40e7b7b9ef
Remove comments about placement of literal pools. (Literal Directive): Update description of literal placement. (Literal Prefix Directive): Remove statement that this does not apply to absolute-mode literals. Describe new section naming scheme.
780 lines
31 KiB
Plaintext
780 lines
31 KiB
Plaintext
@c Copyright (C) 2002, 2004 Free Software Foundation, Inc.
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@c This is part of the GAS manual.
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@c For copying conditions, see the file as.texinfo.
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@c
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@ifset GENERIC
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@page
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@node Xtensa-Dependent
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@chapter Xtensa Dependent Features
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@end ifset
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@ifclear GENERIC
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@node Machine Dependencies
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@chapter Xtensa Dependent Features
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@end ifclear
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@cindex Xtensa architecture
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This chapter covers features of the @sc{gnu} assembler that are specific
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to the Xtensa architecture. For details about the Xtensa instruction
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set, please consult the @cite{Xtensa Instruction Set Architecture (ISA)
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Reference Manual}.
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@menu
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* Xtensa Options:: Command-line Options.
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* Xtensa Syntax:: Assembler Syntax for Xtensa Processors.
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* Xtensa Optimizations:: Assembler Optimizations.
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* Xtensa Relaxation:: Other Automatic Transformations.
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* Xtensa Directives:: Directives for Xtensa Processors.
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@end menu
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@node Xtensa Options
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@section Command Line Options
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The Xtensa version of the @sc{gnu} assembler supports these
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special options:
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@table @code
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@item --text-section-literals | --no-text-section-literals
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@kindex --text-section-literals
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@kindex --no-text-section-literals
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Control the treatment of literal pools. The default is
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@samp{--no-@-text-@-section-@-literals}, which places literals in a
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separate section in the output file. This allows the literal pool to be
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placed in a data RAM/ROM. With @samp{--text-@-section-@-literals}, the
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literals are interspersed in the text section in order to keep them as
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close as possible to their references. This may be necessary for large
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assembly files, where the literals would otherwise be out of range of the
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@code{L32R} instructions in the text section. These options only affect
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literals referenced via PC-relative @code{L32R} instructions; literals
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for absolute mode @code{L32R} instructions are handled separately.
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@item --absolute-literals | --no-absolute-literals
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@kindex --absolute-literals
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@kindex --no-absolute-literals
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Indicate to the assembler whether @code{L32R} instructions use absolute
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or PC-relative addressing. If the processor includes the absolute
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addressing option, the default is to use absolute @code{L32R}
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relocations. Otherwise, only the PC-relative @code{L32R} relocations
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can be used.
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@item --target-align | --no-target-align
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@kindex --target-align
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@kindex --no-target-align
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Enable or disable automatic alignment to reduce branch penalties at some
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expense in code size. @xref{Xtensa Automatic Alignment, ,Automatic
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Instruction Alignment}. This optimization is enabled by default. Note
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that the assembler will always align instructions like @code{LOOP} that
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have fixed alignment requirements.
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@item --longcalls | --no-longcalls
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@kindex --longcalls
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@kindex --no-longcalls
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Enable or disable transformation of call instructions to allow calls
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across a greater range of addresses. @xref{Xtensa Call Relaxation,
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,Function Call Relaxation}. This option should be used when call
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targets can potentially be out of range. It may degrade both code size
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and performance, but the linker can generally optimize away the
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unnecessary overhead when a call ends up within range. The default is
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@samp{--no-@-longcalls}.
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@item --transform | --no-transform
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@kindex --transform
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@kindex --no-transform
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Enable or disable all assembler transformations of Xtensa instructions,
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including both relaxation and optimization. The default is
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@samp{--transform}; @samp{--no-transform} should only be used in the
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rare cases when the instructions must be exactly as specified in the
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assembly source. Using @samp{--no-transform} causes out of range
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instruction operands to be errors.
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@end table
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@node Xtensa Syntax
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@section Assembler Syntax
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@cindex syntax, Xtensa assembler
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@cindex Xtensa assembler syntax
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@cindex FLIX syntax
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Block comments are delimited by @samp{/*} and @samp{*/}. End of line
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comments may be introduced with either @samp{#} or @samp{//}.
