@c Copyright 2002 @c Free Software Foundation, Inc. @c This is part of the GAS manual. @c For copying conditions, see the file as.texinfo. @ifset GENERIC @page @node Alpha-Dependent @chapter Alpha Dependent Features @end ifset @ifclear GENERIC @node Machine Dependencies @chapter Alpha Dependent Features @end ifclear @cindex Alpha support @menu * Alpha Notes:: Notes * Alpha Options:: Options * Alpha Syntax:: Syntax * Alpha Floating Point:: Floating Point * Alpha Directives:: Alpha Machine Directives * Alpha Opcodes:: Opcodes @end menu @node Alpha Notes @section Notes @cindex Alpha notes @cindex notes for Alpha The documentation here is primarily for the ELF object format. @code{@value{AS}} also supports the ECOFF and EVAX formats, but features specific to these formats are not yet documented. @node Alpha Options @section Options @cindex Alpha options @cindex options for Alpha @table @option @cindex @code{-m@var{cpu}} command line option, Alpha @item -m@var{cpu} This option specifies the target processor. If an attempt is made to assemble an instruction which will not execute on the target processor, the assembler may either expand the instruction as a macro or issue an error message. This option is equivalent to the @code{.arch} directive. The following processor names are recognized: @code{21064}, @code{21064a}, @code{21066}, @code{21068}, @code{21164}, @code{21164a}, @code{21164pc}, @code{21264}, @code{21264a}, @code{21264b}, @code{ev4}, @code{ev5}, @code{lca45}, @code{ev5}, @code{ev56}, @code{pca56}, @code{ev6}, @code{ev67}, @code{ev68}. The special name @code{all} may be used to allow the assembler to accept instructions valid for any Alpha processor. In order to support existing practice in OSF/1 with respect to @code{.arch}, and existing practice within @command{MILO} (the Linux ARC bootloader), the numbered processor names (e.g.@: 21064) enable the processor-specific PALcode instructions, while the ``electro-vlasic'' names (e.g.@: @code{ev4}) do not. @cindex @code{-mdebug} command line option, Alpha @cindex @code{-no-mdebug} command line option, Alpha @item -mdebug @itemx -no-mdebug Enables or disables the generation of @code{.mdebug} encapsulation for stabs directives and procedure descriptors. The default is to automatically enable @code{.mdebug} when the first stabs directive is seen. @cindex @code{-relax} command line option, Alpha @item -relax This option forces all relocations to be put into the object file, instead of saving space and resolving some relocations at assembly time. Note that this option does not propagate all symbol arithmetic into the object file, because not all symbol arithmetic can be represented. However, the option can still be useful in specific applications. @cindex @code{-g} command line option, Alpha @item -g This option is used when the compiler generates debug information. When @command{gcc} is using @command{mips-tfile} to generate debug information for ECOFF, local labels must be passed through to the object file. Otherwise this option has no effect. @cindex @code{-G} command line option, Alpha @item -G@var{size} A local common symbol larger than @var{size} is placed in @code{.bss}, while smaller symbols are placed in @code{.sbss}. @cindex @code{-F} command line option, Alpha @cindex @code{-32addr} command line option, Alpha @item -F @itemx -32addr These options are ignored for backward compatibility. @end table @cindex Alpha Syntax @node Alpha Syntax @section Syntax The assembler syntax closely follow the Alpha Reference Manual; assembler directives and general syntax closely follow the OSF/1 and OpenVMS syntax, with a few differences for ELF. @menu * Alpha-Chars:: Special Characters * Alpha-Regs:: Register Names * Alpha-Relocs:: Relocations @end menu @node Alpha-Chars @subsection Special Characters @cindex line comment character, Alpha @cindex Alpha line comment character @samp{#} is the line comment character. @cindex line separator, Alpha @cindex statement separator, Alpha @cindex Alpha line separator @samp{;} can be used instead of a newline to separate statements. @node Alpha-Regs @subsection Register Names @cindex Alpha registers @cindex register names, Alpha The 32 integer registers are refered to as @samp{$@var{n}} or @samp{$r@var{n}}. In addition, registers 15, 28, 29, and 30 may be refered to by the symbols @samp{$fp}, @samp{$at}, @samp{$gp}, and @samp{$sp} respectively. The 32 floating-point registers are refered to as @samp{$f@var{n}}. @node Alpha-Relocs @subsection Relocations @cindex Alpha relocations @cindex relocations, Alpha Some of these relocations are available for ECOFF, but mostly only for ELF. They are modeled after the relocation format introduced in Digial Unix 4.0, but there are additions. The format is @samp{!@var{tag}} or @samp{!@var{tag}!@var{number}} where @var{tag} is the name of the relocation. In some cases @var{number} is used to relate specific instructions. The relocation is placed at the end of the instruction like so: @example ldah $0,a($29) !gprelhigh lda $0,a($0) !gprellow ldq $1,b($29) !literal!100 ldl $2,0($1) !lituse_base!100 @end example @table @code @item !literal @itemx !literal!