| @c Copyright (C) 2016-2024 Free Software Foundation, Inc. |
| @c This is part of the GAS manual. |
| @c For copying conditions, see the file as.texinfo |
| @c man end |
| |
| @ifset GENERIC |
| @page |
| @node RISC-V-Dependent |
| @chapter RISC-V Dependent Features |
| @end ifset |
| @ifclear GENERIC |
| @node Machine Dependencies |
| @chapter RISC-V Dependent Features |
| @end ifclear |
| |
| @cindex RISC-V support |
| @menu |
| * RISC-V-Options:: RISC-V Options |
| * RISC-V-Directives:: RISC-V Directives |
| * RISC-V-Modifiers:: RISC-V Assembler Modifiers |
| * RISC-V-Floating-Point:: RISC-V Floating Point |
| * RISC-V-Formats:: RISC-V Instruction Formats |
| * RISC-V-ATTRIBUTE:: RISC-V Object Attribute |
| * RISC-V-CustomExts:: RISC-V Custom (Vendor-Defined) Extensions |
| @end menu |
| |
| @node RISC-V-Options |
| @section RISC-V Options |
| |
| The following table lists all available RISC-V specific options. |
| |
| @c man begin OPTIONS |
| @table @gcctabopt |
| |
| @cindex @samp{-fpic} option, RISC-V |
| @item -fpic |
| @itemx -fPIC |
| Generate position-independent code |
| |
| @cindex @samp{-fno-pic} option, RISC-V |
| @item -fno-pic |
| Don't generate position-independent code (default) |
| |
| @cindex @samp{-march=ISA} option, RISC-V |
| @item -march=ISA |
| Select the base isa, as specified by ISA. For example -march=rv32ima. |
| If this option and the architecture attributes aren't set, then assembler |
| will check the default configure setting --with-arch=ISA. |
| |
| @cindex @samp{-misa-spec=ISAspec} option, RISC-V |
| @item -misa-spec=ISAspec |
| Select the default isa spec version. If the version of ISA isn't set |
| by -march, then assembler helps to set the version according to |
| the default chosen spec. If this option isn't set, then assembler will |
| check the default configure setting --with-isa-spec=ISAspec. |
| |
| @cindex @samp{-mpriv-spec=PRIVspec} option, RISC-V |
| @item -mpriv-spec=PRIVspec |
| Select the privileged spec version. We can decide whether the CSR is valid or |
| not according to the chosen spec. If this option and the privilege attributes |
| aren't set, then assembler will check the default configure setting |
| --with-priv-spec=PRIVspec. |
| |
| @cindex @samp{-mabi=ABI} option, RISC-V |
| @item -mabi=ABI |
| Selects the ABI, which is either "ilp32" or "lp64", optionally followed |
| by "f", "d", or "q" to indicate single-precision, double-precision, or |
| quad-precision floating-point calling convention, or none or "e" to indicate |
| the soft-float calling convention ("e" indicates a soft-float RVE ABI). |
| |
| @cindex @samp{-mrelax} option, RISC-V |
| @item -mrelax |
| Take advantage of linker relaxations to reduce the number of instructions |
| required to materialize symbol addresses. (default) |
| |
| @cindex @samp{-mno-relax} option, RISC-V |
| @item -mno-relax |
| Don't do linker relaxations. |
| |
| @cindex @samp{-march-attr} option, RISC-V |
| @item -march-attr |
| Generate the default contents for the riscv elf attribute section if the |
| .attribute directives are not set. This section is used to record the |
| information that a linker or runtime loader needs to check compatibility. |
| This information includes ISA string, stack alignment requirement, unaligned |
| memory accesses, and the major, minor and revision version of privileged |
| specification. |
| |
| @cindex @samp{-mno-arch-attr} option, RISC-V |
| @item -mno-arch-attr |
| Don't generate the default riscv elf attribute section if the .attribute |
| directives are not set. |
| |
| @cindex @samp{-mcsr-check} option, RISC-V |
| @item -mcsr-check |
| Enable the CSR checking for the ISA-dependent CRS and the read-only CSR. |
| The ISA-dependent CSR are only valid when the specific ISA is set. The |
| read-only CSR can not be written by the CSR instructions. |
| |
| @cindex @samp{-mno-csr-check} option, RISC-V |
| @item -mno-csr-check |
| Don't do CSR checking. |
| |
| @cindex @samp{-mlittle-endian} option, RISC-V |
