@c Copyright (C) 2016-2020 Free Software Foundation, Inc.
@c This is part of the GAS anual.
@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-Formats:: RISC-V Instruction Formats
* RISC-V-ATTRIBUTE:: RISC-V Object Attribute
@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.
@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 to indicate
the soft-float calling convention. Also, "ilp32" can optionally be followed
by "e" to indicate the RVE ABI, which is always soft-float.
@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.
@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 BSS directive
@item .bss
Sets the current section to the BSS section.
@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.
@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.
@end table
@cindex INSN directives
@item .insn @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}.
@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-Formats
@section Instruction Formats
@cindex instruction formats, risc-v
@cindex RISC-V instruction formats
The RISC-V Instruction Set Manual Volume I: User-Level ISA lists 12
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 opcode @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 uimm8 @tab Unsigned 8-bit immediate for operand x.
@item symbol @tab Symbol or lable 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 opcode, func3, func7, rd, rs1, rs2
@verbatim
+-------+-----+-----+-------+----+-------------+
| func7 | rs2 | rs1 | func3 | rd | opcode |
+-------+-----+-----+-------+----+-------------+
31 25 20 15 12 7 0
@end verbatim
@item R type with 4 register operands: .insn r opcode, func3, func2, rd, rs1, rs2, rs3
@itemx R4 type: .insn r4 opcode, func3, func2, rd, rs1, rs2, rs3
@verbatim
+-----+-------+-----+-----+-------+----+-------------+
| rs3 | func2 | rs2 | rs1 | func3 | rd | opcode |
+-----+-------+-----+-----+-------+----+-------------+
31 27 25 20 15 12 7 0
@end verbatim
@item I type: .insn i opcode, func3, rd, rs1, simm12
@verbatim
+-------------+-----+-------+----+-------------+
| simm12 | rs1 | func3 | rd | opcode |
+-------------+-----+-------+----+-------------+
31 20 15 12 7 0
@end verbatim
@item S type: .insn s opcode, func3, rd, rs1, simm12
@verbatim
+--------------+-----+-----+-------+-------------+-------------+
| simm12[11:5] | rs2 | rs1 | func3 | simm12[4:0] | opcode |
+--------------+-----+-----+-------+-------------+-------------+
31 25 20 15 12 7 0
@end verbatim
@item SB type: .insn sb opcode, func3, rd, rs1, symbol
@itemx SB type: .insn sb opcode, func3, rd, simm12(rs1)
@itemx B type: .insn s opcode, func3, rd, rs1, symbol
@itemx B type: .insn s opcode, func3, rd, simm12(rs1)
@verbatim
+------------+--------------+-----+-----+-------+-------------+-------------+--------+
| simm12[12] | simm12[10:5] | rs2 | rs1 | func3 | simm12[4:1] | simm12[11]] | opcode |
+------------+--------------+-----+-----+-------+-------------+-------------+--------+
31 30 25 20 15 12 7 0
@end verbatim
@item U type: .insn u opcode, rd, simm20
@verbatim
+---------------------------+----+-------------+
| simm20 | rd | opcode |
+---------------------------+----+-------------+
31 12 7 0
@end verbatim
@item UJ type: .insn uj opcode, rd, symbol
@itemx J type: .insn j opcode, rd, symbol
@verbatim
+------------+--------------+------------+---------------+----+-------------+
| simm20[20] | simm20[10:1] | simm20[11] | simm20[19:12] | rd | opcode |
+------------+--------------+------------+---------------+----+-------------+
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 | imm | rd/rs1 | imm | opcode2 |
+---------+-----+--------+-----+---------+
15 13 12 7 2 0
@end verbatim
@item CIW type: .insn ciw opcode2, func3, rd, uimm8
@verbatim
+---------+--------------+-----+---------+
| func3 | imm | rd' | opcode2 |
+---------+--------------+-----+---------+
15 13 7 2 0
@end verbatim
@item CA type: .insn ca opcode2, func6, func2, rd, rs2
@verbatim
+---------+----------+-------+------+--------+
| func6 | rd'/rs1' | func2 | rs2' | opcode |
+---------+----------+-------+------+--------+
15 10 7 5 2 0
@end verbatim
@item CB type: .insn cb opcode2, func3, rs1, symbol
@verbatim
+---------+--------+------+--------+---------+
| func3 | offset | rs1' | offset | opcode2 |
+---------+--------+------+--------+---------+
15 13 10 7 2 0
@end verbatim
@item CJ type: .insn cj opcode2, symbol
@verbatim
+---------+--------------------+---------+
| func3 | jump target | opcode2 |
+---------+--------------------+---------+
15 13 7 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