@var{N} Used with an @code{ldq} instruction to load the address of a symbol from the GOT. A sequence number @var{N} is optional, and if present is used to pair @code{lituse} relocations with this @code{literal} relocation. The @code{lituse} relocations are used by the linker to optimize the code based on the final location of the symbol. Note that these optimizations are dependent on the data flow of the program. Therefore, if @emph{any} @code{lituse} is paired with a @code{literal} relocation, then @emph{all} uses of the register set by the @code{literal} instruction must also be marked with @code{lituse} relocations. This is because the original @code{literal} instruction may be deleted or transformed into another instruction. Also note that there may be a one-to-many relationship between @code{literal} and @code{lituse}, but not a many-to-one. That is, if there are two code paths that load up the same address and feed the value to a single use, then the use may not use a @code{lituse} relocation. @item !lituse_base!@var{N} Used with any memory format instruction (e.g.@: @code{ldl}) to indicate that the literal is used for an address load. The offset field of the instruction must be zero. During relaxation, the code may be altered to use a gp-relative load. @item !lituse_jsr!@var{N} Used with a register branch format instruction (e.g.@: @code{jsr}) to indicate that the literal is used for a call. During relaxation, the code may be altered to use a direct branch (e.g.@: @code{bsr}). @item !lituse_bytoff!@var{N} Used with a byte mask instruction (e.g.@: @code{extbl}) to indicate that only the low 3 bits of the address are relevant. During relaxation, the code may be altered to use an immediate instead of a register shift. @item !lituse_addr!@var{N} Used with any other instruction to indicate that the original address is in fact used, and the original @code{ldq} instruction may not be altered or deleted. This is useful in conjunction with @code{lituse_jsr} to test whether a weak symbol is defined. @example ldq $27,foo($29) !literal!1 beq $27,is_undef !lituse_addr!1 jsr $26,($27),foo !lituse_jsr!1 @end example @item !lituse_tlsgd!@var{N} Used with a register branch format instruction to indicate that the literal is the call to @code{__tls_get_addr} used to compute the address of the thread-local storage variable whose descriptor was loaded with @code{!tlsgd!@var{N}}. @item !lituse_tlsldm!@var{N} Used with a register branch format instruction to indicate that the literal is the call to @code{__tls_get_addr} used to compute the address of the base of the thread-local storage block for the current module. The descriptor for the module must have been loaded with @code{!tlsldm!@var{N}}. @item !gpdisp!@var{N} Used with @code{ldah} and @code{lda} to load the GP from the current address, a-la the @code{ldgp} macro. The source register for the @code{ldah} instruction must contain the address of the @code{ldah} instruction. There must be exactly one @code{lda} instruction paired with the @code{ldah} instruction, though it may appear anywhere in the instruction stream. The immediate operands must be zero. @example bsr $26,foo ldah $29,0($26) !gpdisp!1 lda $29,0($29) !gpdisp!1 @end example @item !gprelhigh Used with an @code{ldah} instruction to add the high 16 bits of a 32-bit displacement from the GP. @item !gprellow Used with any memory format instruction to add the low 16 bits of a 32-bit displacement from the GP. @item !gprel Used with any memory format instruction to add a 16-bit displacement from the GP. @item !samegp Used with any branch format instruction to skip the GP load at the target address. The referenced symbol must have the same GP as the source object file, and it must be declared to either not use @code{$27} or perform a standard GP load in the first two instructions via the @code{.prologue} directive. @item !tlsgd @itemx !tlsgd!@var{N} Used with an @code{lda} instruction to load the address of a TLS descriptor for a symbol in the GOT. The sequence number @var{N} is optional, and if present it used to pair the descriptor load with both the @code{literal} loading the address of the @code{__tls_get_addr} function and the @code{lituse_tlsgd} marking the call to that function. For proper relaxation, both the @code{tlsgd}, @code{literal} and @code{lituse} relocations must be in the same extended basic block. That is, the relocation with the lowest address must be executed first at runtime. @item !tlsldm @itemx !tlsldm!@var{N} Used with an @code{lda} instruction to load the address of a TLS descriptor for the current module in the GOT. Similar in other respects to @code{tlsgd}. @item !gotdtprel Used with an @code{ldq} instruction to load the offset of the TLS symbol within its module's thread-local storage block. Also known as the dynamic thread pointer offset or dtp-relative offset. @item !dtprelhi @itemx !dtprello @itemx !dtprel Like @code{gprel} relocations except they compute dtp-relative offsets. @item !gottprel Used with an @code{ldq} instruction to load the offset of the TLS symbol from the thread pointer. Also known as the tp-relative offset. @item !tprelhi @itemx !tprello @itemx !tprel Like @code{gprel} relocations except they compute tp-relative offsets. @end table @node Alpha Floating Point @section Floating Point @cindex floating point, Alpha (@sc{ieee}) @cindex Alpha floating point (@sc{ieee}) The Alpha family uses both @sc{ieee} and VAX floating-point numbers. @node Alpha Directives @section Alpha Assembler Directives @command{@value{AS}} for the Alpha supports many