perform a clean operation on a cache block
Capability Pointer Mode Mnemonic: cbo.clean 0(cs1)
Integer Pointer Mode Mnemonic: cbo.clean 0(rs1)
Encoding

Capability Pointer Mode Description: A CBO.CLEAN instruction performs a clean operation on the cache block whose effective address is the base address specified in cs1. The authorising capability for this operation is cs1.
Integer Pointer Mode Description: A CBO.CLEAN instruction performs a clean operation on the cache block whose effective address is the base address specified in rs1. The authorising capability for this operation is ddc.

Exceptions

CHERI fault exceptions when the authorising capability fails one of the checks listed below; in this case, CHERI data fault is reported in the mtval or stval TYPE field and the corresponding code is written to CAUSE.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission and R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

None of the bytes accessed are within the bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode: Zicbom, Zcheripurecap
Prerequisites for Integer Pointer Mode: Zicbom, Zcherihybrid
Operation

TBD

8.7.2. CBO.FLUSH

Synopsis: Perform a flush operation on a cache block
Capability Pointer Mode Mnemonic: cbo.flush 0(cs1)
Integer Pointer Mode Mnemonic: cbo.flush 0(rs1)
Encoding

Capability Pointer Mode Description: A CBO.FLUSH instruction performs a flush operation on the cache block whose effective address is the base address specified in cs1. The authorising capability for this operation is cs1.
Integer Pointer Mode Description: A CBO.FLUSH instruction performs a flush operation on the cache block whose effective address is the base address specified in rs1. The authorising capability for this operation is ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission and R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

None of the bytes accessed are within the bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode: Zicbom, Zcheripurecap
Prerequisites for Integer Pointer Mode: Zicbom, Zcherihybrid
Operation

TBD

8.7.3. CBO.INVAL

Synopsis: Perform an invalidate operation on a cache block
Capability Pointer Mode Mnemonic: cbo.inval 0(cs1)
Integer Pointer Mode Mnemonic: cbo.inval 0(rs1)
Encoding

Capability Pointer Mode Description: A CBO.INVAL instruction performs an invalidate operation on the cache block whose effective address is the base address specified in cs1. The authorising capability for this operation is cs1.
Integer Pointer Mode Description: A CBO.INVAL instruction performs an invalidate operation on the cache block whose effective address is the base address specified in rs1. The authorising capability for this operation in ddc.

Exceptions: CHERI fault exceptions when the authorising capability fails one of the checks listed below; in this case, CHERI data fault is reported in the mtval or stval TYPE field and the corresponding code is written to CAUSE.

The CBIE bit in menvcfg and senvcfg indicates whether CBO.INVAL performs cache block flushes instead of invalidations for less privileged modes. The instruction checks shown in the table below remain unchanged regardless of the value of CBIE and the privilege mode.

Invalidating a cache block can re-expose capabilities previously stored to it after the most recent flush, not just secret values. As such, CBO.INVAL has stricter checks on its use than CBO.FLUSH, and should only be made available to, and used by, sufficiently-trusted software. Untrusted software should use CBO.FLUSH instead.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, R-permission or ASR-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

None of the bytes accessed are within the bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode: Zicbom, Zcheripurecap
Prerequisites for Integer Pointer Mode: Zicbom, Zcherihybrid
Operation

TBD

8.7.4. CBO.ZERO

Synopsis: Store zeros to the full set of bytes corresponding to a cache block
Capability Pointer Mode Mnemonic: cbo.zero 0(cs1)
Integer Pointer Mode Mnemonic: cbo.zero 0(rs1)
Encoding

Capability Pointer Mode Description

A cbo.zero instruction performs stores of zeros to the full set of bytes corresponding to the cache block whose effective address is the base address specified in cs1. An implementation may or may not update the entire set of bytes atomically although each individual write must atomically clear the tag bit of the corresponding aligned CLEN-bit location. The authorising capability for this operation is cs1.

Integer Pointer Mode Description

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

Zicboz, Zcheripurecap

Prerequisites for Integer Pointer Mode

Zicboz, Zcherihybrid

Operation

TBD

8.7.5. PREFETCH.I

Synopsis: Provide a HINT to hardware that a cache block is likely to be accessed by an instruction fetch in the near future
Capability Pointer Mode Mnemonic: prefetch.i offset(cs1)
Integer Pointer Mode Mnemonic: prefetch.i offset(rs1)
Encoding

Capability Pointer Mode Description: A PREFETCH.I instruction indicates to hardware that the cache block whose effective address is the sum of the base address specified in cs1 and the sign-extended offset encoded in imm[11:0], where imm[4:0] equals 0b00000, is likely to be accessed by an instruction fetch in the near future. The encoding is only valid if imm[4:0]=0. The authorising capability for this operation is cs1. This instruction does not throw any exceptions. However, following CHERI Exceptions and speculative execution, this instruction does not perform a prefetch if it is not authorized by cs1.
Integer Pointer Mode Description: A PREFETCH.I instruction indicates to hardware that the cache block whose effective address is the sum of the base address specified in rs1 and the sign-extended offset encoded in imm[11:0], where imm[4:0] equals 0b00000, is likely to be accessed by an instruction fetch in the near future. The encoding is only valid if imm[4:0]=0. The authorising capability for this operation is pcc.

In either mode, PREFETCH.I does not perform a memory access if one or more of the following conditions of the authorising capability are met:

The tag is not set
The sealed bit is set
No bytes of the cache line requested is in bounds
The X-permission is not set
Any reserved bits are set
The permissions could not have been produced by ACPERM
The bounds are malformed

Prerequisites for Capability Pointer Mode: Zicbop, Zcheripurecap
Prerequisites for Integer Pointer Mode: Zicbop, Zcherihybrid
Operation

TODO

8.7.6. PREFETCH.R

Synopsis: Provide a HINT to hardware that a cache block is likely to be accessed by a data read in the near future
Capability Pointer Mode Mnemonic: prefetch.r offset(cs1)
Integer Pointer Mode Mnemonic: prefetch.r offset(rs1)
Encoding

Capability Pointer Mode Description: A PREFETCH.R instruction indicates to hardware that the cache block whose effective address is the sum of the base address specified in cs1 and the sign-extended offset encoded in imm[11:0], where imm[4:0] equals 0b00000, is likely to be accessed by a data read (i.e. load) in the near future. The encoding is only valid if imm[4:0]=0. The authorising capability for this operation is cs1. This instruction does not throw any exceptions. However, in following CHERI Exceptions and speculative execution, this instruction does not perform a prefetch if it is not authorized by cs1.
Integer Pointer Mode Description: A PREFETCH.R instruction indicates to hardware that the cache block whose effective address is the sum of the base address specified in rs1 and the sign-extended offset encoded in imm[11:0], where imm[4:0] equals 0b00000, is likely to be accessed by a data read (i.e. load) in the near future. The encoding is only valid if imm[4:0]=0. The authorising capability for this operation is ddc.

In either mode, PREFETCH.R does not perform a memory access if one or more of the following conditions of the authorising capability are met:

The tag is not set
The sealed bit is set
No bytes of the cache line requested is in bounds
The R-permission is not set
Any reserved bits are set
The permissions could not have been produced by ACPERM
The bounds are malformed

Prerequisites for Capability Pointer Mode: Zicbop, Zcheripurecap
Prerequisites for Integer Pointer Mode: Zicbop, Zcherihybrid
Operation

TODO

8.7.7. PREFETCH.W

Synopsis: Provide a HINT to hardware that a cache block is likely to be accessed by a data write in the near future
Capability Pointer Mode Mnemonic: prefetch.w offset(cs1)
Integer Pointer Mode Mnemonic: prefetch.w offset(rs1)
Encoding

Capability Pointer Mode Description: A PREFETCH.W instruction indicates to hardware that the cache block whose effective address is the sum of the base address specified in cs1 and the sign-extended offset encoded in imm[11:0], where imm[4:0] equals 0b00000, is likely to be accessed by a data write (i.e. store) in the near future. The encoding is only valid if imm[4:0]=0. The authorising capability for this operation is cs1. This instruction does not throw any exceptions. However, following CHERI Exceptions and speculative execution, this instruction does not perform a prefetch if it is not authorized by cs1.
Integer Pointer Mode Description: A PREFETCH.W instruction indicates to hardware that the cache block whose effective address is the sum of the base address specified in rs1 and the sign-extended offset encoded in imm[11:0], where imm[4:0] equals 0b00000, is likely to be accessed by a data write (i.e. store) in the near future. The encoding is only valid if imm[4:0]=0. The authorising capability for this operation is ddc.