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Instructions consist of a leading opcode or macro name followed by
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whitespace and an optional comma-separated list of operands:
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@smallexample
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@var{opcode} [@var{operand}, @dots{}]
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@end smallexample
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Instructions must be separated by a newline or semicolon.
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FLIX instructions, which bundle multiple opcodes together in a single
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instruction, are specified by enclosing the bundled opcodes inside
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braces:
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@smallexample
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@{
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[@var{format}]
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@var{opcode0} [@var{operands}]
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@var{opcode1} [@var{operands}]
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@var{opcode2} [@var{operands}]
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@dots{}
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@}
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@end smallexample
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The opcodes in a FLIX instruction are listed in the same order as the
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corresponding instruction slots in the TIE format declaration.
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Directives and labels are not allowed inside the braces of a FLIX
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instruction. A particular TIE format name can optionally be specified
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immediately after the opening brace, but this is usually unnecessary.
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The assembler will automatically search for a format that can encode the
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specified opcodes, so the format name need only be specified in rare
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cases where there is more than one applicable format and where it
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matters which of those formats is used. A FLIX instruction can also be
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specified on a single line by separating the opcodes with semicolons:
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@smallexample
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@{ [@var{format};] @var{opcode0} [@var{operands}]; @var{opcode1} [@var{operands}]; @var{opcode2} [@var{operands}]; @dots{} @}
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@end smallexample
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The assembler can automatically bundle opcodes into FLIX instructions.
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It encodes the opcodes in order, one at a time,
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choosing the smallest format where each opcode can be encoded and
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filling unused instruction slots with no-ops.
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@menu
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* Xtensa Opcodes:: Opcode Naming Conventions.
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* Xtensa Registers:: Register Naming.
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@end menu
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@node Xtensa Opcodes
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@subsection Opcode Names
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@cindex Xtensa opcode names
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@cindex opcode names, Xtensa
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See the @cite{Xtensa Instruction Set Architecture (ISA) Reference
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Manual} for a complete list of opcodes and descriptions of their
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semantics.
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@cindex _ opcode prefix
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If an opcode name is prefixed with an underscore character (@samp{_}),
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@command{@value{AS}} will not transform that instruction in any way. The
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underscore prefix disables both optimization (@pxref{Xtensa
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Optimizations, ,Xtensa Optimizations}) and relaxation (@pxref{Xtensa
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Relaxation, ,Xtensa Relaxation}) for that particular instruction. Only
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use the underscore prefix when it is essential to select the exact
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opcode produced by the assembler. Using this feature unnecessarily
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makes the code less efficient by disabling assembler optimization and
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less flexible by disabling relaxation.
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Note that this special handling of underscore prefixes only applies to
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Xtensa opcodes, not to either built-in macros or user-defined macros.
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When an underscore prefix is used with a macro (e.g., @code{_MOV}), it
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refers to a different macro. The assembler generally provides built-in
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macros both with and without the underscore prefix, where the underscore
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versions behave as if the underscore carries through to the instructions
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in the macros. For example, @code{_MOV} may expand to @code{_MOV.N}@.
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The underscore prefix only applies to individual instructions, not to
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series of instructions. For example, if a series of instructions have
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underscore prefixes, the assembler will not transform the individual
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instructions, but it may insert other instructions between them (e.g.,
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to align a @code{LOOP} instruction). To prevent the assembler from
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modifying a series of instructions as a whole, use the
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@code{no-transform} directive. @xref{Transform Directive, ,transform}.
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@node Xtensa Registers
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@subsection Register Names
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@cindex Xtensa register names
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@cindex register names, Xtensa
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@cindex sp register
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The assembly syntax for a register file entry is the ``short'' name for
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a TIE register file followed by the index into that register file. For
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example, the general-purpose @code{AR} register file has a short name of
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@code{a}, so these registers are named @code{a0}@dots{}@code{a15}.
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As a special feature, @code{sp} is also supported as a synonym for
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@code{a1}. Additional registers may be added by processor configuration
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options and by designer-defined TIE extensions. An initial @samp{$}
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character is optional in all register names.