additional directives for compatibility with the native assembler. This section describes them only briefly. @cindex Alpha-only directives These are the additional directives in @code{@value{AS}} for the Alpha: @table @code @item .arch @var{cpu} Specifies the target processor. This is equivalent to the @option{-m@var{cpu}} command-line option. @xref{Alpha Options, Options}, for a list of values for @var{cpu}. @item .ent @var{function}[, @var{n}] Mark the beginning of @var{function}. An optional number may follow for compatibility with the OSF/1 assembler, but is ignored. When generating @code{.mdebug} information, this will create a procedure descriptor for the function. In ELF, it will mark the symbol as a function a-la the generic @code{.type} directive. @item .end @var{function} Mark the end of @var{function}. In ELF, it will set the size of the symbol a-la the generic @code{.size} directive. @item .mask @var{mask}, @var{offset} Indicate which of the integer registers are saved in the current function's stack frame. @var{mask} is interpreted a bit mask in which bit @var{n} set indicates that register @var{n} is saved. The registers are saved in a block located @var{offset} bytes from the @dfn{canonical frame address} (CFA) which is the value of the stack pointer on entry to the function. The registers are saved sequentially, except that the return address register (normally @code{$26}) is saved first. This and the other directives that describe the stack frame are currently only used when generating @code{.mdebug} information. They may in the future be used to generate DWARF2 @code{.debug_frame} unwind information for hand written assembly. @item .fmask @var{mask}, @var{offset} Indicate which of the floating-point registers are saved in the current stack frame. The @var{mask} and @var{offset} parameters are interpreted as with @code{.mask}. @item .frame @var{framereg}, @var{frameoffset}, @var{retreg}[, @var{argoffset}] Describes the shape of the stack frame. The frame pointer in use is @var{framereg}; normally this is either @code{$fp} or @code{$sp}. The frame pointer is @var{frameoffset} bytes below the CFA. The return address is initially located in @var{retreg} until it is saved as indicated in @code{.mask}. For compatibility with OSF/1 an optional @var{argoffset} parameter is accepted and ignored. It is believed to indicate the offset from the CFA to the saved argument registers. @item .prologue @var{n} Indicate that the stack frame is set up and all registers have been spilled. The argument @var{n} indicates whether and how the function uses the incoming @dfn{procedure vector} (the address of the called function) in @code{$27}. 0 indicates that @code{$27} is not used; 1 indicates that the first two instructions of the function use @code{$27} to perform a load of the GP register; 2 indicates that @code{$27} is used in some non-standard way and so the linker cannot elide the load of the procedure vector during relaxation. @item .gprel32 @var{expression} Computes the difference between the address in @var{expression} and the GP for the current object file, and stores it in 4 bytes. In addition to being smaller than a full 8 byte address, this also does not require a dynamic relocation when used in a shared library. @item .t_floating @var{expression} Stores @var{expression} as an @sc{ieee} double precision value. @item .s_floating @var{expression} Stores @var{expression} as an @sc{ieee} single precision value. @item .f_floating @var{expression} Stores @var{expression} as a VAX F format value. @item .g_floating @var{expression} Stores @var{expression} as a VAX G format value. @item .d_floating @var{expression} Stores @var{expression} as a VAX D format value. @item .set @var{feature} Enables or disables various assembler features. Using the positive name of the feature enables while using @samp{no@var{feature}} disables. @table @code @item at Indicates that macro expansions may clobber the @dfn{assembler temporary} (@code{$at} or @code{$28}) register. Some macros may not be expanded without this and will generate an error message if @code{noat} is in effect. When @code{at} is in effect, a warning will be generated if @code{$at} is used by the programmer. @item macro Enables the expansion of macro instructions. Note that variants of real instructions, such as @code{br label} vs @code{br $31,label} are considered alternate forms and not macros. @item move @itemx reorder @itemx volatile These control whether and how the assembler may re-order instructions. Accepted for compatibility with the OSF/1 assembler, but @command{@value{AS}} does not do instruction scheduling, so these features are ignored. @end table @end table The following directives are recognized for compatibility with the OSF/1 assembler but are ignored. @example .proc .aproc .reguse .livereg .option .aent .ugen .eflag .alias .noalias @end example @node Alpha Opcodes @section Opcodes For detailed information on the Alpha machine instruction set, see the @c Attempt to work around a very overfull hbox. @iftex Alpha Architecture Handbook located at @smallfonts @example ftp://ftp.digital.com/pub/Digital/info/semiconductor/literature/alphaahb.pdf @end example @textfonts @end iftex @ifnottex @uref{ftp://ftp.digital.com/pub/Digital/info/semiconductor/literature/alphaahb.pdf,Alpha Architecture Handbook}. @end ifnottex