In either mode, PREFETCH.W does not perform a memory access if one or more of the following conditions of the authorising capability are met:

The tag is not set
The sealed bit is set
No bytes of the cache line requested is in bounds
The W-permission is not set
Any reserved bits are set
The permissions could not have been produced by ACPERM
The bounds are malformed

Prerequisites for Capability Pointer Mode: Zicbop, Zcheripurecap
Prerequisites for Integer Pointer Mode: Zicbop, Zcherihybrid
Operation

TODO

8.8. "Zba" Extension for Bit Manipulation Instructions

8.8.1. ADD.UW

Synopsis: Add unsigned word for address generation
Capability Pointer Mode Mnemonic (RV64): add.uw cd, rs1, cs2
Integer Pointer Mode Mnemonic (RV64): add.uw rd, rs1, rs2
Encoding

Capability Pointer Mode Description: Increment the address field of cs2 by the unsigned word in rs1. Clear the tag if the resulting capability is unrepresentable or cs2 is sealed.
Integer Pointer Mode Description: Increment rs2 by the unsigned word in rs1.
Prerequisites for Capability Pointer Mode: RV64, Zcheripurecap, Zba
Prerequisites for Integer Pointer Mode: RV64, Zcherihybrid, Zba
Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation: TODO

8.8.2. SH1ADD

See SH3ADD.

8.8.3. SH2ADD

See SH3ADD.

8.8.4. SH3ADD

Synopsis: Shift by n and add for address generation (SH1ADD, SH2ADD, SH3ADD)
Capability Pointer Mode Mnemonics: sh[1|2|3]add cd, rs1, cs2
Integer Pointer Mode Mnemonics: sh[1|2|3]add rd, rs1, rs2
Encoding

Capability Pointer Mode Description: Increment the address field of cs2 by rs1 shifted left by n bit positions and write the result to cd. The tag bit of the output capability is 0 if cs2 did not have its tag set to 1, the incremented address is outside cs2 's Representable Range or cs2 is sealed.

This instruction sets cd.tag=0 if cs2 's bounds are malformed, or if any of the reserved fields are set.

Integer Pointer Mode Description: Increment rs2 by rs1 shifted left by n bit positions and write the result to rd.
Exceptions: None
Prerequisites for Capability Pointer Mode: Zcheripurecap, Zba
Prerequisites for Integer Pointer Mode: Zcherihybrid, Zba
Capability Pointer Mode Operation

TODO

Integer Pointer Mode Operation: TODO

8.8.5. SH1ADD.UW

See SH3ADD.UW.

8.8.6. SH2ADD.UW

See SH3ADD.UW.

8.8.7. SH3ADD.UW

Synopsis: Shift by n and add unsigned word for address generation (SH1ADD.UW, SH2ADD.UW, SH3ADD.UW)
Capability Pointer Mode Mnemonics (RV64): sh[1|2|3]add.uw cd, rs1, cs2
Integer Pointer Mode Mnemonics (RV64): sh[1|2|3]add.uw rd, rs1, rs2
Encoding

Capability Pointer Mode Description: Increment the address field of cs2 by the unsigned word in rs1 shifted left by n bit positions and write the result to cd. The tag bit of the output capability is 0 if cs2 did not have its tag set to 1, the incremented address is outside cs2 's Representable Range or cs2 is sealed.

This instruction sets cd.tag=0 if cs2 's bounds are malformed, or if any of the reserved fields are set.

Integer Pointer Mode Description: Increment rs2 by the unsigned word in rs1 shifted left by n bit positions and write the result to rd.
Exceptions: None
Prerequisites for Capability Pointer Mode: RV64, Zcheripurecap, Zba
Prerequisites for Integer Pointer Mode: RV64, Zcherihybrid, Zba
Capability Pointer Mode Operation

TODO

Integer Pointer Mode Operation: TODO

8.8.8. SH4ADD

Synopsis: Shift by 4 and add for address generation (SH4ADD)
Capability Pointer Mode Mnemonic (RV64): sh4add cd, rs1, cs2
Integer Pointer Mode Mnemonic (RV64): sh4add rd, rs1, rs2
Encoding

Capability Pointer Mode Description: Increment the address field of cs2 by rs1 shifted left by 4 bit positions and write the result to cd. The tag bit of the output capability is 0 if cs2 did not have its tag set to 1, the incremented address is outside cs2 's Representable Range or cs2 is sealed.

This instruction sets cd.tag=0 if cs2 's bounds are malformed, or if any of the reserved fields are set.

Integer Pointer Mode Description: Increment rs2 by rs1 shifted left by 4 bit positions and write the result to rd.
Exceptions: None
Prerequisites for Capability Pointer Mode: RV64, Zish4add
Prerequisites for Integer Pointer Mode: RV64, Zish4add
Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

8.8.9. SH4ADD.UW

Synopsis: Shift by 4 and add unsigned words for address generation (SH4ADD.UW)
Capability Pointer Mode Mnemonic (RV64): sh4add.uw cd, rs1, cs2
Integer Pointer Mode Mnemonic (RV64): sh4add.uw rd, rs1, rs2
Encoding

Capability Pointer Mode Description: Increment the address field of cs2 by the unsigned word in rs1 shifted left by 4 bit positions and write the result to cd. The tag bit of the output capability is 0 if cs2 did not have its tag set to 1, the incremented address is outside cs2 's Representable Range or cs2 is sealed.

This instruction sets cd.tag=0 if cs2 's bounds are malformed, or if any of the reserved fields are set.

Integer Pointer Mode Description: Increment rs2 by the unsigned word in rs1 shifted left by 4 bit positions and write the result to rd.
Exceptions: None
Prerequisites for Capability Pointer Mode: RV64, Zish4add
Prerequisites for Integer Pointer Mode: RV64, Zish4add
Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

8.9. "Zcb" Standard Extension For Code-Size Reduction

8.9.1. C.LH

See C.LBU.

8.9.2. C.LHU

See C.LBU.

8.9.3. C.LBU

Synopsis: Load (C.LH, C.LHU, C.LBU), 16-bit encodings
Capability Pointer Mode Mnemonics: c.lh rd', offset(cs1')
c.lhu rd', offset(cs1')
c.lbu rd', offset(cs1')
Capability Pointer Mode Expansions: lh rd, offset(cs1)
lhu rd, offset(cs1)
lbu rd, offset(cs1)
Integer Pointer Mode Mnemonics: c.lh rd', offset(rs1')
c.lhu rd', offset(rs1')
c.lbu rd', offset(rs1')
Integer Pointer Mode Expansions: lh rd, offset(rs1)
lhu rd, offset(rs1)
lbu rd, offset(rs1)
Encoding

Capability Pointer Mode Description

Subword load instructions, authorised by the capability in cs1.

Integer Pointer Mode Description

Subword load instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

C or Zca, Zcheripurecap, and Zcb

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, and Zcb

Operation (after expansion to 32-bit encodings)

See LHU, LH, LBU

8.9.4. C.SH

See C.SB.

8.9.5. C.SB

Synopsis: Stores (C.SH, C.SB), 16-bit encodings
Capability Pointer Mode Mnemonics: c.sh rs2', offset(cs1')
c.sb rs2', offset(cs1')
Capability Pointer Mode Expansions: sh rs2', offset(cs1')
sb rs2', offset(cs1')
Integer Pointer Mode Mnemonics: c.sh rs2', offset(rs1')
c.sb rs2', offset(rs1')
Integer Pointer Mode Expansions: sh rs2', offset(rs1')
sb rs2', offset(rs1')
Encoding

Capability Pointer Mode Description

Subword store instructions, authorised by the capability in cs1.

Integer Pointer Mode Description

Subword store instructions, authorised by the capability in ddc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

C or Zca, Zcheripurecap, and Zcb

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, and Zcb

Operation (after expansion to 32-bit encodings)

See SH, SB

8.10. "Zcmp" Standard Extension For Code-Size Reduction

The push (CM.PUSH) and pop (CM.POP, CM.POPRET, CM.POPRETZ) instructions are redefined in Capability Pointer Mode to save/restore full capabilities.

The double move instructions (CM.MVSA01, CM.MVA01S) are redefined in Capability Pointer Mode to move full capabilities between registers. The saved register mapping is as shown in

Table 35. saved register mapping for Zcmp
saved register specifier	xreg	integer ABI	CHERI ABI
0	x8	s0	cs0
1	x9	s1	cs1
2	x18	s2	cs2
3	x19	s3	cs3
4	x20	s4	cs4
5	x21	s5	cs5
6	x22	s6	cs6
7	x23	s7	cs7

All instructions are defined in (RISC-V, 2023).