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@node Xtensa Optimizations
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@section Xtensa Optimizations
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@cindex optimizations
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The optimizations currently supported by @command{@value{AS}} are
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generation of density instructions where appropriate and automatic
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branch target alignment.
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@menu
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* Density Instructions:: Using Density Instructions.
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* Xtensa Automatic Alignment:: Automatic Instruction Alignment.
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@end menu
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@node Density Instructions
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@subsection Using Density Instructions
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@cindex density instructions
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The Xtensa instruction set has a code density option that provides
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16-bit versions of some of the most commonly used opcodes. Use of these
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opcodes can significantly reduce code size. When possible, the
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assembler automatically translates instructions from the core
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Xtensa instruction set into equivalent instructions from the Xtensa code
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density option. This translation can be disabled by using underscore
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prefixes (@pxref{Xtensa Opcodes, ,Opcode Names}), by using the
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@samp{--no-transform} command-line option (@pxref{Xtensa Options, ,Command
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Line Options}), or by using the @code{no-transform} directive
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(@pxref{Transform Directive, ,transform}).
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It is a good idea @emph{not} to use the density instructions directly.
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The assembler will automatically select dense instructions where
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possible. If you later need to use an Xtensa processor without the code
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density option, the same assembly code will then work without modification.
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@node Xtensa Automatic Alignment
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@subsection Automatic Instruction Alignment
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@cindex alignment of @code{LOOP} instructions
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@cindex alignment of @code{ENTRY} instructions
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@cindex alignment of branch targets
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@cindex @code{LOOP} instructions, alignment
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@cindex @code{ENTRY} instructions, alignment
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@cindex branch target alignment
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The Xtensa assembler will automatically align certain instructions, both
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to optimize performance and to satisfy architectural requirements.
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As an optimization to improve performance, the assembler attempts to
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align branch targets so they do not cross instruction fetch boundaries.
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(Xtensa processors can be configured with either 32-bit or 64-bit
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instruction fetch widths.) An
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instruction immediately following a call is treated as a branch target
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in this context, because it will be the target of a return from the
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call. This alignment has the potential to reduce branch penalties at
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some expense in code size. The assembler will not attempt to align
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labels with the prefixes @code{.Ln} and @code{.LM}, since these labels
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are used for debugging information and are not typically branch targets.
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This optimization is enabled by default. You can disable it with the
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@samp{--no-target-@-align} command-line option (@pxref{Xtensa Options,
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,Command Line Options}).
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The target alignment optimization is done without adding instructions
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that could increase the execution time of the program. If there are
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density instructions in the code preceding a target, the assembler can
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change the target alignment by widening some of those instructions to
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the equivalent 24-bit instructions. Extra bytes of padding can be
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inserted immediately following unconditional jump and return
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instructions.
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This approach is usually successful in aligning many, but not all,
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branch targets.
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The @code{LOOP} family of instructions must be aligned such that the
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first instruction in the loop body does not cross an instruction fetch
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boundary (e.g., with a 32-bit fetch width, a @code{LOOP} instruction
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must be on either a 1 or 2 mod 4 byte boundary). The assembler knows
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about this restriction and inserts the minimal number of 2 or 3 byte
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no-op instructions to satisfy it. When no-op instructions are added,
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any label immediately preceding the original loop will be moved in order
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to refer to the loop instruction, not the newly generated no-op
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instruction. To preserve binary compatibility across processors with
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different fetch widths, the assembler conservatively assumes a 32-bit
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fetch width when aligning @code{LOOP} instructions (except if the first
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instruction in the loop is a 64-bit instruction).
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Similarly, the @code{ENTRY} instruction must be aligned on a 0 mod 4
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byte boundary. The assembler satisfies this requirement by inserting
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zero bytes when required. In addition, labels immediately preceding the
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@code{ENTRY} instruction will be moved to the newly aligned instruction
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location.