| @item -mlittle-endian |
| Generate code for a little endian machine. |
| |
| @cindex @samp{-mbig-endian} option, RISC-V |
| @item -mbig-endian |
| Generate code for a big endian machine. |
| @end table |
| @c man end |
| |
| @node RISC-V-Directives |
| @section RISC-V Directives |
| @cindex machine directives, RISC-V |
| @cindex RISC-V machine directives |
| |
| The following table lists all available RISC-V specific directives. |
| |
| @table @code |
| |
| @cindex @code{align} directive |
| @item .align @var{size-log-2} |
| Align to the given boundary, with the size given as log2 the number of bytes to |
| align to. |
| |
| @cindex Data directives |
| @item .half @var{value} |
| @itemx .word @var{value} |
| @itemx .dword @var{value} |
| Emits a half-word, word, or double-word value at the current position. |
| |
| @cindex DTP-relative data directives |
| @item .dtprelword @var{value} |
| @itemx .dtpreldword @var{value} |
| Emits a DTP-relative word (or double-word) at the current position. This is |
| meant to be used by the compiler in shared libraries for DWARF debug info for |
| thread local variables. |
| |
| @cindex LEB128 directives |
| @item .uleb128 @var{value} |
| @itemx .sleb128 @var{value} |
| Emits a signed or unsigned LEB128 value at the current position. This only |
| accepts constant expressions, because symbol addresses can change with |
| relaxation, and we don't support relocations to modify LEB128 values at link |
| time. |
| |
| @cindex Option directive |
| @cindex @code{option} directive |
| @item .option @var{argument} |
| Modifies RISC-V specific assembler options inline with the assembly code. |
| This is used when particular instruction sequences must be assembled with a |
| specific set of options. For example, since we relax addressing sequences to |
| shorter GP-relative sequences when possible the initial load of GP must not be |
| relaxed and should be emitted as something like |
| |
| @smallexample |
| .option push |
| .option norelax |
| la gp, __global_pointer$ |
| .option pop |
| @end smallexample |
| |
| in order to produce after linker relaxation the expected |
| |
| @smallexample |
| auipc gp, %pcrel_hi(__global_pointer$) |
| addi gp, gp, %pcrel_lo(__global_pointer$) |
| @end smallexample |
| |
| instead of just |
| |
| @smallexample |
| addi gp, gp, 0 |
| @end smallexample |
| |
| It's not expected that options are changed in this manner during regular use, |
| but there are a handful of esoteric cases like the one above where users need |
| to disable particular features of the assembler for particular code sequences. |
| The complete list of option arguments is shown below: |
| |
| @table @code |
| @item push |
| @itemx pop |
| Pushes or pops the current option stack. These should be used whenever |
| changing an option in line with assembly code in order to ensure the user's |
| command-line options are respected for the bulk of the file being assembled. |
| |
| @item rvc |
| @itemx norvc |
| Enables or disables the generation of compressed instructions. Instructions |
| are opportunistically compressed by the RISC-V assembler when possible, but |
| sometimes this behavior is not desirable, especially when handling alignments. |
| |
| @item pic |
| @itemx nopic |
| Enables or disables position-independent code generation. Unless you really |
| know what you're doing, this should only be at the top of a file. |
| |
| @item relax |
| @itemx norelax |
| Enables or disables relaxation. The RISC-V assembler and linker |
| opportunistically relax some code sequences, but sometimes this behavior is not |
| desirable. |
| |
| @item csr-check |
| @itemx no-csr-check |
| Enables or disables the CSR checking. |
| |
| @item arch, @var{+extension[version]} [,...,@var{+extension_n[version_n]}] |
| @itemx arch, @var{-extension} [,...,@var{-extension_n}] |
| @itemx arch, @var{=ISA} |
| Enables or disables the extensions for specific code region. For example, |