8.10.1. CM.PUSH

Synopsis: Create stack frame (CM.PUSH): store the return address register and 0 to 12 saved registers to the stack frame, optionally allocate additional stack space. 16-bit encodings.
Capability Pointer Mode Mnemonic (RV32): cm.push {creg_list}, -stack_adj
Integer Pointer Mode Mnemonic: cm.push {reg_list}, -stack_adj
Encoding

rlist values 0 to 3 are reserved for a future EABI variant

Capability Pointer Mode Description: Create stack frame, store capability registers as specified in creg_list. Optionally allocate additional multiples of 16-byte stack space. All accesses are checked against csp.
Integer Pointer Mode Description: Create stack frame, store integer registers as specified in reg_list. Optionally allocate additional multiples of 16-byte stack space. All accesses are checked against ddc.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

C or Zca, Zcheripurecap, Zcmp

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, Zcmp

Operation

TBD

8.10.2. CM.POP

Synopsis: Destroy stack frame (CM.POP): load the return address register and 0 to 12 saved registers from the stack frame, deallocate the stack frame. 16-bit encodings.
Capability Pointer Mode Mnemonic (RV32): cm.pop {creg_list}, -stack_adj
Integer Pointer Mode Mnemonic: cm.pop {reg_list}, -stack_adj
Encoding

rlist values 0 to 3 are reserved for a future EABI variant

Capability Pointer Mode Description: Load capability registers as specified in creg_list. Deallocate stack frame. All accesses are checked against csp.
Integer Pointer Mode Description: Load integer registers as specified in reg_list. Deallocate stack frame. All accesses are checked against ddc.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

C or Zca, Zcheripurecap, Zcmp

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, Zcmp

Operation

TBD

8.10.3. CM.POPRET

Synopsis: Destroy stack frame (CM.POPRET): load the return address register and 0 to 12 saved registers from the stack frame, deallocate the stack frame. Return through the return address register. 16-bit encodings.
Capability Pointer Mode Mnemonic (RV32): cm.popret {creg_list}, -stack_adj
Integer Pointer Mode Mnemonic: cm.popret {reg_list}, -stack_adj
Encoding

rlist values 0 to 3 are reserved for a future EABI variant

Capability Pointer Mode Description

Load capability registers as specified in creg_list. Deallocate stack frame. Return by calling JALR to cra. All data accesses are checked against csp. The return destination is checked against cra.

Integer Pointer Mode Description

Load integer registers as specified in reg_list. Deallocate stack frame. Return by calling JALR to ra. All data accesses are checked against ddc. The return destination is checked against pcc.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

C or Zca, Zcheripurecap, Zcmp

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, Zcmp

Operation

TBD

8.10.4. CM.POPRETZ

Synopsis: Destroy stack frame (CM.POPRETZ): load the return address register and register 0 to 12 saved registers from the stack frame, deallocate the stack frame. Move zero into argument register zero. Return through the return address register. 16-bit encodings.
Capability Pointer Mode Mnemonic (RV32): cm.popretz {creg_list}, -stack_adj
Integer Pointer Mode Mnemonic: cm.popretz {reg_list}, -stack_adj
Encoding

rlist values 0 to 3 are reserved for a future EABI variant

Capability Pointer Mode Description: Load capability registers as specified in creg_list. Deallocate stack frame. Move zero into ca0. Return by calling JALR to cra. All data accesses are checked against csp. The return destination is checked against cra.
Integer Pointer Mode Description: Load integer registers as specified in reg_list. Deallocate stack frame. Move zero into a0. Return by calling JALR to ra. All data accesses are checked against ddc. The return destination is checked against pcc.
Permissions: Loads are checked as for LC in both Integer Pointer Mode and Capability Pointer Mode.

The return is checked as for JALR in both Integer Pointer Mode and Capability Pointer Mode.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

C or Zca, Zcheripurecap, Zcmp

Prerequisites for Integer Pointer Mode

C or Zca, Zcherihybrid, Zcmp

Operation

TBD

8.10.5. CM.MVSA01

Synopsis: CM.MVSA01: Move argument registers 0 and 1 into two saved registers.
Capability Pointer Mode Mnemonic (RV32): cm.mvsa01 cr1s', cr2s'
Integer Pointer Mode Mnemonic: cm.mvsa01 r1s', r2s'
Encoding

The encoding uses sreg number specifiers instead of xreg number specifiers to save encoding space. The saved register encoding is shown in Table 35.

Capability Pointer Mode Description: Atomically move two saved capability registers cs0-cs7 into ca0 and ca1.
Integer Pointer Mode Description: Atomically move two saved integer registers s0-s7 into a0 and a1.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap, Zcmp
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid, Zcmp
Operation

TBD

8.10.6. CM.MVA01S

Synopsis: Move two saved registers into argument registers 0 and 1.
Capability Pointer Mode Mnemonic (RV32): cm.mva01s cr1s', cr2s'
Integer Pointer Mode Mnemonic: cm.mva01s r1s', r2s'
Encoding

The encoding uses sreg number specifiers instead of xreg number specifiers to save encoding space. The saved register encoding is shown in Table 35.

Capability Pointer Mode Description: Atomically move two capability registers ca0 and ca1 into cs0-cs7.
Integer Pointer Mode Description: Atomically move two integer registers a0 and a1 into s0-s7.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap, Zcmp
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid, Zcmp
Operation

TBD

8.11. "Zcmt" Standard Extension For Code-Size Reduction

The table jump instructions (CM.JT, CM.JALT) defined in (RISC-V, 2023) are not redefined in Capability Pointer Mode to have capabilities in the jump table. This is to prevent the code-size growth caused by doubling the size of the jump table.

In the future, new jump table modes or new encodings can be added to have capabilities in the jump table.

The jump vector table CSR jvt has a capability alias jvtc so that it can only be configured to point to accessible memory. All accesses to the jump table are checked against jvtc in Capability Pointer Mode, and against pcc bounds in Integer Pointer Mode. This allows the jump table to be accessed when the pcc bounds are set narrowly to the local function only in Capability Pointer Mode.

Zcmt defines that the fetch from the jump table is from instruction memory. The overall instruction executed is effectively 48-bit, with 16-bits from CM.JALT/CM.JT, the other 32-bits (for RV32) from the table. Therefore pcc is used to authorise the fetch in Integer Pointer Mode, as the fetch is designated to be from instruction memory in (RISC-V, 2023).

In Capability Pointer Mode the implementation doesn’t need to expand and bounds check against jvtc on every access, it is sufficient to decode the valid accessible range of entries after every write to jvtc, and then check that the accessed entry is in that range.

8.11.1. Jump Vector Table CSR (jvt)

The JVT CSR is exactly as defined by (RISC-V, 2023). It is renamed to jvtc.

8.11.2. Jump Vector Table CSR (jvtc)

jvtc extends jvt to be a capability width CSR, as shown in Table 17.

Figure 59. Jump Vector Table Capability register

All instruction fetches from the jump vector table are checked against jvtc in Capability Pointer Mode. In Integer Pointer Mode the address field gives the base address of the table, and the access is checked against pcc bounds.

See CM.JALT, CM.JT.

If the access to the jump table succeeds, then the instructions execute as follows:

CM.JT executes as J or AUIPC+JR
CM.JALT executes as JAL or AUIPC+JALR

As a result the capability metadata is retained in pcc during execution.

8.11.3. CM.JALT

Synopsis: Jump via table with link (CM.JALT), 16-bit encodings
Capability Pointer Mode Mnemonic (RV32): cm.jalt index
Integer Pointer Mode Mnemonic: cm.jalt index
Encoding

For this encoding to decode as <CM.JALT, index>=32, otherwise it decodes as CM.JT.

Capability Pointer Mode Description: Redirect instruction fetch via the jump table defined by the indexing via jvtc.address+ index*XLEN/8, checking every byte of the jump table access against jvtc bounds (not against pcc) and requiring X-permission. Link to cra.
Integer Pointer Mode Description: Redirect instruction fetch via the jump table defined by the indexing via jvtc.address+ index*XLEN/8, checking every byte of the jump table access against pcc bounds and requiring X-permission. Link to ra.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Capability Pointer Mode Permissions: Requires jvtc to be tagged, not sealed, have X-permission and for the full XLEN-wide access to be in jvtc bounds.
Capability Pointer Mode Exceptions: When these instructions cause CHERI exceptions, CHERI instruction access fault is reported in the TYPE field and the following codes may be reported in the CAUSE field of mtval or stval:

CAUSE

Tag violation

✔

Seal violation

✔

Permission violation

✔

Invalid address violation

✔

Length violation

✔

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap, Zcmt
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid, Zcmt
Operation

TBD

8.11.4. CM.JT

Synopsis: Jump via table with link (CM.JT), 16-bit encodings
Capability Pointer Mode Mnemonic: cm.jt index
Integer Pointer Mode Mnemonic: cm.jt index
Encoding

For this encoding to decode as CM.JT, index<32, otherwise it decodes as CM.JALT.