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@node Xtensa Relaxation
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@section Xtensa Relaxation
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@cindex relaxation
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When an instruction operand is outside the range allowed for that
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particular instruction field, @command{@value{AS}} can transform the code
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to use a functionally-equivalent instruction or sequence of
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instructions. This process is known as @dfn{relaxation}. This is
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typically done for branch instructions because the distance of the
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branch targets is not known until assembly-time. The Xtensa assembler
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offers branch relaxation and also extends this concept to function
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calls, @code{MOVI} instructions and other instructions with immediate
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fields.
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@menu
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* Xtensa Branch Relaxation:: Relaxation of Branches.
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* Xtensa Call Relaxation:: Relaxation of Function Calls.
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* Xtensa Immediate Relaxation:: Relaxation of other Immediate Fields.
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@end menu
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@node Xtensa Branch Relaxation
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@subsection Conditional Branch Relaxation
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@cindex relaxation of branch instructions
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@cindex branch instructions, relaxation
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When the target of a branch is too far away from the branch itself,
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i.e., when the offset from the branch to the target is too large to fit
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in the immediate field of the branch instruction, it may be necessary to
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replace the branch with a branch around a jump. For example,
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@smallexample
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beqz a2, L
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@end smallexample
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may result in:
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@smallexample
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bnez.n a2, M
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j L
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M:
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@end smallexample
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(The @code{BNEZ.N} instruction would be used in this example only if the
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density option is available. Otherwise, @code{BNEZ} would be used.)
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This relaxation works well because the unconditional jump instruction
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has a much larger offset range than the various conditional branches.
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However, an error will occur if a branch target is beyond the range of a
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jump instruction. @command{@value{AS}} cannot relax unconditional jumps.
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Similarly, an error will occur if the original input contains an
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unconditional jump to a target that is out of range.
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Branch relaxation is enabled by default. It can be disabled by using
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underscore prefixes (@pxref{Xtensa Opcodes, ,Opcode Names}), the
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@samp{--no-transform} command-line option (@pxref{Xtensa Options,
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,Command Line Options}), or the @code{no-transform} directive
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(@pxref{Transform Directive, ,transform}).
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@node Xtensa Call Relaxation
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@subsection Function Call Relaxation
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@cindex relaxation of call instructions
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@cindex call instructions, relaxation
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Function calls may require relaxation because the Xtensa immediate call
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instructions (@code{CALL0}, @code{CALL4}, @code{CALL8} and
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@code{CALL12}) provide a PC-relative offset of only 512 Kbytes in either
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direction. For larger programs, it may be necessary to use indirect
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calls (@code{CALLX0}, @code{CALLX4}, @code{CALLX8} and @code{CALLX12})
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where the target address is specified in a register. The Xtensa
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assembler can automatically relax immediate call instructions into
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indirect call instructions. This relaxation is done by loading the
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address of the called function into the callee's return address register
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and then using a @code{CALLX} instruction. So, for example:
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@smallexample
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call8 func
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@end smallexample
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might be relaxed to:
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@smallexample
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.literal .L1, func
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l32r a8, .L1
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callx8 a8
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@end smallexample
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Because the addresses of targets of function calls are not generally
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known until link-time, the assembler must assume the worst and relax all
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the calls to functions in other source files, not just those that really
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will be out of range. The linker can recognize calls that were
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unnecessarily relaxed, and it will remove the overhead introduced by the
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assembler for those cases where direct calls are sufficient.
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Call relaxation is disabled by default because it can have a negative
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effect on both code size and performance, although the linker can
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usually eliminate the unnecessary overhead. If a program is too large
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and some of the calls are out of range, function call relaxation can be
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enabled using the @samp{--longcalls} command-line option or the
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@code{longcalls} directive (@pxref{Longcalls Directive, ,longcalls}).
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@node Xtensa Immediate Relaxation
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@subsection Other Immediate Field Relaxation
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@cindex immediate fields, relaxation
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@cindex relaxation of immediate fields
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The assembler normally performs the following other relaxations. They
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can be disabled by using underscore prefixes (@pxref{Xtensa Opcodes,
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,Opcode Names}), the @samp{--no-transform} command-line option
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(@pxref{Xtensa Options, ,Command Line Options}), or the
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@code{no-transform} directive (@pxref{Transform Directive, ,transform}).
