@c Copyright (C) 2002, 2003, 2004, 2005, 2006, 2007, 2008 @c Free Software Foundation, Inc. @c This is part of the GAS manual. @c For copying conditions, see the file as.texinfo. @c @c man end @ifset GENERIC @page @node Xtensa-Dependent @chapter Xtensa Dependent Features @end ifset @ifclear GENERIC @node Machine Dependencies @chapter Xtensa Dependent Features @end ifclear @cindex Xtensa architecture This chapter covers features of the @sc{gnu} assembler that are specific to the Xtensa architecture. For details about the Xtensa instruction set, please consult the @cite{Xtensa Instruction Set Architecture (ISA) Reference Manual}. @menu * Xtensa Options:: Command-line Options. * Xtensa Syntax:: Assembler Syntax for Xtensa Processors. * Xtensa Optimizations:: Assembler Optimizations. * Xtensa Relaxation:: Other Automatic Transformations. * Xtensa Directives:: Directives for Xtensa Processors. @end menu @node Xtensa Options @section Command Line Options @c man begin OPTIONS @table @gcctabopt @item --text-section-literals | --no-text-section-literals @kindex --text-section-literals @kindex --no-text-section-literals Control the treatment of literal pools. The default is @samp{--no-@-text-@-section-@-literals}, which places literals in separate sections in the output file. This allows the literal pool to be placed in a data RAM/ROM. With @samp{--text-@-section-@-literals}, the literals are interspersed in the text section in order to keep them as close as possible to their references. This may be necessary for large assembly files, where the literals would otherwise be out of range of the @code{L32R} instructions in the text section. These options only affect literals referenced via PC-relative @code{L32R} instructions; literals for absolute mode @code{L32R} instructions are handled separately. @xref{Literal Directive, ,literal}. @item --absolute-literals | --no-absolute-literals @kindex --absolute-literals @kindex --no-absolute-literals Indicate to the assembler whether @code{L32R} instructions use absolute or PC-relative addressing. If the processor includes the absolute addressing option, the default is to use absolute @code{L32R} relocations. Otherwise, only the PC-relative @code{L32R} relocations can be used. @item --target-align | --no-target-align @kindex --target-align @kindex --no-target-align Enable or disable automatic alignment to reduce branch penalties at some expense in code size. @xref{Xtensa Automatic Alignment, ,Automatic Instruction Alignment}. This optimization is enabled by default. Note that the assembler will always align instructions like @code{LOOP} that have fixed alignment requirements. @item --longcalls | --no-longcalls @kindex --longcalls @kindex --no-longcalls Enable or disable transformation of call instructions to allow calls across a greater range of addresses. @xref{Xtensa Call Relaxation, ,Function Call Relaxation}. This option should be used when call targets can potentially be out of range. It may degrade both code size and performance, but the linker can generally optimize away the unnecessary overhead when a call ends up within range. The default is @samp{--no-@-longcalls}. @item --transform | --no-transform @kindex --transform @kindex --no-transform Enable or disable all assembler transformations of Xtensa instructions, including both relaxation and optimization. The default is @samp{--transform}; @samp{--no-transform} should only be used in the rare cases when the instructions must be exactly as specified in the assembly source. Using @samp{--no-transform} causes out of range instruction operands to be errors. @item --rename-section @var{oldname}=@var{newname} @kindex --rename-section Rename the @var{oldname} section to @var{newname}. This option can be used multiple times to rename multiple sections. @end table @c man end @node Xtensa Syntax @section Assembler Syntax @cindex syntax, Xtensa assembler @cindex Xtensa assembler syntax @cindex FLIX syntax Block comments are delimited by @samp{/*} and @samp{*/}. End of line comments may be introduced with either @samp{#} or @samp{//}. Instructions consist of a leading opcode or macro name followed by whitespace and an optional comma-separated list of operands: @smallexample @var{opcode} [@var{operand}, @dots{}] @end smallexample Instructions must be separated by a newline or semicolon. FLIX instructions, which bundle multiple opcodes together in a single instruction, are specified by enclosing the bundled opcodes inside braces: @smallexample @group @{ [@var{format}] @var{opcode0} [@var{operands}] @end group @var{opcode1} [@var{operands}] @group @var{opcode2} [@var{operands}] @dots{} @} @end group @end smallexample The opcodes in a FLIX instruction are listed in the same order as the corresponding instruction slots in the TIE format declaration. Directives and