Capability Pointer Mode Description: Redirect instruction fetch via the jump table defined by the indexing via jvtc.address+ index*XLEN/8, checking every byte of the jump table access against jvtc bounds (not against pcc) and requiring X-permission.
Integer Pointer Mode Description: Redirect instruction fetch via the jump table defined by the indexing via jvtc.address+ index*XLEN/8, checking every byte of the jump table access against pcc bounds and requiring X-permission.

This encoding conflicts with C.FSDSP which is remapped to C.SCSP in RV64 Capability Pointer Mode.

Capability Pointer Mode Permissions: Requires jvtc to be tagged, not sealed, have X-permission and for the full XLEN-wide access to be in jvtc bounds.
Capability Pointer Mode Exceptions: When these instructions cause CHERI exceptions, CHERI instruction access fault is reported in the TYPE field and the following codes may be reported in the CAUSE field of mtval or stval:

CAUSE

Tag violation

✔

Seal violation

✔

Permission violation

✔

Invalid address violation

✔

Length violation

✔

Prerequisites for Capability Pointer Mode: C or Zca, Zcheripurecap, Zcmt
Prerequisites for Integer Pointer Mode: C or Zca, Zcherihybrid, Zcmt
Operation

TBD

8.12. "H" Extension for Hypervisor Support

8.12.1. HLV.B

See HLV.W.

8.12.2. HLV.BU

See HLV.W.

8.12.3. HLV.H

See HLV.W.

8.12.4. HLV.HU

See HLV.W.

8.12.5. HLV.WU

See HLV.W.

8.12.6. HLV.D

See HLV.W.

8.12.7. HLV.W

Synopsis: Hypervisor virtual-machine load
Capability Pointer Mode Mnemonics (RV64): hlv.b[u] rd, cs1
hlv.h[u] rd, cs1
hlv.w[u] rd, cs1
hlv.d rd, cs1
Integer Pointer Mode Mnemonics (RV64): hlv.b[u] rd, rs1
hlv.h[u] rd, rs1
hlv.w[u] rd, rs1
hlv.d rd, rs1
Capability Pointer Mode Mnemonics (RV32): hlv.b[u] rd, cs1
hlv.h[u] rd, cs1
hlv.w rd, cs1
Integer Pointer Mode Mnemonics (RV32): hlv.b[u] rd, rs1
hlv.h[u] rd, rs1
hlv.w rd, rs1
Encoding

Capability Pointer Mode Description

Performs a load as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is the address of cs1. The authorising capability for the operation is cs1. A copy of the loaded value is written to rd.

Integer Pointer Mode Description

Performs a load as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is the is rs1. The authorising capability for the operation is ddc. A copy of the loaded value is written to rd.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode HLV.B[U], HLV.H[U], HLV.W

Zcheripurecap, H

Prerequisites for Integer Pointer Mode HLV.B[U], HLV.H[U], HLV.W

Zcheripurecap, Zcherihybrid, H

Prerequisites for Capability Pointer Mode HLV.WU, HLV.D

RV64, Zcheripurecap, H

Prerequisites for Integer Pointer Mode HLV.WU, HLV.D

RV64, Zcheripurecap, Zcherihybrid, H

Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

8.12.8. HLV.C

Synopsis: Hypervisor virtual-machine load capability
Capability Pointer Mode Mnemonic: hlv.c cd, cs1
Integer Pointer Mode Mnemonic: hlv.c cd, rs1
Encoding

Capability Pointer Mode Description: Load a CLEN+1 bit value from memory as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is the address of cs1. The authorising capability for the operation is cs1. A copy of the loaded value is written to cd.
Integer Pointer Mode Description: Load a CLEN+1 bit value from memory as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode and VU-mode. The effective address is rs1. The authorising capability for the operation is ddc. A copy of the loaded value is written to cd.
Resulting value of cd: The tag value written to cd is 0 if the tag of the memory location loaded is 0 or the authorizing capability (ddc or cs1) does not grant C-permission.

If the authorizing capability does not grant LM-permission, and the tag of cd is 1 and cd is not sealed, then an implicit ACPERM clearing W-permission and LM-permission is performed to obtain the final permissions on cd.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions

Misaligned address fault exception when the effective address is not aligned to CLEN/8.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites for Capability Pointer Mode

Zcheripurecap, H

Prerequisites for Integer Pointer Mode

Zcheripurecap, Zcherihybrid, H

Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

8.12.9. HSV.B

See HSV.W.

8.12.10. HSV.H

See HSV.W.

8.12.11. HSV.D

See HSV.W.

8.12.12. HSV.W

Synopsis: Hypervisor virtual-machine store
Capability Pointer Mode Mnemonics (RV64): hsv.b rs2, cs1
hsv.h rs2, cs1
hsv.w rs2, cs1
hsv.d rs2, cs1
Integer Pointer Mode Mnemonics (RV64): hsv.b rs2, rs1
hsv.h rs2, rs1
hsv.w rs2, rs1
hsv.d rs2, rs1
Capability Pointer Mode Mnemonics (RV32): hsv.b rs2, cs1
hsv.h rs2, cs1
hsv.w rs2, cs1
Integer Pointer Mode Mnemonics (RV32): hsv.b rs2, rs1
hsv.h rs2, rs1
hsv.w rs2, rs1
Encoding

Capability Pointer Mode Description

Performs a store as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is the address of cs1. The authorising capability for the operation is cs1. A copy of rs2 is written to memory at the location indicated by the effective address and the tag bit of each block of memory naturally aligned to CLEN/8 is cleared.

Integer Pointer Mode Description

Performs a store as though V=1; i.e., with address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is rs1. The authorising capability for the operation is ddc. A copy of rs2 is written to memory at the location indicated by the effective address and the tag bit of each block of memory naturally aligned to CLEN/8 is cleared.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode HSV.B, HSV.H, HSV.W

Zcheripurecap, H

Prerequisites for Integer Pointer Mode HSV.B, HSV.H, HSV.W

Zcheripurecap, Zcherihybrid H

Prerequisites for Capability Pointer Mode HSV.D

RV64, Zcheripurecap, H

Prerequisites for Integer Pointer Mode HSV.D

RV64, Zcheripurecap, Zcherihybrid H

Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

8.12.13. HSV.C

Synopsis: Hypervisor virtual-machine store capability
Capability Pointer Mode Mnemonic: hsv.c cs2, cs1
Integer Pointer Mode Mnemonic: hsv.c cs2, rs1
Encoding

Capability Pointer Mode Description: Store a CLEN+1 bit value in cs2 to memory as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is the address of cs1. The authorising capability for the operation is cs1. The capability written to memory has the tag set to 0 if the tag of cs2 is 0 or cs1 does not grant C-permission.
Integer Pointer Mode Description: Store a CLEN+1 bit value in cs2 to memory as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory accesses in either VS-mode or VU-mode. The effective address is the rs1. The authorising capability for the operation is ddc. The capability written to memory has the tag set to 0 if the tag of cs2 is 0 or ddc does not grant C-permission.

This instruction can propagate tagged capabilities which have malformed bounds, have reserved bits set or have a permission field which cannot be produced by ACPERM.

Exceptions

Misaligned address fault exception when the effective address is not aligned to CLEN/8.

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant W-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

This instruction is illegal if the CHERI register access is disabled for the current privilege.

Prerequisites for Capability Pointer Mode

Zcheripurecap, H

Prerequisites for Integer Pointer Mode

Zcheripurecap, Zcherihybrid, H

Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

8.12.14. HLVX.HU

See HLVX.WU.

8.12.15. HLVX.WU

Synopsis: Hypervisor virtual machine load from executable memory
Capability Pointer Mode Mnemonics: hlv.hu rd, cs1
hlv.wu rd, cs1
Integer Pointer Mode Mnemonics: hlv.hu rd, rs1
hlv.wu rd, rs1
Encoding

Capability Pointer Mode Description

Performs a load with the execute permission taking the place of read permission during address translation and as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory access in either VS-mode or VU-mode. The effective address is the address of cs1. The authorising capability for the operation is cs1. A copy of the loaded value is written to rd.

Integer Pointer Mode Description

Performs a load with the execute permission taking the place of read permission during address translation and as though V=1; i.e., with the address translation and protection, and endianness, that apply to memory access in either VS-mode or VU-mode. The effective address is rs1. The authorising capability for the operation is ddc. A copy of the loaded value is written to rd.