| @samp{.option arch, +m2p0} means add m extension with version 2.0, and |
| @samp{.option arch, -f, -d} means remove extensions, f and d, from the |
| architecture string. Note that, @samp{.option arch, +c, -c} have the same |
| behavior as @samp{.option rvc, norvc}. However, they are also undesirable |
| sometimes. Besides, @samp{.option arch, -i} is illegal, since we cannot |
| remove the base i extension anytime. If you want to reset the whole ISA |
| string, you can also use @samp{.option arch, =rv32imac} to overwrite the |
| previous settings. |
| @end table |
| |
| @cindex INSN directives |
| @item .insn @var{type}, @var{operand} [,...,@var{operand_n}] |
| @itemx .insn @var{insn_length}, @var{value} |
| @itemx .insn @var{value} |
| This directive permits the numeric representation of an instructions |
| and makes the assembler insert the operands according to one of the |
| instruction formats for @samp{.insn} (@ref{RISC-V-Formats}). |
| For example, the instruction @samp{add a0, a1, a2} could be written as |
| @samp{.insn r 0x33, 0, 0, a0, a1, a2}. But in fact, the instruction |
| formats are difficult to use for some users, so most of them are using |
| @samp{.word} to encode the instruction directly, rather than using |
| @samp{.insn}. It is fine for now, but will be wrong when the mapping |
| symbols are supported, since @samp{.word} will not be shown as an |
| instruction, it should be shown as data. Therefore, we also support |
| two more formats of the @samp{.insn}, the instruction @samp{add a0, a1, a2} |
| could also be written as @samp{.insn 0x4, 0xc58533} or @samp{.insn 0xc58533}. |
| When the @var{insn_length} is set, then assembler will check if the |
| @var{value} is a valid @var{insn_length} bytes instruction. |
| |
| @cindex @code{.attribute} directive, RISC-V |
| @item .attribute @var{tag}, @var{value} |
| Set the object attribute @var{tag} to @var{value}. |
| |
| The @var{tag} is either an attribute number, or one of the following: |
| @code{Tag_RISCV_arch}, @code{Tag_RISCV_stack_align}, |
| @code{Tag_RISCV_unaligned_access}, @code{Tag_RISCV_priv_spec}, |
| @code{Tag_RISCV_priv_spec_minor}, @code{Tag_RISCV_priv_spec_revision}. |
| |
| @end table |
| |
| @node RISC-V-Modifiers |
| @section RISC-V Assembler Modifiers |
| |
| The RISC-V assembler supports following modifiers for relocatable addresses |
| used in RISC-V instruction operands. However, we also support some pseudo |
| instructions that are easier to use than these modifiers. |
| |
| @table @code |
| @item %lo(@var{symbol}) |
| The low 12 bits of absolute address for @var{symbol}. |
| |
| @item %hi(@var{symbol}) |
| The high 20 bits of absolute address for @var{symbol}. This is usually |
| used with the %lo modifier to represent a 32-bit absolute address. |
| |
| @smallexample |
| lui a0, %hi(@var{symbol}) // R_RISCV_HI20 |
| addi a0, a0, %lo(@var{symbol}) // R_RISCV_LO12_I |
| |
| lui a0, %hi(@var{symbol}) // R_RISCV_HI20 |
| load/store a0, %lo(@var{symbol})(a0) // R_RISCV_LO12_I/S |
| @end smallexample |
| |
| @item %pcrel_lo(@var{label}) |
| The low 12 bits of relative address between pc and @var{symbol}. |
| The @var{symbol} is related to the high part instruction which is marked |
| by @var{label}. |
| |
| @item %pcrel_hi(@var{symbol}) |
| The high 20 bits of relative address between pc and @var{symbol}. |
| This is usually used with the %pcrel_lo modifier to represent a +/-2GB |
| pc-relative range. |
| |
| @smallexample |
| @var{label}: |
| auipc a0, %pcrel_hi(@var{symbol}) // R_RISCV_PCREL_HI20 |
| addi a0, a0, %pcrel_lo(@var{label}) // R_RISCV_PCREL_LO12_I |
| |
| @var{label}: |
| auipc a0, %pcrel_hi(@var{symbol}) // R_RISCV_PCREL_HI20 |
| load/store a0, %pcrel_lo(@var{label})(a0) // R_RISCV_PCREL_LO12_I/S |
| @end smallexample |
| |
| Or you can use the pseudo lla/lw/sw/... instruction to do this. |
| |
| @smallexample |
| lla a0, @var{symbol} |
| @end smallexample |
| |
| @item %got_pcrel_hi(@var{symbol}) |
| The high 20 bits of relative address between pc and the GOT entry of |