labels are not allowed inside the braces of a FLIX instruction. A particular TIE format name can optionally be specified immediately after the opening brace, but this is usually unnecessary. The assembler will automatically search for a format that can encode the specified opcodes, so the format name need only be specified in rare cases where there is more than one applicable format and where it matters which of those formats is used. A FLIX instruction can also be specified on a single line by separating the opcodes with semicolons: @smallexample @{ [@var{format};] @var{opcode0} [@var{operands}]; @var{opcode1} [@var{operands}]; @var{opcode2} [@var{operands}]; @dots{} @} @end smallexample If an opcode can only be encoded in a FLIX instruction but is not specified as part of a FLIX bundle, the assembler will choose the smallest format where the opcode can be encoded and will fill unused instruction slots with no-ops. @menu * Xtensa Opcodes:: Opcode Naming Conventions. * Xtensa Registers:: Register Naming. @end menu @node Xtensa Opcodes @subsection Opcode Names @cindex Xtensa opcode names @cindex opcode names, Xtensa See the @cite{Xtensa Instruction Set Architecture (ISA) Reference Manual} for a complete list of opcodes and descriptions of their semantics. @cindex _ opcode prefix If an opcode name is prefixed with an underscore character (@samp{_}), @command{@value{AS}} will not transform that instruction in any way. The underscore prefix disables both optimization (@pxref{Xtensa Optimizations, ,Xtensa Optimizations}) and relaxation (@pxref{Xtensa Relaxation, ,Xtensa Relaxation}) for that particular instruction. Only use the underscore prefix when it is essential to select the exact opcode produced by the assembler. Using this feature unnecessarily makes the code less efficient by disabling assembler optimization and less flexible by disabling relaxation. Note that this special handling of underscore prefixes only applies to Xtensa opcodes, not to either built-in macros or user-defined macros. When an underscore prefix is used with a macro (e.g., @code{_MOV}), it refers to a different macro. The assembler generally provides built-in macros both with and without the underscore prefix, where the underscore versions behave as if the underscore carries through to the instructions in the macros. For example, @code{_MOV} may expand to @code{_MOV.N}@. The underscore prefix only applies to individual instructions, not to series of instructions. For example, if a series of instructions have underscore prefixes, the assembler will not transform the individual instructions, but it may insert other instructions between them (e.g., to align a @code{LOOP} instruction). To prevent the assembler from modifying a series of instructions as a whole, use the @code{no-transform} directive. @xref{Transform Directive, ,transform}. @node Xtensa Registers @subsection Register Names @cindex Xtensa register names @cindex register names, Xtensa @cindex sp register The assembly syntax for a register file entry is the ``short'' name for a TIE register file followed by the index into that register file. For example, the general-purpose @code{AR} register file has a short name of @code{a}, so these registers are named @code{a0}@dots{}@code{a15}. As a special feature, @code{sp} is also supported as a synonym for @code{a1}. Additional registers may be added by processor configuration options and by designer-defined TIE extensions. An initial @samp{$} character is optional in all register names. @node Xtensa Optimizations @section Xtensa Optimizations @cindex optimizations The optimizations currently supported by @command{@value{AS}} are generation of density instructions where appropriate and automatic branch target alignment. @menu * Density Instructions:: Using Density Instructions. * Xtensa Automatic Alignment:: Automatic Instruction Alignment. @end menu @node Density Instructions @subsection Using Density Instructions @cindex density instructions The Xtensa instruction set has a code density option that provides 16-bit versions of some of the most commonly used opcodes. Use of these opcodes can significantly reduce code size. When possible, the assembler automatically translates instructions from the core Xtensa instruction set into equivalent instructions from the Xtensa code density option. This translation can be disabled by using underscore prefixes (@pxref{Xtensa Opcodes, ,Opcode Names}), by using the @samp{--no-transform} command-line option (@pxref{Xtensa Options, ,Command Line Options}), or by using the @code{no-transform} directive (@pxref{Transform Directive, ,transform}). It is a good idea @emph{not} to use the density instructions directly. The assembler will automatically select dense instructions where possible. If you later need to use an Xtensa processor