Exceptions

CAUSE

Reason

Tag violation

Authority capability tag set to 0, or has any reserved bits set

Seal violation

Authority capability is sealed

Permission violation

Authority capability does not grant R-permission or X-permission, or the AP field could not have been produced by ACPERM

Invalid address violation

The effective address is invalid according to Invalid address conversion

Length violation

At least one byte accessed is outside the authority capability bounds, or the capability has malformed bounds

Prerequisites for Capability Pointer Mode

Zcheripurecap, H

Prerequisites for Integer Pointer Mode

Zcheripurecap, Zcherihybrid, H

Capability Pointer Mode Operation

TBD

Integer Pointer Mode Operation

TBD

9. Extension summary

9.1. Zabhlrsc

Zabhlrsc is a separate extension independent of CHERI, but is required for CHERI software.

These instructions are not controlled by the CRE bits in mseccfg, menvcfg or senvcfg.

Table 36. Zabhlrsc instruction extension
Mnemonic	Zabhlrsc	Function
LR.H	✔	Load reserved half
LR.B	✔	Load reserved byte
SC.H	✔	Store conditional half
SC.B	✔	Store conditional byte

9.2. Zish4add

Zish4add is a separate extension independent of CHERI, but improves performance for CHERI code as the natural data width of pointers has doubled.

These instructions are not controlled by the CRE bits in mseccfg, menvcfg or senvcfg.

Table 37. Zish4add instruction extension
Mnemonic	Zish4add	Function
SH4ADD	✔	shift and add, representability check in Capability Mode
SH4ADD.UW	✔	shift and add unsigned words, representability check in Capability Mode

9.3. Zcheripurecap

Zcheripurecap defines the set of instructions used by a purecap core.

Some instructions depend on the presence of other extensions, as listed in Table 38

Table 38. Zcheripurecap instruction extension - Pure *Capability Pointer Mode* instructions
Mnemonic	RV32	RV64	A	Zabhlrsc	Zicbo[mpz]	C or Zca	Zba	Zcb	Zcmp	Zcmt	Zfh	F	D	Function
LC	✔	✔												Load cap via capability register
SC	✔	✔												Store cap via capability register
C.LCSP	✔	✔				✔								Load cap capability, SP relative
C.SCSP	✔	✔				✔								Store cap capability, SP relative
C.LC	✔	✔				✔								Load cap capability
C.SC	✔	✔				✔								Store cap capability
C.LWSP	✔	✔				✔								Load word capability, SP relative
C.SWSP	✔	✔				✔								Store word capability, SP relative
C.LW	✔	✔				✔								Load word capability
C.SW	✔	✔				✔								Store word capability
C.LD		✔				✔								Load word capability
C.SD		✔				✔								Store word capability
C.LDSP		✔				✔								Load word capability
C.SDSP		✔				✔								Store word capability
LB	✔	✔												Load signed byte
LH	✔	✔												Load signed half
C.LH	✔	✔						✔						Load signed half
LW	✔	✔												Load signed word
LBU	✔	✔												Load unsigned byte
C.LBU	✔	✔						✔						Load unsigned byte
LHU	✔	✔												Load unsigned half
C.LHU	✔	✔						✔						Load unsigned half
LWU		✔												Load unsigned word
LD		✔												Load double
SB	✔	✔												Store byte
C.SB	✔	✔						✔						Store byte
SH	✔	✔												Store half
C.SH	✔	✔						✔						Store half
SW	✔	✔												Store word
SD		✔												Store double
AUIPC	✔	✔												Add immediate to PCC address
CADD	✔	✔												Increment cap address by register, representability check
CADDI	✔	✔												Increment cap address by immediate, representability check
SCADDR	✔	✔												Replace capability address, representability check
GCTAG	✔	✔												Get tag field
GCPERM	✔	✔												Get hperm and uperm fields as 1-bit per permission, packed together
CMV	✔	✔												Move capability register
ACPERM	✔	✔												AND capability permissions (expand to 1-bit per permission before ANDing)
GCHI	✔	✔												Get metadata
SCHI	✔	✔												Set metadata and clear tag
SCEQ	✔	✔												Full capability bitwise compare, set result true if both are fully equal
SENTRY	✔	✔												Seal capability
SCSS	✔	✔												Set result true if cs1 and cs1 tags match and cs2 bounds and permissions are a subset of cs1
CBLD	✔	✔												Set cd to cs2 with its tag set after checking that cs2 is a subset of cs1
SCBNDS	✔	✔												Set register bounds on capability with rounding, clear tag if rounding is required
SCBNDSI	✔	✔												Set immediate bounds on capability with rounding, clear tag if rounding is required
SCBNDSR	✔	✔												Set bounds on capability with rounding up as required
CRAM	✔	✔												Representable Alignment Mask: Return mask to apply to address to get the requested bounds
GCBASE	✔	✔												Get capability base
GCLEN	✔	✔												Get capability length
GCTYPE	✔	✔												Get capability type
C.ADDI16SP	✔	✔				✔								ADD immediate to stack pointer, CADD in Capability Mode
C.ADDI4SPN	✔	✔				✔								ADD immediate to stack pointer, CADDI in Capability Mode
C.MV	✔	✔				✔								Register Move, cap reg move in Capability Mode
C.J	✔	✔				✔								Jump to PC+offset, bounds check minimum size target instruction
C.JAL	✔					✔								Jump to PC+offset, bounds check minimum size target instruction, link to cd
JAL	✔	✔				✔								Jump to PC+offset, bounds check minimum size target instruction, link to cd
JALR	✔	✔												Indirect cap jump and link, bounds check minimum size target instruction, unseal target cap, seal link cap
C.JALR	✔	✔				✔								Indirect cap jump and link, bounds check minimum size target instruction, unseal target cap, seal link cap
C.JR	✔	✔				✔								Indirect cap jump, bounds check minimum size target instruction, unseal target cap
CBO.INVAL	✔	✔			✔									Cache block invalidate (implemented as clean)
CBO.CLEAN	✔	✔			✔									Cache block clean
CBO.FLUSH	✔	✔			✔									Cache block flush
CBO.ZERO	✔	✔			✔									Cache block zero
PREFETCH.R	✔	✔			✔									Prefetch instruction cache line, always valid
PREFETCH.W	✔	✔			✔									Prefetch read-only data cache line
PREFETCH.I	✔	✔			✔									Prefetch writeable data cache line
LR.C	✔	✔	✔											Load reserved capability
LR.D			✔											Load reserved double
LR.W			✔											Load reserved word
LR.H	✔	✔		✔										Load reserved half
LR.B	✔	✔		✔										Load reserved byte
SC.C	✔	✔	✔											Store conditional capability
SC.D			✔											Store conditional double
SC.W			✔											Store conditional word
SC.H	✔	✔		✔										Store conditional half
SC.B	✔	✔		✔										Store conditional byte
AMOSWAP.C	✔	✔	✔											Atomic swap of cap
AMO<OP>.W	✔	✔	✔											Atomic op of word
AMO<OP>.D		✔	✔											Atomic op of double
C.FLD	✔												✔	Load floating point double
C.FLDSP	✔												✔	Load floating point double, sp relative
C.FSD	✔												✔	Store floating point double
C.FSDSP	✔												✔	Store floating point double, sp relative
FLH	✔	✔									✔			Load floating point half capability
FSH	✔	✔									✔			Store floating point half capability
FLW	✔	✔										✔		Load floating point word capability
FSW	✔	✔										✔		Store floating point word capability
FLD	✔	✔											✔	Load floating point double capability
FSD	✔	✔											✔	Store floating point double capability
CM.PUSH	✔	✔							✔					Push integer stack frame
CM.POP	✔	✔							✔					Pop integer stack frame
CM.POPRET	✔	✔							✔					Pop integer stack frame and return
CM.POPRETZ	✔	✔							✔					Pop integer stack frame and return zero
CM.MVSA01	✔	✔							✔					Move two integer registers
CM.MVA01S	✔	✔							✔					Move two integer registers
CM.JALT	✔	✔								✔				Table jump and link
CM.JT	✔	✔								✔				Table jump
ADD.UW		✔					✔							add unsigned words, representability check in Capability Mode
SH1ADD	✔	✔					✔							shift and add, representability check in Capability Mode
SH1ADD.UW		✔					✔							shift and add unsigned words, representability check in Capability Mode
SH2ADD	✔	✔					✔							shift and add, representability check in Capability Mode
SH2ADD.UW		✔					✔							shift and add unsigned words, representability check in Capability Mode
SH3ADD	✔	✔					✔							shift and add, representability check in Capability Mode
SH3ADD.UW		✔					✔							shift and add unsigned words, representability check in Capability Mode
HLV.B	✔	✔												Hypervisor virtual machine load byte
HLV.BU	✔	✔												Hypervisor virtual machine load unsigned byte
HLV.H	✔	✔												Hypervisor virtual machine load half word
HLV.HU	✔	✔												Hypervisor virtual machine load unsigned half word
HLV.W	✔	✔												Hypervisor virtual machine load word
HLV.WU		✔												Hypervisor virtual machine load unsigned word
HLV.D		✔												Hypervisor virtual machine load double
HLV.C	✔	✔												Hypervisor virtual machine load capability
HSV.B	✔	✔												Hypervisor virtual machine store byte
HSV.H	✔	✔												Hypervisor virtual machine store half word
HSV.W	✔	✔												Hypervisor virtual machine store word
HSV.D		✔												Hypervisor virtual machine store double
HSV.C	✔	✔												Hypervisor virtual machine store capability
HLVX.HU	✔	✔												Hypervisor virtual machine load half word from executable memory
HLVX.WU	✔	✔												Hypervisor virtual machine load wordfrom executable memory

9.4. Zcherihybrid

Zcherihybrid defines the set of instructions added by the Integer Pointer Mode, in addition to Zcheripurecap.