| @var{symbol}. This is usually used with the %pcrel_lo modifier to access |
| the GOT entry. |
| |
| @smallexample |
| @var{label}: |
| auipc a0, %got_pcrel_hi(@var{symbol}) // R_RISCV_GOT_HI20 |
| addi a0, a0, %pcrel_lo(@var{label}) // R_RISCV_PCREL_LO12_I |
| |
| @var{label}: |
| auipc a0, %got_pcrel_hi(@var{symbol}) // R_RISCV_GOT_HI20 |
| load/store a0, %pcrel_lo(@var{label})(a0) // R_RISCV_PCREL_LO12_I/S |
| @end smallexample |
| |
| Also, the pseudo la instruction with PIC has similar behavior. |
| |
| @item %tprel_add(@var{symbol}) |
| This is used purely to associate the R_RISCV_TPREL_ADD relocation for |
| TLS relaxation. This one is only valid as the fourth operand to the normally |
| 3 operand add instruction. |
| |
| @item %tprel_lo(@var{symbol}) |
| The low 12 bits of relative address between tp and @var{symbol}. |
| |
| @item %tprel_hi(@var{symbol}) |
| The high 20 bits of relative address between tp and @var{symbol}. This is |
| usually used with the %tprel_lo and %tprel_add modifiers to access the thread |
| local variable @var{symbol} in TLS Local Exec. |
| |
| @smallexample |
| lui a5, %tprel_hi(@var{symbol}) // R_RISCV_TPREL_HI20 |
| add a5, a5, tp, %tprel_add(@var{symbol}) // R_RISCV_TPREL_ADD |
| load/store t0, %tprel_lo(@var{symbol})(a5) // R_RISCV_TPREL_LO12_I/S |
| @end smallexample |
| |
| @item %tls_ie_pcrel_hi(@var{symbol}) |
| The high 20 bits of relative address between pc and GOT entry. It is |
| usually used with the %pcrel_lo modifier to access the thread local |
| variable @var{symbol} in TLS Initial Exec. |
| |
| @smallexample |
| la.tls.ie a5, @var{symbol} |
| add a5, a5, tp |
| load/store t0, 0(a5) |
| @end smallexample |
| |
| The pseudo la.tls.ie instruction can be expended to |
| |
| @smallexample |
| @var{label}: |
| auipc a5, %tls_ie_pcrel_hi(@var{symbol}) // R_RISCV_TLS_GOT_HI20 |
| load a5, %pcrel_lo(@var{label})(a5) // R_RISCV_PCREL_LO12_I |
| @end smallexample |
| |
| @item %tls_gd_pcrel_hi(@var{symbol}) |
| The high 20 bits of relative address between pc and GOT entry. It is |
| usually used with the %pcrel_lo modifier to access the thread local variable |
| @var{symbol} in TLS Global Dynamic. |
| |
| @smallexample |
| la.tls.gd a0, @var{symbol} |
| call __tls_get_addr@@plt |
| mv a5, a0 |
| load/store t0, 0(a5) |
| @end smallexample |
| |
| The pseudo la.tls.gd instruction can be expended to |
| |
| @smallexample |
| @var{label}: |
| auipc a0, %tls_gd_pcrel_hi(@var{symbol}) // R_RISCV_TLS_GD_HI20 |
| addi a0, a0, %pcrel_lo(@var{label}) // R_RISCV_PCREL_LO12_I |
| @end smallexample |
| |
| @end table |
| |
| @node RISC-V-Floating-Point |
| @section RISC-V Floating Point |
| @cindex floating point, risc-v (@sc{ieee}) |
| @cindex RISC-V floating point (@sc{ieee}) |
| |
| The RISC-V architecture uses @sc{ieee} floating-point numbers. |
| |
| The RISC-V Zfa extension includes a load-immediate instruction |
| for floating-point registers, which allows specifying the immediate |
| (from a pool of 32 predefined values defined in the specification) |
| as operand. |
| E.g. to load the value @code{0.0625} as single-precision FP value into |
| the FP register @code{ft1} one of the following instructions can be used: |
| |
| fli.s ft1, 0.0625 # dec floating-point literal |
| fli.s ft1, 0x1p-4 # hex floating-point literal |
| fli.s ft1, 0x0.8p-3 |
| fli.s ft1, 0x1.0p-4 |
| fli.s ft1, 0x2p-5 |
| fli.s ft1, 0x4p-6 |
| ... |
| |
| As can be seen, many valid ways exist to express a floating-point value. |
| This is realized by parsing the value operand using strtof() and |
| comparing the parsed value against built-in float-constants that |
| are written as hex floating-point literals. |
| |
| This approach works on all machines that use IEEE 754. |
| However, there is a chance that this fails on other machines |
| with the following error message: |
| |
| Error: improper fli value operand |
| Error: illegal operands `fli.s ft1,0.0625 |
| |
| The error indicates that parsing @samp{0x1p-4} and @samp{0.0625} |