without the code density option, the same assembly code will then work without modification. @node Xtensa Automatic Alignment @subsection Automatic Instruction Alignment @cindex alignment of @code{LOOP} instructions @cindex alignment of branch targets @cindex @code{LOOP} instructions, alignment @cindex branch target alignment The Xtensa assembler will automatically align certain instructions, both to optimize performance and to satisfy architectural requirements. As an optimization to improve performance, the assembler attempts to align branch targets so they do not cross instruction fetch boundaries. (Xtensa processors can be configured with either 32-bit or 64-bit instruction fetch widths.) An instruction immediately following a call is treated as a branch target in this context, because it will be the target of a return from the call. This alignment has the potential to reduce branch penalties at some expense in code size. This optimization is enabled by default. You can disable it with the @samp{--no-target-@-align} command-line option (@pxref{Xtensa Options, ,Command Line Options}). The target alignment optimization is done without adding instructions that could increase the execution time of the program. If there are density instructions in the code preceding a target, the assembler can change the target alignment by widening some of those instructions to the equivalent 24-bit instructions. Extra bytes of padding can be inserted immediately following unconditional jump and return instructions. This approach is usually successful in aligning many, but not all, branch targets. The @code{LOOP} family of instructions must be aligned such that the first instruction in the loop body does not cross an instruction fetch boundary (e.g., with a 32-bit fetch width, a @code{LOOP} instruction must be on either a 1 or 2 mod 4 byte boundary). The assembler knows about this restriction and inserts the minimal number of 2 or 3 byte no-op instructions to satisfy it. When no-op instructions are added, any label immediately preceding the original loop will be moved in order to refer to the loop instruction, not the newly generated no-op instruction. To preserve binary compatibility across processors with different fetch widths, the assembler conservatively assumes a 32-bit fetch width when aligning @code{LOOP} instructions (except if the first instruction in the loop is a 64-bit instruction). Previous versions of the assembler automatically aligned @code{ENTRY} instructions to 4-byte boundaries, but that alignment is now the programmer's responsibility. @node Xtensa Relaxation @section Xtensa Relaxation @cindex relaxation When an instruction operand is outside the range allowed for that particular instruction field, @command{@value{AS}} can transform the code to use a functionally-equivalent instruction or sequence of instructions. This process is known as @dfn{relaxation}. This is typically done for branch instructions because the distance of the branch targets is not known until assembly-time. The Xtensa assembler offers branch relaxation and also extends this concept to function calls, @code{MOVI} instructions and other instructions with immediate fields. @menu * Xtensa Branch Relaxation:: Relaxation of Branches. * Xtensa Call Relaxation:: Relaxation of Function Calls. * Xtensa Immediate Relaxation:: Relaxation of other Immediate Fields. @end menu @node Xtensa Branch Relaxation @subsection Conditional Branch Relaxation @cindex relaxation of branch instructions @cindex branch instructions, relaxation When the target of a branch is too far away from the branch itself, i.e., when the offset from the branch to the target is too large to fit in the immediate field of the branch instruction, it may be necessary to replace the branch with a branch around a jump. For example, @smallexample beqz a2, L @end smallexample may result in: @smallexample @group bnez.n a2, M j L M: @end group @end smallexample (The @code{BNEZ.N} instruction would be used in this example only if the density option is available. Otherwise, @code{BNEZ} would be used.) This relaxation works well because the unconditional jump instruction has a much larger offset range than the various conditional branches. However, an error will occur if a branch target is beyond the range of a jump instruction. @command{@value{AS}} cannot relax unconditional jumps. Similarly, an error will occur if the original input contains an unconditional jump to a target that is out of range. Branch relaxation is enabled by default. It can be disabled by using underscore prefixes (@pxref{Xtensa Opcodes, ,Opcode Names}), the @samp{--no-transform} command-line option (@pxref{Xtensa Options, ,Command Line Options}), or the @code{no-transform} directive (@pxref{Transform Directive, ,transform}). @node Xtensa Call