Zcherihybrid implies Zcheripurecap

Table 39. Zcherihybrid instruction extension - *Integer Pointer Mode* instructions
Mnemonic	RV32	RV64	F	D	Function
SCMODE	✔	✔			Set the mode bit of a capability, no permissions required
GCMODE	✔	✔			Get the mode bit of a capability, no permissions required
MODESW	✔	✔			Directly switch mode (Integer Pointer Mode/ Capability Pointer Mode)
C.MODESW	✔	✔			Directly switch mode (Integer Pointer Mode/ Capability Pointer Mode)
C.FLW	✔		✔		Load floating point word capability
C.FLWSP	✔		✔		Load floating point word, sp relative
C.FSW	✔		✔		Store floating point word capability
C.FSWSP	✔		✔		Store floating point word, sp relative
C.FLD		✔		✔	Load floating point double
C.FLDSP		✔		✔	Load floating point double, sp relative
C.FSD		✔		✔	Store floating point double
C.FSDSP		✔		✔	Store floating point double, sp relative

9.5. Instruction Modes

The tables summarise which operating modes each instruction may be executed in.

Table 40. Instructions valid for execution in *Capability Pointer Mode* only
Mnemonic	Zcheripurecap	Function
C.LCSP	✔	Load cap capability, SP relative
C.SCSP	✔	Store cap capability, SP relative
C.LC	✔	Load cap capability
C.SC	✔	Store cap capability

Table 41. Instructions valid for execution in *Integer Pointer Mode* only
Mnemonic	Zcherihybrid	Function
C.FLW	✔	Load floating point word capability
C.FLWSP	✔	Load floating point word, sp relative
C.FSW	✔	Store floating point word capability
C.FSWSP	✔	Store floating point word, sp relative
C.FLD	✔	Load floating point double
C.FLDSP	✔	Load floating point double, sp relative
C.FSD	✔	Store floating point double
C.FSDSP	✔	Store floating point double, sp relative

Table 42. Instructions valid for execution in both *Integer Pointer Mode* and *Capability Pointer Mode*
Mnemonic	Zcherihybrid	Zcheripurecap	Function
LC	✔	✔	Load cap via int pointer
SC	✔	✔	Store cap via int pointer
C.LWSP	✔	✔	Load word capability, SP relative
C.SWSP	✔	✔	Store word capability, SP relative
C.LW	✔	✔	Load word capability
C.SW	✔	✔	Store word capability
C.LD	✔	✔	Load word capability
C.SD	✔	✔	Store word capability
C.LDSP	✔	✔	Load word capability
C.SDSP	✔	✔	Store word capability
LB	✔	✔	Load signed byte
LH	✔	✔	Load signed half
C.LH	✔	✔	Load signed half
LW	✔	✔	Load signed word
LBU	✔	✔	Load unsigned byte
C.LBU	✔	✔	Load unsigned byte
LHU	✔	✔	Load unsigned half
C.LHU	✔	✔	Load unsigned half
LWU	✔	✔	Load unsigned word
LD	✔	✔	Load double
SB	✔	✔	Store byte
C.SB	✔	✔	Store byte
SH	✔	✔	Store half
C.SH	✔	✔	Store half
SW	✔	✔	Store word
SD	✔	✔	Store double
AUIPC	✔	✔	Add immediate to PCC address
CADD	✔	✔	Increment cap address by register, representability check
CADDI	✔	✔	Increment cap address by immediate, representability check
SCADDR	✔	✔	Replace capability address, representability check
GCTAG	✔	✔	Get tag field
GCPERM	✔	✔	Get hperm and uperm fields as 1-bit per permission, packed together
CMV	✔	✔	Move capability register
ACPERM	✔	✔	AND capability permissions (expand to 1-bit per permission before ANDing)
GCHI	✔	✔	Get metadata
SCHI	✔	✔	Set metadata and clear tag
SCEQ	✔	✔	Full capability bitwise compare, set result true if both are fully equal
SENTRY	✔	✔	Seal capability
SCSS	✔	✔	Set result true if cs1 and cs1 tags match and cs2 bounds and permissions are a subset of cs1
CBLD	✔	✔	Set cd to cs2 with its tag set after checking that cs2 is a subset of cs1
SCBNDS	✔	✔	Set register bounds on capability with rounding, clear tag if rounding is required
SCBNDSI	✔	✔	Set immediate bounds on capability with rounding, clear tag if rounding is required
SCBNDSR	✔	✔	Set bounds on capability with rounding up as required
CRAM	✔	✔	Representable Alignment Mask: Return mask to apply to address to get the requested bounds
GCBASE	✔	✔	Get capability base
GCLEN	✔	✔	Get capability length
GCTYPE	✔	✔	Get capability type
SCMODE	✔		Set the mode bit of a capability, no permissions required
GCMODE	✔		Get the mode bit of a capability, no permissions required
MODESW	✔		Directly switch mode (Integer Pointer Mode/ Capability Pointer Mode)
C.MODESW	✔		Directly switch mode (Integer Pointer Mode/ Capability Pointer Mode)
C.ADDI16SP	✔	✔	ADD immediate to stack pointer, CADD in Capability Mode
C.ADDI4SPN	✔	✔	ADD immediate to stack pointer, CADDI in Capability Mode
C.MV	✔	✔	Register Move, cap reg move in Capability Mode
C.J	✔	✔	Jump to PC+offset, bounds check minimum size target instruction
C.JAL	✔	✔	Jump to PC+offset, bounds check minimum size target instruction, link to cd
JAL	✔	✔	Jump to PC+offset, bounds check minimum size target instruction, link to cd
JALR	✔	✔	Indirect cap jump and link, bounds check minimum size target instruction, unseal target cap, seal link cap
C.JALR	✔	✔	Indirect cap jump and link, bounds check minimum size target instruction, unseal target cap, seal link cap
C.JR	✔	✔	Indirect cap jump, bounds check minimum size target instruction, unseal target cap
DRET			Return from debug mode, sets ddc from dddc and pcc from dpcc
MRET			Return from machine mode handler, sets pcc from mtvecc , needs ASR-permission
SRET			Return from supervisor mode handler, sets pcc from stvecc, needs ASR-permission
CSRRW			CSR write - can also read/write a full capability through an address alias
CSRRS			CSR set - can also read/write a full capability through an address alias
CSRRC			CSR clear - can also read/write a full capability through an address alias
CSRRWI			CSR write - can also read/write a full capability through an address alias
CSRRSI			CSR set - can also read/write a full capability through an address alias
CSRRCI			CSR clear - can also read/write a full capability through an address alias
CBO.INVAL	✔	✔	Cache block invalidate (implemented as clean)
CBO.CLEAN	✔	✔	Cache block clean
CBO.FLUSH	✔	✔	Cache block flush
CBO.ZERO	✔	✔	Cache block zero
PREFETCH.R	✔	✔	Prefetch instruction cache line, always valid
PREFETCH.W	✔	✔	Prefetch read-only data cache line
PREFETCH.I	✔	✔	Prefetch writeable data cache line
LR.C	✔	✔	Load reserved capability
LR.D	✔	✔	Load reserved double
LR.W	✔	✔	Load reserved word
LR.H	✔	✔	Load reserved half
LR.B	✔	✔	Load reserved byte
SC.C	✔	✔	Store conditional capability
SC.D	✔	✔	Store conditional double
SC.W	✔	✔	Store conditional word
SC.H	✔	✔	Store conditional half
SC.B	✔	✔	Store conditional byte
AMOSWAP.C	✔	✔	Atomic swap of cap
AMO<OP>.W	✔	✔	Atomic op of word
AMO<OP>.D	✔	✔	Atomic op of double
C.FLD	✔	✔	Load floating point double
C.FLDSP	✔	✔	Load floating point double, sp relative
C.FSD	✔	✔	Store floating point double
C.FSDSP	✔	✔	Store floating point double, sp relative
FLH	✔	✔	Load floating point half capability
FSH	✔	✔	Store floating point half capability
FLW	✔	✔	Load floating point word capability
FSW	✔	✔	Store floating point word capability
FLD	✔	✔	Load floating point double capability
FSD	✔	✔	Store floating point double capability
CM.PUSH	✔	✔	Push integer stack frame
CM.POP	✔	✔	Pop integer stack frame
CM.POPRET	✔	✔	Pop integer stack frame and return
CM.POPRETZ	✔	✔	Pop integer stack frame and return zero
CM.MVSA01	✔	✔	Move two integer registers
CM.MVA01S	✔	✔	Move two integer registers
CM.JALT	✔	✔	Table jump and link
CM.JT	✔	✔	Table jump
ADD.UW	✔	✔	add unsigned words, representability check in Capability Mode
SH1ADD	✔	✔	shift and add, representability check in Capability Mode
SH1ADD.UW	✔	✔	shift and add unsigned words, representability check in Capability Mode
SH2ADD	✔	✔	shift and add, representability check in Capability Mode
SH2ADD.UW	✔	✔	shift and add unsigned words, representability check in Capability Mode
SH3ADD	✔	✔	shift and add, representability check in Capability Mode
SH3ADD.UW	✔	✔	shift and add unsigned words, representability check in Capability Mode
SH4ADD			shift and add, representability check in Capability Mode
SH4ADD.UW			shift and add unsigned words, representability check in Capability Mode
HLV.B	✔	✔	Hypervisor virtual machine load byte
HLV.BU	✔	✔	Hypervisor virtual machine load unsigned byte
HLV.H	✔	✔	Hypervisor virtual machine load half word
HLV.HU	✔	✔	Hypervisor virtual machine load unsigned half word
HLV.W	✔	✔	Hypervisor virtual machine load word
HLV.WU	✔	✔	Hypervisor virtual machine load unsigned word
HLV.D	✔	✔	Hypervisor virtual machine load double
HLV.C	✔	✔	Hypervisor virtual machine load capability
HSV.B	✔	✔	Hypervisor virtual machine store byte
HSV.H	✔	✔	Hypervisor virtual machine store half word
HSV.W	✔	✔	Hypervisor virtual machine store word
HSV.D	✔	✔	Hypervisor virtual machine store double
HSV.C	✔	✔	Hypervisor virtual machine store capability
HLVX.HU	✔	✔	Hypervisor virtual machine load half word from executable memory
HLVX.WU	✔	✔	Hypervisor virtual machine load wordfrom executable memory

10. Capability Width CSR Summary

Table 43. CSRs renamed and extended to capability width
CLEN CSR	Alias	Prerequisites
dpcc	dpc	Sdext
dscratch0c	dscratch0	Sdext
dscratch1c	dscratch1	Sdext
mtvecc	mtvec	M-mode
mscratchc	mscratch	M-mode
mepcc	mepc	M-mode
stvecc	stvec	S-mode
sscratchc	sscratch	S-mode
sepcc	sepc	S-mode
vstvecc	vstvec	H
vsscratchc	vsscratch	H
vsepcc	vsepc	H
jvtc	jvt	Zcmt
utidc	utid	Zstid
stidc	stid	Zstid
vstidc	vstid	Zstid
mtidc	mtid	Zstid

Table 44. Action taken on writing to extended CSRs^**
CLEN CSR	Action on XLEN write	Action on CLEN write
dpcc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
dscratch0c	Update the CSR using SCADDR.	direct write
dscratch1c	Update the CSR using SCADDR.	direct write
mtvecc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change, including the MODE field in the address for simplicity. Vector range check ^* if vectored mode is programmed.	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change, including the MODE field in the address for simplicity. Vector range check ^* if vectored mode is programmed.
mscratchc	Update the CSR using SCADDR.	direct write
mepcc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
stvecc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change, including the MODE field in the address for simplicity. Vector range check ^* if vectored mode is programmed.	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change, including the MODE field in the address for simplicity. Vector range check ^* if vectored mode is programmed.
sscratchc	Update the CSR using SCADDR.	direct write
sepcc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
vstvecc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change, including the MODE field in the address for simplicity. Vector range check ^* if vectored mode is programmed.	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change, including the MODE field in the address for simplicity. Vector range check ^* if vectored mode is programmed.
vsscratchc	Update the CSR using SCADDR.	direct write
vsepcc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
jvtc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
utidc	Update the CSR using SCADDR.	direct write
stidc	Update the CSR using SCADDR.	direct write
vstidc	Update the CSR using SCADDR.	direct write
mtidc	Update the CSR using SCADDR.	direct write

^* The vector range check is to ensure that vectored entry to the handler is within bounds of the capability written to Xtvecc. The check on writing must include the lowest (0 offset) and highest possible offset (e.g. 64 * MXLEN bits where HICAUSE=16).

^** XLEN bits of extended capability CSRs are written when executing CSRRWI, CSRRC, CSRRS, CSRRCI or CSRRSI regardless of the CHERI execution mode. When using CSRRW, CLEN bits are written when the CHERI execution mode is Capability Pointer Mode and XLEN bits are written when the mode is Integer Pointer Mode; therefore, writing XLEN bits with CSRRW is only possible when Zcherihybrid is implemented.

Table 45. Action taken on writing to new capability CSRs⁺
CLEN CSR	Action on XLEN write	Action on CLEN write
dddc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
mtdc	Update the CSR using SCADDR.	direct write
stdc	Update the CSR using SCADDR.	direct write
vstdc	Update the CSR using SCADDR.	direct write
ddc	Apply Invalid address conversion. Always update the CSR with SCADDR even if the address didn’t change.	Apply Invalid address conversion and update the CSR with the result if the address changed, direct write if address didn’t change
dinfc	Ignore	Ignore

⁺ XLEN bits of new capability CSRs added in Zcherihybrid are written when executing CSRRWI, CSRRC, CSRRS, CSRRCI or CSRRSI regardless of the CHERI execution mode. CLEN bits are always written when using CSRRW regardless of the CHERI execution mode.

Implementations which allow misa.C to be writable need to legalise Xepcc on reading if the misa.C value has changed since the value was written as this can cause the read value of bit [1] to change state.

Table 46. CLEN-wide CSRs storing executable vectors or data pointers
CLEN CSR	Executable Vector	Data Pointer	Unseal On Execution
dpcc	✔		✔
mtvecc	✔
mepcc	✔		✔
stvecc	✔
sepcc	✔		✔
vstvecc	✔
vsepcc	✔		✔
jvtc	✔
dddc		✔
ddc		✔

Some CSRs store executable vectors or data pointers as shown in Table 46. These CSRs do not need to store the full width address on RV64. If they store fewer address bits then writes are subject to the invalid address check in Invalid address conversion.

Table 47. CLEN-wide CSRs which store all CLEN+1 bits
CLEN CSR	Store full metadata
dscratch0c	✔
dscratch1c	✔
mscratchc	✔
sscratchc	✔
vsscratchc	✔
dinfc	✔
utidc	✔
stidc	✔
vstidc	✔
mtidc	✔

Table 47 shows which CLEN-wide CSRs store all CLEN+1 bits. No other CLEN-wide CSRs store any reserved bits. All CLEN-wide CSRs store all non-reserved metadata fields.

Table 48. All CLEN-wide CSRs. Zcheripurecap is a prerequisite for all CSRs in this table
CLEN CSR	Prerequisites	Address	Permissions	Reset Value	Description
dpcc	Sdext	0x7b1	DRW	tag=0, otherwise undefined	Debug Program Counter Capability
dscratch0c	Sdext	0x7b2	DRW	tag=0, otherwise undefined	Debug Scratch Capability 0
dscratch1c	Sdext	0x7b3	DRW	tag=0, otherwise undefined	Debug Scratch Capability 1
mtvecc	M-mode	0x305	MRW, ASR-permission	Infinite	Machine Trap-Vector Base-Address Capability
mscratchc	M-mode	0x340	MRW, ASR-permission	tag=0, otherwise undefined	Machine Scratch Capability
mepcc	M-mode	0x341	MRW, ASR-permission	Infinite	Machine Exception Program Counter Capability
stvecc	S-mode	0x105	SRW, ASR-permission	Infinite	Supervisor Trap-Vector Base-Address Capability
sscratchc	S-mode	0x140	SRW, ASR-permission	tag=0, otherwise undefined	Supervisor Scratch Capability
sepcc	S-mode	0x141	SRW, ASR-permission	Infinite	Supervisor Exception Program Counter Capability
vstvecc	H	0x205	HRW, ASR-permission	Infinite	Virtual Supervisor Trap-Vector Base-Address Capability
vsscratchc	H	0x240	HRW, ASR-permission	tag=0, otherwise undefined	Virtual Supervisor Scratch Capability
vsepcc	H	0x241	HRW, ASR-permission	Infinite	Virtual Supervisor Exception Program Counter Capability
jvtc	Zcmt	0x017	URW	tag=0, otherwise undefined	Jump Vector Table Capability
dddc	Zcherihybrid, Sdext	0x7bc	DRW	tag=0, otherwise undefined	Debug Default Data Capability (saved/restored on debug mode entry/exit)
mtdc	Zcherihybrid, M-mode	0x74c	MRW, ASR-permission	tag=0, otherwise undefined	Machine Trap Data Capability (scratch register)
stdc	Zcherihybrid, S-mode	0x163	SRW, ASR-permission	tag=0, otherwise undefined	Supervisor Trap Data Capability (scratch register)
vstdc	Zcherihybrid, H	0x245	HRW, ASR-permission	tag=0, otherwise undefined	Virtual Supervisor Trap Data Capability (scratch register)
ddc	Zcherihybrid	0x416	URW	Infinite	User Default Data Capability
dinfc	Sdext	0x7bd	DRW	Infinite	Source of Infinite capability in debug mode, writes are ignored
utidc	Zstid	0x480	Read: U, Write: U, ASR-permission	tag=0, otherwise undefined	User thread ID
stidc	Zstid	0x580	Read: S, Write: S, ASR-permission	tag=0, otherwise undefined	Supervisor thread ID
vstidc	Zstid	0xA80	Read: VS, Write: VS, ASR-permission	tag=0, otherwise undefined	Virtual supervisor thread ID
mtidc	Zstid	0x780	Read: M, Write: M, ASR-permission	tag=0, otherwise undefined	Machine thread ID

10.1. Other tables

Table 49. Mnemonics with the same encoding but mapped to different instructions in *Integer Pointer Mode* and *Capability Pointer Mode*
Mnemonic	Integer Pointer Mode mnemonic RV32	Integer Pointer Mode mnemonic RV64
C.LCSP	C.FLWSP	C.FLDSP
C.SCSP	C.FSWSP	C.FSDSP
C.LC	C.FLW	C.FLD
C.SC	C.FSW	C.FSD

Table 50. Instruction encodings which vary depending on the current XLEN
Mnemonic	Function
LC	Load cap via int pointer
SC	Store cap via int pointer
C.LCSP	Load cap capability, SP relative
C.SCSP	Store cap capability, SP relative
C.LC	Load cap capability
C.SC	Store cap capability
LR.C	Load reserved capability
SC.C	Store conditional capability
AMOSWAP.C	Atomic swap of cap

MODESW and SCMODE only exist in Capability Pointer Mode if Integer Pointer Mode is also present. A purecap core does not implement the mode bit in the capability.

Table 51. Illegal instruction detect for CHERI instructions
Mnemonic	illegal insn if (1)	OR illegal insn if (2)	OR illegal insn if (3)
MODESW	mode==D (optional)
C.MODESW	mode==D (optional)
C.J	mode==D (optional)
C.JAL	mode==D (optional)
JAL	mode==D (optional)
JALR	mode==D (optional)
C.JALR	mode==D (optional)
C.JR	mode==D (optional)
DRET	MODE<D
MRET	MODE<M	PCC.ASR==0
SRET	MODE<S	PCC.ASR==0	mstatus.TSR==1 AND MODE==S
CSRRW	CSR permission fault
CSRRS	CSR permission fault
CSRRC	CSR permission fault
CSRRWI	CSR permission fault
CSRRSI	CSR permission fault
CSRRCI	CSR permission fault
CBO.INVAL	MODE<M AND menvcfg.CBIE[0]==0	MODE<S AND senvcfg.CBIE[0]==0
CBO.CLEAN	MODE<M AND menvcfg.CBIE[0]==0	MODE<S AND senvcfg.CBIE[0]==0
CBO.FLUSH	MODE<M AND menvcfg.CBIE[0]==0	MODE<S AND senvcfg.CBIE[0]==0
CBO.ZERO	MODE<M AND menvcfg.CBIE[0]==0	MODE<S AND senvcfg.CBIE[0]==0
C.FLW	Xstatus.fs==0
C.FLWSP	Xstatus.fs==0
C.FSW	Xstatus.fs==0
C.FSWSP	Xstatus.fs==0
C.FLD	Xstatus.fs==0
C.FLDSP	Xstatus.fs==0
C.FLD	Xstatus.fs==0
C.FLDSP	Xstatus.fs==0
C.FSD	Xstatus.fs==0
C.FSDSP	Xstatus.fs==0
C.FSD	Xstatus.fs==0
C.FSDSP	Xstatus.fs==0
FLH	Xstatus.fs==0
FSH	Xstatus.fs==0
FLW	Xstatus.fs==0
FSW	Xstatus.fs==0
FLD	Xstatus.fs==0
FSD	Xstatus.fs==0
HLV.B	V=1	MODE==U AND hstatus.HU=0
HLV.BU	V=1	MODE==U AND hstatus.HU=0
HLV.H	V=1	MODE==U AND hstatus.HU=0
HLV.HU	V=1	MODE==U AND hstatus.HU=0
HLV.W	V=1	MODE==U AND hstatus.HU=0
HLV.WU	V=1	MODE==U AND hstatus.HU=0
HLV.D	V=1	MODE==U AND hstatus.HU=0
HLV.C	V=1	MODE==U AND hstatus.HU=0
HSV.B	V=1	MODE==U AND hstatus.HU=0
HSV.H	V=1	MODE==U AND hstatus.HU=0
HSV.W	V=1	MODE==U AND hstatus.HU=0
HSV.D	V=1	MODE==U AND hstatus.HU=0
HSV.C	V=1	MODE==U AND hstatus.HU=0
HLVX.HU	V=1	MODE==U AND hstatus.HU=0
HLVX.WU	V=1	MODE==U AND hstatus.HU=0

Index

Bibliography

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RISC-V. (2023). RISC-V Privileged Specification. github.com/riscv/riscv-isa-manual/releases/download/riscv-isa-release-056b6ff-2023-10-02/priv-isa-asciidoc.pdf

RISC-V. (2023). RISC-V Unprivileged Specification. github.com/riscv/riscv-isa-manual/releases/download/riscv-isa-release-056b6ff-2023-10-02/unpriv-isa-asciidoc.pdf

RISC-V. (2023). RISC-V Code-size Reduction Specification. github.com/riscv/riscv-code-size-reduction/releases/download/v1.0.4-3/Zc-1.0.4-3.pdf

Watson, R. N. M., Neumann, P. G., Woodruff, J., Roe, M., Almatary, H., Anderson, J., Baldwin, J., Barnes, G., Chisnall, D., Clarke, J., Davis, B., Eisen, L., Filardo, N. W., Fuchs, F. A., Grisenthwaite, R., Joannou, A., Laurie, B., Markettos, A. T., Moore, S. W., … Xia, H. (2023). Capability Hardware Enhanced RISC Instructions: CHERI Instruction-Set Architecture (Version 9) (UCAM-CL-TR-987; Issue UCAM-CL-TR-987). University of Cambridge, Computer Laboratory. doi.org/10.48456/tr-987

Woodruff, J., Joannou, A., Xia, H., Fox, A., Norton, R. M., Chisnall, D., Davis, B., Gudka, K., Filardo, N. W., Markettos, A. T., & others. (2019). Cheri concentrate: Practical compressed capabilities. IEEE Transactions on Computers, 68(10), 1455–1469. doi.org/10.1109/TC.2019.2914037

saved register specifier	xreg	integer ABI	CHERI ABI
0	x8	s0	cs0
1	x9	s1	cs1
2	x18	s2	cs2
3	x19	s3	cs3
4	x20	s4	cs4
5	x21	s5	cs5
6	x22	s6	cs6
7	x23	s7	cs7

saved register specifier	xreg	integer ABI	CHERI ABI
0	x8	s0	cs0
1	x9	s1	cs1
2	x18	s2	cs2
3	x19	s3	cs3
4	x20	s4	cs4
5	x21	s5	cs5
6	x22	s6	cs6
7	x23	s7	cs7

saved register specifier	xreg	integer ABI	CHERI ABI
0	x8	s0	cs0
1	x9	s1	cs1
2	x18	s2	cs2
3	x19	s3	cs3
4	x20	s4	cs4
5	x21	s5	cs5
6	x22	s6	cs6
7	x23	s7	cs7