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@cindex @code{MOVI} instructions, relaxation
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@cindex relaxation of @code{MOVI} instructions
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The @code{MOVI} machine instruction can only materialize values in the
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range from -2048 to 2047. Values outside this range are best
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materialized with @code{L32R} instructions. Thus:
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@smallexample
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movi a0, 100000
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@end smallexample
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is assembled into the following machine code:
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@smallexample
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.literal .L1, 100000
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l32r a0, .L1
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@end smallexample
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@cindex @code{L8UI} instructions, relaxation
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@cindex @code{L16SI} instructions, relaxation
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@cindex @code{L16UI} instructions, relaxation
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@cindex @code{L32I} instructions, relaxation
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@cindex relaxation of @code{L8UI} instructions
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@cindex relaxation of @code{L16SI} instructions
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@cindex relaxation of @code{L16UI} instructions
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@cindex relaxation of @code{L32I} instructions
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The @code{L8UI} machine instruction can only be used with immediate
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offsets in the range from 0 to 255. The @code{L16SI} and @code{L16UI}
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machine instructions can only be used with offsets from 0 to 510. The
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@code{L32I} machine instruction can only be used with offsets from 0 to
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1020. A load offset outside these ranges can be materalized with
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an @code{L32R} instruction if the destination register of the load
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is different than the source address register. For example:
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@smallexample
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l32i a1, a0, 2040
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@end smallexample
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is translated to:
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@smallexample
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.literal .L1, 2040
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l32r a1, .L1
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addi a1, a0, a1
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l32i a1, a1, 0
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@end smallexample
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@noindent
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If the load destination and source address register are the same, an
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out-of-range offset causes an error.
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@cindex @code{ADDI} instructions, relaxation
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@cindex relaxation of @code{ADDI} instructions
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The Xtensa @code{ADDI} instruction only allows immediate operands in the
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range from -128 to 127. There are a number of alternate instruction
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sequences for the @code{ADDI} operation. First, if the
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immediate is 0, the @code{ADDI} will be turned into a @code{MOV.N}
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instruction (or the equivalent @code{OR} instruction if the code density
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option is not available). If the @code{ADDI} immediate is outside of
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the range -128 to 127, but inside the range -32896 to 32639, an
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@code{ADDMI} instruction or @code{ADDMI}/@code{ADDI} sequence will be
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used. Finally, if the immediate is outside of this range and a free
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register is available, an @code{L32R}/@code{ADD} sequence will be used
|
|
with a literal allocated from the literal pool.
|
|
|
|
For example:
|
|
|
|
@smallexample
|
|
addi a5, a6, 0
|
|
addi a5, a6, 512
|
|
addi a5, a6, 513
|
|
addi a5, a6, 50000
|
|
@end smallexample
|
|
|
|
is assembled into the following:
|
|
|
|
@smallexample
|
|
.literal .L1, 50000
|
|
mov.n a5, a6
|
|
addmi a5, a6, 0x200
|
|
addmi a5, a6, 0x200
|
|
addi a5, a5, 1
|
|
l32r a5, .L1
|
|
add a5, a6, a5
|
|
@end smallexample
|
|
|
|
@node Xtensa Directives
|
|
@section Directives
|
|
@cindex Xtensa directives
|
|
@cindex directives, Xtensa
|
|
|
|
The Xtensa assember supports a region-based directive syntax:
|
|
|
|
@smallexample
|
|
.begin @var{directive} [@var{options}]
|
|
@dots{}
|
|
.end @var{directive}
|
|
@end smallexample
|
|
|
|
All the Xtensa-specific directives that apply to a region of code use
|
|
this syntax.
|
|
|
|
The directive applies to code between the @code{.begin} and the
|
|
@code{.end}. The state of the option after the @code{.end} reverts to
|
|
what it was before the @code{.begin}.
|
|
A nested @code{.begin}/@code{.end} region can further
|
|
change the state of the directive without having to be aware of its
|
|
outer state. For example, consider:
|
|
|
|
@smallexample
|
|
.begin no-transform
|
|
L: add a0, a1, a2
|
|
.begin transform
|
|
M: add a0, a1, a2
|
|
.end transform
|
|
N: add a0, a1, a2
|
|
.end no-transform
|
|
@end smallexample
|
|
|
|
The @code{ADD} opcodes at @code{L} and @code{N} in the outer
|
|
@code{no-transform} region both result in @code{ADD} machine instructions,
|
|
but the assembler selects an @code{ADD.N} instruction for the
|
|
@code{ADD} at @code{M} in the inner @code{transform} region.
|
|
|
|
The advantage of this style is that it works well inside macros which can
|
|
preserve the context of their callers.
|
|
|
|
The following directives are available:
|
|
@menu
|
|
* Schedule Directive:: Enable instruction scheduling.
|
|
* Longcalls Directive:: Use Indirect Calls for Greater Range.
|
|
* Transform Directive:: Disable All Assembler Transformations.
|
|
* Literal Directive:: Intermix Literals with Instructions.
|
|
* Literal Position Directive:: Specify Inline Literal Pool Locations.
|
|
* Literal Prefix Directive:: Specify Literal Section Name Prefix.
|
|
* Absolute Literals Directive:: Control PC-Relative vs. Absolute Literals.
|
|
* Frame Directive:: Describe a stack frame.
|
|
@end menu
|
|
|
|
@node Schedule Directive
|
|
@subsection schedule
|
|
@cindex @code{schedule} directive
|
|
@cindex @code{no-schedule} directive
|
|
|
|
The @code{schedule} directive is recognized only for compatibility with
|
|
Tensilica's assembler.
|
|
|
|
@smallexample
|
|
.begin [no-]schedule
|
|
.end [no-]schedule
|
|
@end smallexample
|
|
|
|
This directive is ignored and has no effect on @command{@value{AS}}.
|
|
|
|
@node Longcalls Directive
|
|
@subsection longcalls
|
|
@cindex @code{longcalls} directive
|
|
@cindex @code{no-longcalls} directive
|
|
|
|
The @code{longcalls} directive enables or disables function call
|
|
relaxation. @xref{Xtensa Call Relaxation, ,Function Call Relaxation}.
|
|
|
|
@smallexample
|
|
.begin [no-]longcalls
|
|
.end [no-]longcalls
|
|
@end smallexample
|
|
|
|
Call relaxation is disabled by default unless the @samp{--longcalls}
|
|
command-line option is specified. The @code{longcalls} directive
|
|
overrides the default determined by the command-line options.
|
|
|
|
@node Transform Directive
|
|
@subsection transform
|
|
@cindex @code{transform} directive
|
|
@cindex @code{no-transform} directive
|
|
|
|
This directive enables or disables all assembler transformation,
|
|
including relaxation (@pxref{Xtensa Relaxation, ,Xtensa Relaxation}) and
|
|
optimization (@pxref{Xtensa Optimizations, ,Xtensa Optimizations}).
|
|
|
|
@smallexample
|
|
.begin [no-]transform
|
|
.end [no-]transform
|
|
@end smallexample
|
|
|
|
Transformations are enabled by default unless the @samp{--no-transform}
|
|
option is used. The @code{transform} directive overrides the default
|
|
determined by the command-line options. An underscore opcode prefix,
|
|
disabling transformation of that opcode, always takes precedence over
|
|
both directives and command-line flags.
|
|
|
|
@node Literal Directive
|
|
@subsection literal
|
|
@cindex @code{literal} directive
|
|
|
|
The @code{.literal} directive is used to define literal pool data, i.e.,
|
|
read-only 32-bit data accessed via @code{L32R} instructions.
|
|
|
|
@smallexample
|
|
.literal @var{label}, @var{value}[, @var{value}@dots{}]
|
|
@end smallexample
|
|
|
|
This directive is similar to the standard @code{.word} directive, except
|
|
that the actual location of the literal data is determined by the
|
|
assembler and linker, not by the position of the @code{.literal}
|
|
directive. Using this directive gives the assembler freedom to locate
|
|
the literal data in the most appropriate place and possibly to combine
|
|
identical literals. For example, the code:
|
|
|
|
@smallexample
|
|
entry sp, 40
|
|
.literal .L1, sym
|
|
l32r a4, .L1
|
|
@end smallexample
|
|
|
|
can be used to load a pointer to the symbol @code{sym} into register
|
|
@code{a4}. The value of @code{sym} will not be placed between the
|
|
@code{ENTRY} and @code{L32R} instructions; instead, the assembler puts
|
|
the data in a literal pool.
|
|
|
|
Literal pools for absolute mode @code{L32R} instructions
|
|
(@pxref{Absolute Literals Directive}) are placed in a seperate
|
|
@code{.lit4} section. By default literal pools for PC-relative mode
|
|
@code{L32R} instructions are placed in a separate @code{.literal}
|
|
section; however, when using the @samp{--text-@-section-@-literals}
|
|
option (@pxref{Xtensa Options, ,Command Line Options}), the literal
|
|
pools are placed in the current section. These text section literal
|
|
pools are created automatically before @code{ENTRY} instructions and
|
|
manually after @samp{.literal_position} directives (@pxref{Literal
|
|
Position Directive, ,literal_position}). If there are no preceding
|
|
@code{ENTRY} instructions, explicit @code{.literal_position} directives
|
|
must be used to place the text section literal pools; otherwise,
|
|
@command{@value{AS}} will report an error.
|
|
|
|
@node Literal Position Directive
|
|
@subsection literal_position
|
|
@cindex @code{literal_position} directive
|
|
|
|
When using @samp{--text-@-section-@-literals} to place literals inline
|
|
in the section being assembled, the @code{.literal_position} directive
|
|
can be used to mark a potential location for a literal pool.
|
|
|
|
@smallexample
|
|
.literal_position
|
|
@end smallexample
|
|
|
|
The @code{.literal_position} directive is ignored when the
|
|
@samp{--text-@-section-@-literals} option is not used or when
|
|
@code{L32R} instructions use the absolute addressing mode.
|
|
|
|
The assembler will automatically place text section literal pools
|
|
before @code{ENTRY} instructions, so the @code{.literal_position}
|
|
directive is only needed to specify some other location for a literal
|
|
pool. You may need to add an explicit jump instruction to skip over an
|
|
inline literal pool.
|
|
|
|
For example, an interrupt vector does not begin with an @code{ENTRY}
|
|
instruction so the assembler will be unable to automatically find a good
|
|
place to put a literal pool. Moreover, the code for the interrupt
|
|
vector must be at a specific starting address, so the literal pool
|
|
cannot come before the start of the code. The literal pool for the
|
|
vector must be explicitly positioned in the middle of the vector (before
|
|
any uses of the literals, due to the negative offsets used by
|
|
PC-relative @code{L32R} instructions). The @code{.literal_position}
|
|
directive can be used to do this. In the following code, the literal
|
|
for @samp{M} will automatically be aligned correctly and is placed after
|
|
the unconditional jump.
|
|
|
|
@smallexample
|
|
.global M
|
|
code_start:
|
|
j continue
|
|
.literal_position
|
|
.align 4
|
|
continue:
|
|
movi a4, M
|
|
@end smallexample
|
|
|
|
@node Literal Prefix Directive
|
|
@subsection literal_prefix
|
|
@cindex @code{literal_prefix} directive
|
|
|
|
The @code{literal_prefix} directive allows you to specify different
|
|
sections to hold literals from different portions of an assembly file.
|
|
With this directive, a single assembly file can be used to generate code
|
|
into multiple sections, including literals generated by the assembler.
|
|
|
|
@smallexample
|
|
.begin literal_prefix [@var{name}]
|
|
.end literal_prefix
|
|
@end smallexample
|
|
|
|
By default the assembler places literal pools in sections separate from
|
|
the instructions, using the default literal section names of
|
|
@code{.literal} for PC-relative mode @code{L32R} instructions and
|
|
@code{.lit4} for absolute mode @code{L32R} instructions (@pxref{Absolute
|
|
Literals Directive}). The @code{literal_prefix} directive causes
|
|
different literal sections to be used for the code inside the delimited
|
|
region. The new literal sections are determined by including @var{name}
|
|
as a prefix to the default literal section names. If the @var{name}
|
|
argument is omitted, the literal sections revert to the defaults. This
|
|
directive has no effect when using the
|
|
@samp{--text-@-section-@-literals} option (@pxref{Xtensa Options,
|
|
,Command Line Options}).