Relaxation @subsection Function Call Relaxation @cindex relaxation of call instructions @cindex call instructions, relaxation Function calls may require relaxation because the Xtensa immediate call instructions (@code{CALL0}, @code{CALL4}, @code{CALL8} and @code{CALL12}) provide a PC-relative offset of only 512 Kbytes in either direction. For larger programs, it may be necessary to use indirect calls (@code{CALLX0}, @code{CALLX4}, @code{CALLX8} and @code{CALLX12}) where the target address is specified in a register. The Xtensa assembler can automatically relax immediate call instructions into indirect call instructions. This relaxation is done by loading the address of the called function into the callee's return address register and then using a @code{CALLX} instruction. So, for example: @smallexample call8 func @end smallexample might be relaxed to: @smallexample @group .literal .L1, func l32r a8, .L1 callx8 a8 @end group @end smallexample Because the addresses of targets of function calls are not generally known until link-time, the assembler must assume the worst and relax all the calls to functions in other source files, not just those that really will be out of range. The linker can recognize calls that were unnecessarily relaxed, and it will remove the overhead introduced by the assembler for those cases where direct calls are sufficient. Call relaxation is disabled by default because it can have a negative effect on both code size and performance, although the linker can usually eliminate the unnecessary overhead. If a program is too large and some of the calls are out of range, function call relaxation can be enabled using the @samp{--longcalls} command-line option or the @code{longcalls} directive (@pxref{Longcalls Directive, ,longcalls}). @node Xtensa Immediate Relaxation @subsection Other Immediate Field Relaxation @cindex immediate fields, relaxation @cindex relaxation of immediate fields The assembler normally performs the following other relaxations. They can be disabled by using underscore prefixes (@pxref{Xtensa Opcodes, ,Opcode Names}), the @samp{--no-transform} command-line option (@pxref{Xtensa Options, ,Command Line Options}), or the @code{no-transform} directive (@pxref{Transform Directive, ,transform}). @cindex @code{MOVI} instructions, relaxation @cindex relaxation of @code{MOVI} instructions The @code{MOVI} machine instruction can only materialize values in the range from -2048 to 2047. Values outside this range are best materialized with @code{L32R} instructions. Thus: @smallexample movi a0, 100000 @end smallexample is assembled into the following machine code: @smallexample @group .literal .L1, 100000 l32r a0, .L1 @end group @end smallexample @cindex @code{L8UI} instructions, relaxation @cindex @code{L16SI} instructions, relaxation @cindex @code{L16UI} instructions, relaxation @cindex @code{L32I} instructions, relaxation @cindex relaxation of @code{L8UI} instructions @cindex relaxation of @code{L16SI} instructions @cindex relaxation of @code{L16UI} instructions @cindex relaxation of @code{L32I} instructions The @code{L8UI} machine instruction can only be used with immediate offsets in the range from 0 to 255. The @code{L16SI} and @code{L16UI} machine instructions can only be used with offsets from 0 to 510. The @code{L32I} machine instruction can only be used with offsets from 0 to 1020. A load offset outside these ranges can be materialized with an @code{L32R} instruction if the destination register of the load is different than the source address register. For example: @smallexample l32i a1, a0, 2040 @end smallexample is translated to: @smallexample @group .literal .L1, 2040 l32r a1, .L1 @end group @group add a1, a0, a1 l32i a1, a1, 0 @end group @end smallexample @noindent If the load destination and source address register are the same, an out-of-range offset causes an error. @cindex @code{ADDI} instructions, relaxation @cindex relaxation of @code{ADDI} instructions The Xtensa @code{ADDI} instruction only allows immediate operands in the range from -128 to 127. There are a number of alternate instruction sequences for the @code{ADDI} operation. First, if the immediate is 0, the @code{ADDI} will be turned into a @code{MOV.N} instruction (or the equivalent @code{OR} instruction if the code density option is not available). If the @code{ADDI} immediate is outside of the range -128 to 127, but inside the range -32896 to 32639, an @code{ADDMI} instruction or @code{ADDMI}/@code{ADDI} sequence will be used. Finally, if the immediate is outside of this range and a free register is available, an @code{L32R}/@code{ADD} sequence will be used with a literal allocated from the literal pool. For example: @smallexample @group addi a5, a6, 0 addi a5, a6, 512 @end group @group addi a5, a6, 513 addi a5, a6, 50000 @end group @end