| to single-precision floating point numbers will not result |
| in two equal values on that machine. |
| |
| If you encounter this problem, then please report it. |
| |
| @node RISC-V-Formats |
| @section RISC-V Instruction Formats |
| @cindex instruction formats, risc-v |
| @cindex RISC-V instruction formats |
| |
| The RISC-V Instruction Set Manual Volume I: User-Level ISA lists 15 |
| instruction formats where some of the formats have multiple variants. |
| For the @samp{.insn} pseudo directive the assembler recognizes some |
| of the formats. |
| Typically, the most general variant of the instruction format is used |
| by the @samp{.insn} directive. |
| |
| The following table lists the abbreviations used in the table of |
| instruction formats: |
| |
| @display |
| @multitable @columnfractions .15 .40 |
| @item opcode7 @tab Unsigned immediate or opcode name for 7-bits opcode. |
| @item opcode2 @tab Unsigned immediate or opcode name for 2-bits opcode. |
| @item func7 @tab Unsigned immediate for 7-bits function code. |
| @item func6 @tab Unsigned immediate for 6-bits function code. |
| @item func4 @tab Unsigned immediate for 4-bits function code. |
| @item func3 @tab Unsigned immediate for 3-bits function code. |
| @item func2 @tab Unsigned immediate for 2-bits function code. |
| @item rd @tab Destination register number for operand x, can be GPR or FPR. |
| @item rd' @tab Destination register number for operand x, |
| only accept s0-s1, a0-a5, fs0-fs1 and fa0-fa5. |
| @item rs1 @tab First source register number for operand x, can be GPR or FPR. |
| @item rs1' @tab First source register number for operand x, |
| only accept s0-s1, a0-a5, fs0-fs1 and fa0-fa5. |
| @item rs2 @tab Second source register number for operand x, can be GPR or FPR. |
| @item rs2' @tab Second source register number for operand x, |
| only accept s0-s1, a0-a5, fs0-fs1 and fa0-fa5. |
| @item simm12 @tab Sign-extended 12-bit immediate for operand x. |
| @item simm20 @tab Sign-extended 20-bit immediate for operand x. |
| @item simm6 @tab Sign-extended 6-bit immediate for operand x. |
| @item uimm5 @tab Unsigned 5-bit immediate for operand x. |
| @item uimm6 @tab Unsigned 6-bit immediate for operand x. |
| @item uimm8 @tab Unsigned 8-bit immediate for operand x. |
| @item symbol @tab Symbol or label reference for operand x. |
| @end multitable |
| @end display |
| |
| The following table lists all available opcode name: |
| |
| @table @code |
| @item C0 |
| @item C1 |
| @item C2 |
| Opcode space for compressed instructions. |
| |
| @item LOAD |
| Opcode space for load instructions. |
| |
| @item LOAD_FP |
| Opcode space for floating-point load instructions. |
| |
| @item STORE |
| Opcode space for store instructions. |
| |
| @item STORE_FP |
| Opcode space for floating-point store instructions. |
| |
| @item AUIPC |
| Opcode space for auipc instruction. |
| |
| @item LUI |
| Opcode space for lui instruction. |
| |
| @item BRANCH |
| Opcode space for branch instructions. |
| |
| @item JAL |
| Opcode space for jal instruction. |
| |
| @item JALR |
| Opcode space for jalr instruction. |
| |
| @item OP |
| Opcode space for ALU instructions. |
| |
| @item OP_32 |
| Opcode space for 32-bits ALU instructions. |
| |
| @item OP_IMM |
| Opcode space for ALU with immediate instructions. |
| |
| @item OP_IMM_32 |
| Opcode space for 32-bits ALU with immediate instructions. |
| |
| @item OP_FP |
| Opcode space for floating-point operation instructions. |
| |
| @item MADD |
| Opcode space for madd instruction. |
| |
| @item MSUB |
| Opcode space for msub instruction. |
| |
| @item NMADD |
| Opcode space for nmadd instruction. |
| |
| @item NMSUB |
| Opcode space for msub instruction. |
| |
| @item AMO |
| Opcode space for atomic memory operation instructions. |
| |
| @item MISC_MEM |
| Opcode space for misc instructions. |
| |
| @item SYSTEM |
| Opcode space for system instructions. |
| |
| @item CUSTOM_0 |
| @item CUSTOM_1 |
| @item CUSTOM_2 |
| @item CUSTOM_3 |
| Opcode space for customize instructions. |
| |
| @end table |
| |
| An instruction is two or four bytes in length and must be aligned |
| on a 2 byte boundary. The first two bits of the instruction specify the |
| length of the instruction, 00, 01 and 10 indicates a two byte instruction, |
| 11 indicates a four byte instruction. |
| |
| The following table lists the RISC-V instruction formats that are available |
| with the @samp{.insn} pseudo directive: |
| |
| @table @code |
| @item R type: .insn r opcode7, func3, func7, rd, rs1, rs2 |
| @verbatim |
| +-------+-----+-----+-------+----+---------+ |
| | func7 | rs2 | rs1 | func3 | rd | opcode7 | |
| +-------+-----+-----+-------+----+---------+ |
| 31 25 20 15 12 7 0 |
| @end verbatim |
| |
| @item R type with 4 register operands: .insn r opcode7, func3, func2, rd, rs1, rs2, rs3 |
| @itemx R4 type: .insn r4 opcode7, func3, func2, rd, rs1, rs2, rs3 |
| @verbatim |
| +-----+-------+-----+-----+-------+----+---------+ |
| | rs3 | func2 | rs2 | rs1 | func3 | rd | opcode7 | |
| +-----+-------+-----+-----+-------+----+---------+ |
| 31 27 25 20 15 12 7 0 |
| @end verbatim |
| |
| @item I type: .insn i opcode7, func3, rd, rs1, simm12 |
| @itemx I type: .insn i opcode7, func3, rd, simm12(rs1) |
| @verbatim |
| +--------------+-----+-------+----+---------+ |
| | simm12[11:0] | rs1 | func3 | rd | opcode7 | |
| +--------------+-----+-------+----+---------+ |
| 31 20 15 12 7 0 |
| @end verbatim |
| |
| @item S type: .insn s opcode7, func3, rs2, simm12(rs1) |
| @verbatim |
| +--------------+-----+-----+-------+-------------+---------+ |
| | simm12[11:5] | rs2 | rs1 | func3 | simm12[4:0] | opcode7 | |
| +--------------+-----+-----+-------+-------------+---------+ |
| 31 25 20 15 12 7 0 |
| @end verbatim |
| |
| @item B type: .insn s opcode7, func3, rs1, rs2, symbol |
| @itemx SB type: .insn sb opcode7, func3, rs1, rs2, symbol |
| @verbatim |
| +-----------------+-----+-----+-------+----------------+---------+ |
| | simm12[12|10:5] | rs2 | rs1 | func3 | simm12[4:1|11] | opcode7 | |
| +-----------------+-----+-----+-------+----------------+---------+ |
| 31 25 20 15 12 7 0 |
| @end verbatim |
| |
| @item U type: .insn u opcode7, rd, simm20 |
| @verbatim |
| +--------------+----+---------+ |
| | simm20[19:0] | rd | opcode7 | |
| +--------------+----+---------+ |
| 31 12 7 0 |
| @end verbatim |
| |
| @item J type: .insn j opcode7, rd, symbol |
| @itemx UJ type: .insn uj opcode7, rd, symbol |
| @verbatim |
| +------------+--------------+------------+---------------+----+---------+ |
| | simm20[20] | simm20[10:1] | simm20[11] | simm20[19:12] | rd | opcode7 | |
| +------------+--------------+------------+---------------+----+---------+ |
| 31 30 21 20 12 7 0 |
| @end verbatim |
| |
| @item CR type: .insn cr opcode2, func4, rd, rs2 |
| @verbatim |
| +-------+--------+-----+---------+ |
| | func4 | rd/rs1 | rs2 | opcode2 | |
| +-------+--------+-----+---------+ |
| 15 12 7 2 0 |
| @end verbatim |
| |
| @item CI type: .insn ci opcode2, func3, rd, simm6 |
| @verbatim |
| +-------+----------+--------+------------+---------+ |
| | func3 | simm6[5] | rd/rs1 | simm6[4:0] | opcode2 | |
| +-------+----------+--------+------------+---------+ |
| 15 13 12 7 2 0 |
| @end verbatim |
| |
| @item CIW type: .insn ciw opcode2, func3, rd', uimm8 |
| @verbatim |
| +-------+------------+-----+---------+ |
| | func3 | uimm8[7:0] | rd' | opcode2 | |
| +-------+-------- ---+-----+---------+ |
| 15 13 5 2 0 |
| @end verbatim |
| |
| @item CSS type: .insn css opcode2, func3, rd, uimm6 |
| @verbatim |
| +-------+------------+----+---------+ |
| | func3 | uimm6[5:0] | rd | opcode2 | |
| +-------+------------+----+---------+ |
| 15 13 7 2 0 |
| @end verbatim |
| |
| @item CL type: .insn cl opcode2, func3, rd', uimm5(rs1') |
| @verbatim |
| +-------+------------+------+------------+------+---------+ |
| | func3 | uimm5[4:2] | rs1' | uimm5[1:0] | rd' | opcode2 | |
| +-------+------------+------+------------+------+---------+ |
| 15 13 10 7 5 2 0 |
| @end verbatim |
| |
| @item CS type: .insn cs opcode2, func3, rs2', uimm5(rs1') |
| @verbatim |
| +-------+------------+------+------------+------+---------+ |
| | func3 | uimm5[4:2] | rs1' | uimm5[1:0] | rs2' | opcode2 | |
| +-------+------------+------+------------+------+---------+ |
| 15 13 10 7 5 2 0 |
| @end verbatim |
| |
| @item CA type: .insn ca opcode2, func6, func2, rd', rs2' |
| @verbatim |
| +-- ----+----------+-------+------+---------+ |
| | func6 | rd'/rs1' | func2 | rs2' | opcode2 | |
| +-------+----------+-------+------+---------+ |
| 15 10 7 5 2 0 |
| @end verbatim |
| |
| @item CB type: .insn cb opcode2, func3, rs1', symbol |
| @verbatim |
| +-------+--------------+------+------------------+---------+ |
| | func3 | simm8[8|4:3] | rs1' | simm8[7:6|2:1|5] | opcode2 | |
| +-------+--------------+------+------------------+---------+ |
| 15 13 10 7 2 0 |
| @end verbatim |
| |
| @item CJ type: .insn cj opcode2, symbol |
| @verbatim |
| +-------+-------------------------------+---------+ |
| | func3 | simm11[11|4|9:8|10|6|7|3:1|5] | opcode2 | |
| +-------+-------------------------------+---------+ |
| 15 13 2 0 |
| @end verbatim |
| |
| |
| @end table |
| |
| For the complete list of all instruction format variants see |
| The RISC-V Instruction Set Manual Volume I: User-Level ISA. |
| |
| @node RISC-V-ATTRIBUTE |
| @section RISC-V Object Attribute |
| @cindex Object Attribute, RISC-V |
| |
| RISC-V attributes have a string value if the tag number is odd and an integer |
| value if the tag number is even. |
| |
| @table @r |
| @item Tag_RISCV_stack_align (4) |
| Tag_RISCV_strict_align records the N-byte stack alignment for this object. The |
| default value is 16 for RV32I or RV64I, and 4 for RV32E. |
| |
| The smallest value will be used if object files with different |
| Tag_RISCV_stack_align values are merged. |
| |
| @item Tag_RISCV_arch (5) |
| Tag_RISCV_arch contains a string for the target architecture taken from the |
| option @option{-march}. Different architectures will be integrated into a |
| superset when object files are merged. |
| |
| Note that the version information of the target architecture must be presented |
| explicitly in the attribute and abbreviations must be expanded. The version |
| information, if not given by @option{-march}, must be in accordance with the |
| default specified by the tool. For example, the architecture @code{RV32I} has |
| to be recorded in the attribute as @code{RV32I2P0} in which @code{2P0} stands |
| for the default version of its base ISA. On the other hand, the architecture |
| @code{RV32G} has to be presented as @code{RV32I2P0_M2P0_A2P0_F2P0_D2P0} in |
| which the abbreviation @code{G} is expanded to the @code{IMAFD} combination |
| with default versions of the standard extensions. |
| |
| @item Tag_RISCV_unaligned_access (6) |
| Tag_RISCV_unaligned_access is 0 for files that do not allow any unaligned |
| memory accesses, and 1 for files that do allow unaligned memory accesses. |
| |
| @item Tag_RISCV_priv_spec (8) |
| @item Tag_RISCV_priv_spec_minor (10) |
| @item Tag_RISCV_priv_spec_revision (12) |
| Tag_RISCV_priv_spec contains the major/minor/revision version information of |
| the privileged specification. It will report errors if object files of |
| different privileged specification versions are merged. |
| |
| @end table |
| |
| @node RISC-V-CustomExts |
| @section RISC-V Custom (Vendor-Defined) Extensions |
| @cindex custom (vendor-defined) extensions, RISC-V |
| @cindex RISC-V custom (vendor-defined) extensions |
| |
| The following table lists the custom (vendor-defined) RISC-V |
| extensions supported and provides the location of their |
| publicly-released documentation: |
| |
| @table @r |
| @item Xcvmac |
| The Xcvmac extension provides instructions for multiply-accumulate operations. |
| |
| It is documented in @url{https://docs.openhwgroup.org/projects/cv32e40p-user-manual/en/latest/instruction_set_extensions.html} |
| |
| @item Xcvalu |
| The Xcvalu extension provides instructions for general ALU operations. |
| |
| It is documented in @url{https://docs.openhwgroup.org/projects/cv32e40p-user-manual/en/latest/instruction_set_extensions.html} |
| |
| @item Xcvelw |
| The Xcvelw extension provides instructions for event load word operations. |
| |
| It is documented in @url{https://docs.openhwgroup.org/projects/cv32e40p-user-manual/en/latest/instruction_set_extensions.html} |
| |
| @item Xcvbi |
| The Xcvbi extension provides instructions for branch immediate operations. |
| |
| It is documented in @url{https://docs.openhwgroup.org/projects/cv32e40p-user-manual/en/latest/instruction_set_extensions.html} |
| |
| @item Xcvmem |
| The Xcvmem extension provides instructions for post inc load/store operations. |
| |
| It is documented in @url{https://docs.openhwgroup.org/projects/cv32e40p-user-manual/en/latest/instruction_set_extensions.html} |
| |
| @item XTheadBa |
| The XTheadBa extension provides instructions for address calculations. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadBb |
| The XTheadBb extension provides instructions for basic bit-manipulation |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadBs |
| The XTheadBs extension provides single-bit instructions. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadCmo |
| The XTheadCmo extension provides instructions for cache management. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadCondMov |
| The XTheadCondMov extension provides instructions for conditional moves. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadFMemIdx |
| The XTheadFMemIdx extension provides floating-point memory operations. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadFmv |
| The XTheadFmv extension provides access to the upper 32 bits of a doulbe-precision floating point register. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.1.0/xthead-2022-11-07-2.1.0.pdf}. |
| |
| @item XTheadInt |
| The XTheadInt extension provides access to ISR stack management instructions. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.1.0/xthead-2022-11-07-2.1.0.pdf}. |
| |
| @item XTheadMac |
| The XTheadMac extension provides multiply-accumulate instructions. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadMemIdx |
| The XTheadMemIdx extension provides GPR memory operations. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadMemPair |
| The XTheadMemPair extension provides two-GP-register memory operations. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadSync |
| The XTheadSync extension provides instructions for multi-processor synchronization. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.0.0/xthead-2022-09-05-2.0.0.pdf}. |
| |
| @item XTheadVector |
| The XTheadVector extension provides instructions for thead vector. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.3.0/xthead-2023-11-10-2.3.0.pdf}. |
| |
| @item XTheadZvamo |
| The XTheadZvamo extension is a subextension of the XTheadVector extension, |
| and it provides AMO instructions for the T-Head VECTOR vendor extension. |
| |
| It is documented in @url{https://github.com/T-head-Semi/thead-extension-spec/releases/download/2.3.0/xthead-2023-11-10-2.3.0.pdf}. |
| |
| @item XVentanaCondOps |
| XVentanaCondOps extension provides instructions for branchless |
| sequences that perform conditional arithmetic, conditional |
| bitwise-logic, and conditional select operations. |
| |
| It is documented in @url{https://github.com/ventanamicro/ventana-custom-extensions/releases/download/v1.0.0/ventana-custom-extensions-v1.0.0.pdf}. |
| |
| @item XSfVcp |
| The XSfVcp (VCIX) extension provides flexible instructions for extending |
| vector coprocessor. To accelerate performance, system designers may use |
| VCIX as a low-latency, high-throughput interface to a coprocessor. |
| |
| It is documented in @url{https://sifive.cdn.prismic.io/sifive/c3829e36-8552-41f0-a841-79945784241b_vcix-spec-software.pdf}. |
| |
| @end table |