|
|
|
|
Except for two special cases, the assembler determines the new literal
|
|
sections by simply prepending @var{name} to the default section names,
|
|
resulting in @code{@var{name}.literal} and @code{@var{name}.lit4}
|
|
sections. The @code{literal_prefix} directive is often used with the
|
|
name of the current text section as the prefix argument. To facilitate
|
|
this usage, the assembler uses special case rules when it recognizes
|
|
@var{name} as a text section name. First, if @var{name} ends with
|
|
@code{.text}, that suffix is not included in the literal section name.
|
|
For example, if @var{name} is @code{.iram0.text}, then the literal
|
|
sections will be @code{.iram0.literal} and @code{.iram0.lit4}. Second,
|
|
if @var{name} begins with @code{.gnu.linkonce.t.}, then the literal
|
|
section names are formed by replacing the @code{.t} substring with
|
|
@code{.literal} and @code{.lit4}. For example, if @var{name} is
|
|
@code{.gnu.linkonce.t.func}, the literal sections will be
|
|
@code{.gnu.linkonce.literal.func} and @code{.gnu.linkonce.lit4.func}.
|
|
|
|
@node Absolute Literals Directive
|
|
@subsection absolute-literals
|
|
@cindex @code{absolute-literals} directive
|
|
@cindex @code{no-absolute-literals} directive
|
|
|
|
The @code{absolute-@-literals} and @code{no-@-absolute-@-literals}
|
|
directives control the absolute vs.@: PC-relative mode for @code{L32R}
|
|
instructions. These are relevant only for Xtensa configurations that
|
|
include the absolute addressing option for @code{L32R} instructions.
|
|
|
|
@smallexample
|
|
.begin [no-]absolute-literals
|
|
.end [no-]absolute-literals
|
|
@end smallexample
|
|
|
|
These directives do not change the @code{L32R} mode---they only cause
|
|
the assembler to emit the appropriate kind of relocation for @code{L32R}
|
|
instructions and to place the literal values in the appropriate section.
|
|
To change the @code{L32R} mode, the program must write the
|
|
@code{LITBASE} special register. It is the programmer's responsibility
|
|
to keep track of the mode and indicate to the assembler which mode is
|
|
used in each region of code.
|
|
|
|
If the Xtensa configuration includes the absolute @code{L32R} addressing
|
|
option, the default is to assume absolute @code{L32R} addressing unless
|
|
the @samp{--no-@-absolute-@-literals} command-line option is specified.
|
|
Otherwise, the default is to assume PC-relative @code{L32R} addressing.
|
|
The @code{absolute-@-literals} directive can then be used to override
|
|
the default determined by the command-line options.
|
|
|
|
@node Frame Directive
|
|
@subsection frame
|
|
@cindex @code{frame} directive
|
|
|
|
This directive tells the assembler to emit information to allow the
|
|
debugger to locate a function's stack frame. The syntax is:
|
|
|
|
@smallexample
|
|
.frame @var{reg}, @var{size}
|
|
@end smallexample
|
|
|
|
where @var{reg} is the register used to hold the frame pointer (usually
|
|
the same as the stack pointer) and @var{size} is the size in bytes of
|
|
the stack frame. The @code{.frame} directive is typically placed
|
|
near the @code{ENTRY} instruction for a function.
|
|
|
|
In many circumstances, this information just duplicates the
|
|
information given in the function's @code{ENTRY} instruction; however,
|
|
there are two cases where this is not true:
|
|
|
|
@enumerate
|
|
@item
|
|
The size of the stack frame is too big to fit in the immediate field
|
|
of the @code{ENTRY} instruction.
|
|
|
|
@item
|
|
The frame pointer is different than the stack pointer, as with functions
|
|
that call @code{alloca}.
|
|
@end enumerate
|
|
|
|
@c Local Variables:
|
|
@c fill-column: 72
|
|
@c End:
|