smallexample is assembled into the following: @smallexample @group .literal .L1, 50000 mov.n a5, a6 @end group addmi a5, a6, 0x200 addmi a5, a6, 0x200 addi a5, a5, 1 @group l32r a5, .L1 add a5, a6, a5 @end group @end smallexample @node Xtensa Directives @section Directives @cindex Xtensa directives @cindex directives, Xtensa The Xtensa assembler supports a region-based directive syntax: @smallexample @group .begin @var{directive} [@var{options}] @dots{} .end @var{directive} @end group @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 @group .begin no-transform L: add a0, a1, a2 @end group .begin transform M: add a0, a1, a2 .end transform @group N: add a0, a1, a2 .end no-transform @end group @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. @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 @group .begin [no-]schedule .end [no-]schedule @end group @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 @group .begin [no-]longcalls .end [no-]longcalls @end group @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 @group .begin [no-]transform .end [no-]transform @end group @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 @group entry sp, 40 .literal .L1, sym l32r a4, .L1 @end group @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 are placed by default in separate literal sections; however, when using the @samp{--text-@-section-@-literals} option (@pxref{Xtensa Options, ,Command Line Options}), the literal pools for PC-relative mode @code{L32R} instructions are placed in the current section.@footnote{Literals for the @code{.init} and @code{.fini} sections are always placed in separate sections, even when @samp{--text-@-section-@-literals} is enabled.} 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. When literals are placed in separate sections, the literal section names are derived from the names of the sections where the literals are defined. The base literal section names are @code{.literal} for PC-relative mode @code{L32R} instructions and @code{.lit4} for absolute mode @code{L32R} instructions (@pxref{Absolute Literals Directive, ,absolute-literals}). These base names are used for literals defined in the default @code{.text} section. For literals defined in other sections or within the scope of a @code{literal_prefix} directive (@pxref{Literal Prefix Directive, ,literal_prefix}), the following rules determine the literal section name: @enumerate @item If the current section is a member of a section group, the literal section name includes the group name as a suffix to the base @code{.literal} or @code{.lit4} name, with a period to separate the base name and group name. The literal section is also made a member of the group. @item If the current section name (or @code{literal_prefix} value) begins with ``@code{.gnu.linkonce.@var{kind}.}'', the literal section name is formed by replacing ``@code{.@var{kind}}'' with the base @code{.literal} or @code{.lit4} name. For example, for literals defined in a section named @code{.gnu.linkonce.t.func}, the literal section will be @code{.gnu.linkonce.literal.func} or @code{.gnu.linkonce.lit4.func}. @item If the current section name (or @code{literal_prefix} value) ends with @code{.text}, the literal section name is formed by replacing that suffix with the base @code{.literal} or @code{.lit4} name. For example, for literals defined in a section named @code{.iram0.text}, the literal section will be @code{.iram0.literal} or @code{.iram0.lit4}. @item If none of the preceding conditions apply, the literal section name is formed by adding the base @code{.literal} or @code{.lit4} name as a suffix to the current section name (or @code{literal_prefix} value). @end enumerate @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 @group .global M code_start: @end group j continue .literal_position .align 4 @group continue: movi a4, M @end group @end smallexample @node Literal Prefix Directive @subsection literal_prefix @cindex @code{literal_prefix} directive The @code{literal_prefix} directive allows you to override the default literal section names, which are derived from the names of the sections where the literals are defined. @smallexample @group .begin literal_prefix [@var{name}] .end literal_prefix @end group @end smallexample For literals defined within the delimited region, the literal section names are derived from the @var{name} argument instead of the name of the current section. The rules used to derive the literal section names do not change. @xref{Literal Directive, ,literal}. 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}). @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 @group .begin [no-]absolute-literals .end [no-]absolute-literals @end group @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. @c Local Variables: @c fill-column: 72 @c End: