Auto.name
const ( A_AUTO = 1 + iota A_PARAM A_DELETED_AUTO )
const ( ElfRelocOffset = 256 MachoRelocOffset = 2048 // reserve enough space for ELF relocations GlobalDictPrefix = ".dict" // prefix for names of global dictionaries )
func AbsFile(dir, file, rewrites string) string
AbsFile returns the absolute filename for file in the given directory, as rewritten by the rewrites argument. For unrewritten paths, AbsFile rewrites a leading $GOROOT prefix to the literal "$GOROOT". If the resulting path is the empty string, the result is "??".
The rewrites argument is a ;-separated list of rewrites. Each rewrite is of the form "prefix" or "prefix=>replace", where prefix must match a leading sequence of path elements and is either removed entirely or replaced by the replacement.
func AddVersionFlag()
func ApplyRewrites(file, rewrites string) (string, bool)
ApplyRewrites returns the filename for file in the given directory, as rewritten by the rewrites argument.
The rewrites argument is a ;-separated list of rewrites. Each rewrite is of the form "prefix" or "prefix=>replace", where prefix must match a leading sequence of path elements and is either removed entirely or replaced by the replacement.
func DecodeArg(arg string) string
DecodeArg decodes an argument.
This function is public for testing with the parallel encoder.
func Flagcount(name, usage string, val *int)
func Flagfn1(name, usage string, f func(string))
func Flagparse(usage func())
func Flagprint(w io.Writer)
func GetFuncID(name string, isWrapper bool) abi.FuncID
Get the function ID for the named function in the named file. The function should be package-qualified.
func HeaderString() string
HeaderString returns the toolchain configuration string written in Go object headers. This string ensures we don't attempt to import or link object files that are incompatible with each other. This string always starts with "go object ".
func PathToPrefix(s string) string
PathToPrefix converts raw string to the prefix that will be used in the symbol table. All control characters, space, '%' and '"', as well as non-7-bit clean bytes turn into %xx. The period needs escaping only in the last segment of the path, and it makes for happier users if we escape that as little as possible.
func PrefixToPath(s string) (string, error)
PrefixToPath is the inverse of PathToPrefix, replacing escape sequences with the original character.
func StackNosplit(race bool) int
func WorkingDir() string
WorkingDir returns the current working directory (or "/???" if the directory cannot be identified), with "/" as separator.
type DebugFlag struct {
// contains filtered or unexported fields
}
func NewDebugFlag(debug interface{}, debugSSA DebugSSA) *DebugFlag
NewDebugFlag constructs a DebugFlag for the fields of debug, which must be a pointer to a struct.
Each field of *debug is a different value, named for the lower-case of the field name. Each field must be an int or string and must have a `help` struct tag. There may be an "Any bool" field, which will be set if any debug flags are set.
The returned flag takes a comma-separated list of settings. Each setting is name=value; for ints, name is short for name=1.
If debugSSA is non-nil, any debug flags of the form ssa/... will be passed to debugSSA for processing.
func (f *DebugFlag) Set(debugstr string) error
func (f *DebugFlag) String() string
A DebugSSA function is called to set a -d ssa/... option. If nil, those options are reported as invalid options. If DebugSSA returns a non-empty string, that text is reported as a compiler error. If phase is "help", it should print usage information and terminate the process.
type DebugSSA func(phase, flag string, val int, valString string) string
HeadType is the executable header type.
type HeadType uint8
const ( Hunknown HeadType = iota Hdarwin Hdragonfly Hfreebsd Hjs Hlinux Hnetbsd Hopenbsd Hplan9 Hsolaris Hwasip1 Hwindows Haix )
func (h *HeadType) Set(s string) error
func (h HeadType) String() string
PkgSpecial indicates special build properties of a given runtime-related package.
type PkgSpecial struct { // Runtime indicates that this package is "runtime" or imported by // "runtime". This has several effects (which maybe should be split out): // // - Implicit allocation is disallowed. // // - Various runtime pragmas are enabled. // // - Optimizations are always enabled. // // - Checkptr is always disabled. // // This should be set for runtime and all packages it imports, and may be // set for additional packages. Runtime bool // NoInstrument indicates this package should not receive sanitizer // instrumentation. In many of these, instrumentation could cause infinite // recursion. This is all runtime packages, plus those that support the // sanitizers. NoInstrument bool // NoRaceFunc indicates functions in this package should not get // racefuncenter/racefuncexit instrumentation Memory accesses in these // packages are either uninteresting or will cause false positives. NoRaceFunc bool // AllowAsmABI indicates that assembly in this package is allowed to use ABI // selectors in symbol names. Generally this is needed for packages that // interact closely with the runtime package or have performance-critical // assembly. AllowAsmABI bool }
func LookupPkgSpecial(pkgPath string) PkgSpecial
LookupPkgSpecial returns special build properties for the given package path.
type RelocType int16
const ( R_ADDR RelocType = 1 + iota // R_ADDRPOWER relocates a pair of "D-form" instructions (instructions with 16-bit // immediates in the low half of the instruction word), usually addis followed by // another add or a load, inserting the "high adjusted" 16 bits of the address of // the referenced symbol into the immediate field of the first instruction and the // low 16 bits into that of the second instruction. R_ADDRPOWER // R_ADDRARM64 relocates an adrp, add pair to compute the address of the // referenced symbol. R_ADDRARM64 // R_ADDRMIPS (only used on mips/mips64) resolves to the low 16 bits of an external // address, by encoding it into the instruction. R_ADDRMIPS // R_ADDROFF resolves to a 32-bit offset from the beginning of the section // holding the data being relocated to the referenced symbol. R_ADDROFF R_SIZE R_CALL R_CALLARM R_CALLARM64 R_CALLIND R_CALLPOWER // R_CALLMIPS (only used on mips64) resolves to non-PC-relative target address // of a CALL (JAL) instruction, by encoding the address into the instruction. R_CALLMIPS R_CONST R_PCREL // R_TLS_LE, used on 386, amd64, and ARM, resolves to the offset of the // thread-local symbol from the thread local base and is used to implement the // "local exec" model for tls access (r.Sym is not set on intel platforms but is // set to a TLS symbol -- runtime.tlsg -- in the linker when externally linking). R_TLS_LE // R_TLS_IE, used 386, amd64, and ARM resolves to the PC-relative offset to a GOT // slot containing the offset from the thread-local symbol from the thread local // base and is used to implemented the "initial exec" model for tls access (r.Sym // is not set on intel platforms but is set to a TLS symbol -- runtime.tlsg -- in // the linker when externally linking). R_TLS_IE R_GOTOFF R_PLT0 R_PLT1 R_PLT2 R_USEFIELD // R_USETYPE resolves to an *rtype, but no relocation is created. The // linker uses this as a signal that the pointed-to type information // should be linked into the final binary, even if there are no other // direct references. (This is used for types reachable by reflection.) R_USETYPE // R_USEIFACE marks a type is converted to an interface in the function this // relocation is applied to. The target is a type descriptor or an itab // (in the latter case it refers to the concrete type contained in the itab). // This is a marker relocation (0-sized), for the linker's reachabililty // analysis. R_USEIFACE // R_USEIFACEMETHOD marks an interface method that is used in the function // this relocation is applied to. The target is an interface type descriptor. // The addend is the offset of the method in the type descriptor. // This is a marker relocation (0-sized), for the linker's reachabililty // analysis. R_USEIFACEMETHOD // R_USENAMEDMETHOD marks that methods with a specific name must not be eliminated. // The target is a symbol containing the name of a method called via a generic // interface or looked up via MethodByName("F"). R_USENAMEDMETHOD // R_METHODOFF resolves to a 32-bit offset from the beginning of the section // holding the data being relocated to the referenced symbol. // It is a variant of R_ADDROFF used when linking from the uncommonType of a // *rtype, and may be set to zero by the linker if it determines the method // text is unreachable by the linked program. R_METHODOFF // R_KEEP tells the linker to keep the referred-to symbol in the final binary // if the symbol containing the R_KEEP relocation is in the final binary. R_KEEP R_POWER_TOC R_GOTPCREL // R_JMPMIPS (only used on mips64) resolves to non-PC-relative target address // of a JMP instruction, by encoding the address into the instruction. // The stack nosplit check ignores this since it is not a function call. R_JMPMIPS // R_DWARFSECREF resolves to the offset of the symbol from its section. // Target of relocation must be size 4 (in current implementation). R_DWARFSECREF // R_DWARFFILEREF resolves to an index into the DWARF .debug_line // file table for the specified file symbol. Must be applied to an // attribute of form DW_FORM_data4. R_DWARFFILEREF // Set a MOV[NZ] immediate field to bits [15:0] of the offset from the thread // local base to the thread local variable defined by the referenced (thread // local) symbol. Error if the offset does not fit into 16 bits. R_ARM64_TLS_LE // Relocates an ADRP; LD64 instruction sequence to load the offset between // the thread local base and the thread local variable defined by the // referenced (thread local) symbol from the GOT. R_ARM64_TLS_IE // R_ARM64_GOTPCREL relocates an adrp, ld64 pair to compute the address of the GOT // slot of the referenced symbol. R_ARM64_GOTPCREL // R_ARM64_GOT resolves a GOT-relative instruction sequence, usually an adrp // followed by another ld instruction. R_ARM64_GOT // R_ARM64_PCREL resolves a PC-relative addresses instruction sequence, usually an // adrp followed by another add instruction. R_ARM64_PCREL // R_ARM64_PCREL_LDST8 resolves a PC-relative addresses instruction sequence, usually an // adrp followed by a LD8 or ST8 instruction. R_ARM64_PCREL_LDST8 // R_ARM64_PCREL_LDST16 resolves a PC-relative addresses instruction sequence, usually an // adrp followed by a LD16 or ST16 instruction. R_ARM64_PCREL_LDST16 // R_ARM64_PCREL_LDST32 resolves a PC-relative addresses instruction sequence, usually an // adrp followed by a LD32 or ST32 instruction. R_ARM64_PCREL_LDST32 // R_ARM64_PCREL_LDST64 resolves a PC-relative addresses instruction sequence, usually an // adrp followed by a LD64 or ST64 instruction. R_ARM64_PCREL_LDST64 // R_ARM64_LDST8 sets a LD/ST immediate value to bits [11:0] of a local address. R_ARM64_LDST8 // R_ARM64_LDST16 sets a LD/ST immediate value to bits [11:1] of a local address. R_ARM64_LDST16 // R_ARM64_LDST32 sets a LD/ST immediate value to bits [11:2] of a local address. R_ARM64_LDST32 // R_ARM64_LDST64 sets a LD/ST immediate value to bits [11:3] of a local address. R_ARM64_LDST64 // R_ARM64_LDST128 sets a LD/ST immediate value to bits [11:4] of a local address. R_ARM64_LDST128 // R_POWER_TLS_LE is used to implement the "local exec" model for tls // access. It resolves to the offset of the thread-local symbol from the // thread pointer (R13) and is split against a pair of instructions to // support a 32 bit displacement. R_POWER_TLS_LE // R_POWER_TLS_IE is used to implement the "initial exec" model for tls access. It // relocates a D-form, DS-form instruction sequence like R_ADDRPOWER_DS. It // inserts to the offset of GOT slot for the thread-local symbol from the TOC (the // GOT slot is filled by the dynamic linker with the offset of the thread-local // symbol from the thread pointer (R13)). R_POWER_TLS_IE // R_POWER_TLS marks an X-form instruction such as "ADD R3,R13,R4" as completing // a sequence of GOT-relative relocations to compute a TLS address. This can be // used by the system linker to to rewrite the GOT-relative TLS relocation into a // simpler thread-pointer relative relocation. See table 3.26 and 3.28 in the // ppc64 elfv2 1.4 ABI on this transformation. Likewise, the second argument // (usually called RB in X-form instructions) is assumed to be R13. R_POWER_TLS // R_POWER_TLS_IE_PCREL34 is similar to R_POWER_TLS_IE, but marks a single MOVD // which has been assembled as a single prefixed load doubleword without using the // TOC. R_POWER_TLS_IE_PCREL34 // R_POWER_TLS_LE_TPREL34 is similar to R_POWER_TLS_LE, but computes an offset from // the thread pointer in one prefixed instruction. R_POWER_TLS_LE_TPREL34 // R_ADDRPOWER_DS is similar to R_ADDRPOWER above, but assumes the second // instruction is a "DS-form" instruction, which has an immediate field occupying // bits [15:2] of the instruction word. Bits [15:2] of the address of the // relocated symbol are inserted into this field; it is an error if the last two // bits of the address are not 0. R_ADDRPOWER_DS // R_ADDRPOWER_GOT relocates a D-form + DS-form instruction sequence by inserting // a relative displacement of referenced symbol's GOT entry to the TOC pointer. R_ADDRPOWER_GOT // R_ADDRPOWER_GOT_PCREL34 is identical to R_ADDRPOWER_GOT, but uses a PC relative // sequence to generate a GOT symbol addresses. R_ADDRPOWER_GOT_PCREL34 // R_ADDRPOWER_PCREL relocates two D-form instructions like R_ADDRPOWER, but // inserts the displacement from the place being relocated to the address of the // relocated symbol instead of just its address. R_ADDRPOWER_PCREL // R_ADDRPOWER_TOCREL relocates two D-form instructions like R_ADDRPOWER, but // inserts the offset from the TOC to the address of the relocated symbol // rather than the symbol's address. R_ADDRPOWER_TOCREL // R_ADDRPOWER_TOCREL_DS relocates a D-form, DS-form instruction sequence like // R_ADDRPOWER_DS but inserts the offset from the TOC to the address of the // relocated symbol rather than the symbol's address. R_ADDRPOWER_TOCREL_DS // R_ADDRPOWER_D34 relocates a single prefixed D-form load/store operation. All // prefixed forms are D form. The high 18 bits are stored in the prefix, // and the low 16 are stored in the suffix. The address is absolute. R_ADDRPOWER_D34 // R_ADDRPOWER_PCREL34 relates a single prefixed D-form load/store/add operation. // All prefixed forms are D form. The resulting address is relative to the // PC. It is a signed 34 bit offset. R_ADDRPOWER_PCREL34 // R_RISCV_JAL resolves a 20 bit offset for a J-type instruction. R_RISCV_JAL // R_RISCV_JAL_TRAMP is the same as R_RISCV_JAL but denotes the use of a // trampoline, which we may be able to avoid during relocation. These are // only used by the linker and are not emitted by the compiler or assembler. R_RISCV_JAL_TRAMP // R_RISCV_CALL resolves a 32 bit PC-relative address for an AUIPC + JALR // instruction pair. R_RISCV_CALL // R_RISCV_PCREL_ITYPE resolves a 32 bit PC-relative address for an // AUIPC + I-type instruction pair. R_RISCV_PCREL_ITYPE // R_RISCV_PCREL_STYPE resolves a 32 bit PC-relative address for an // AUIPC + S-type instruction pair. R_RISCV_PCREL_STYPE // R_RISCV_TLS_IE resolves a 32 bit TLS initial-exec address for an // AUIPC + I-type instruction pair. R_RISCV_TLS_IE // R_RISCV_TLS_LE resolves a 32 bit TLS local-exec address for a // LUI + I-type instruction sequence. R_RISCV_TLS_LE // R_RISCV_GOT_HI20 resolves the high 20 bits of a 32-bit PC-relative GOT // address. R_RISCV_GOT_HI20 // R_RISCV_PCREL_HI20 resolves the high 20 bits of a 32-bit PC-relative // address. R_RISCV_PCREL_HI20 // R_RISCV_PCREL_LO12_I resolves the low 12 bits of a 32-bit PC-relative // address using an I-type instruction. R_RISCV_PCREL_LO12_I // R_RISCV_PCREL_LO12_S resolves the low 12 bits of a 32-bit PC-relative // address using an S-type instruction. R_RISCV_PCREL_LO12_S // R_RISCV_BRANCH resolves a 12-bit PC-relative branch offset. R_RISCV_BRANCH // R_RISCV_RVC_BRANCH resolves an 8-bit PC-relative offset for a CB-type // instruction. R_RISCV_RVC_BRANCH // R_RISCV_RVC_JUMP resolves an 11-bit PC-relative offset for a CJ-type // instruction. R_RISCV_RVC_JUMP // R_PCRELDBL relocates s390x 2-byte aligned PC-relative addresses. // TODO(mundaym): remove once variants can be serialized - see issue 14218. R_PCRELDBL // R_LOONG64_ADDR_HI resolves to the sign-adjusted "upper" 20 bits (bit 5-24) of an // external address, by encoding it into the instruction. // R_LOONG64_ADDR_LO resolves to the low 12 bits of an external address, by encoding // it into the instruction. R_LOONG64_ADDR_HI R_LOONG64_ADDR_LO // R_LOONG64_TLS_LE_HI resolves to the high 20 bits of a TLS address (offset from // thread pointer), by encoding it into the instruction. // R_LOONG64_TLS_LE_LO resolves to the low 12 bits of a TLS address (offset from // thread pointer), by encoding it into the instruction. R_LOONG64_TLS_LE_HI R_LOONG64_TLS_LE_LO // R_CALLLOONG64 resolves to non-PC-relative target address of a CALL (BL/JIRL) // instruction, by encoding the address into the instruction. R_CALLLOONG64 // R_LOONG64_TLS_IE_HI and R_LOONG64_TLS_IE_LO relocates a pcalau12i, ld.d // pair to compute the address of the GOT slot of the tls symbol. R_LOONG64_TLS_IE_HI R_LOONG64_TLS_IE_LO // R_LOONG64_GOT_HI and R_LOONG64_GOT_LO resolves a GOT-relative instruction sequence, // usually an pcalau12i followed by another ld or addi instruction. R_LOONG64_GOT_HI R_LOONG64_GOT_LO // R_JMPLOONG64 resolves to non-PC-relative target address of a JMP instruction, // by encoding the address into the instruction. R_JMPLOONG64 // R_ADDRMIPSU (only used on mips/mips64) resolves to the sign-adjusted "upper" 16 // bits (bit 16-31) of an external address, by encoding it into the instruction. R_ADDRMIPSU // R_ADDRMIPSTLS (only used on mips64) resolves to the low 16 bits of a TLS // address (offset from thread pointer), by encoding it into the instruction. R_ADDRMIPSTLS // R_ADDRCUOFF resolves to a pointer-sized offset from the start of the // symbol's DWARF compile unit. R_ADDRCUOFF // R_WASMIMPORT resolves to the index of the WebAssembly function import. R_WASMIMPORT // R_XCOFFREF (only used on aix/ppc64) prevents garbage collection by ld // of a symbol. This isn't a real relocation, it can be placed in anywhere // in a symbol and target any symbols. R_XCOFFREF // R_PEIMAGEOFF resolves to a 32-bit offset from the start address of where // the executable file is mapped in memory. R_PEIMAGEOFF // R_INITORDER specifies an ordering edge between two inittask records. // (From one p..inittask record to another one.) // This relocation does not apply any changes to the actual data, it is // just used in the linker to order the inittask records appropriately. R_INITORDER // R_WEAK marks the relocation as a weak reference. // A weak relocation does not make the symbol it refers to reachable, // and is only honored by the linker if the symbol is in some other way // reachable. R_WEAK = -1 << 15 R_WEAKADDR = R_WEAK | R_ADDR R_WEAKADDROFF = R_WEAK | R_ADDROFF )
func (r RelocType) IsDirectCall() bool
IsDirectCall reports whether r is a relocation for a direct call. A direct call is a CALL instruction that takes the target address as an immediate. The address is embedded into the instruction(s), possibly with limited width. An indirect call is a CALL instruction that takes the target address in register or memory.
func (r RelocType) IsDirectCallOrJump() bool
IsDirectCallOrJump reports whether r is a relocation for a direct call or a direct jump.
func (r RelocType) IsDirectJump() bool
IsDirectJump reports whether r is a relocation for a direct jump. A direct jump is a JMP instruction that takes the target address as an immediate. The address is embedded into the instruction, possibly with limited width. An indirect jump is a JMP instruction that takes the target address in register or memory.
func (i RelocType) String() string
A SymKind describes the kind of memory represented by a symbol.
type SymKind uint8
Defined SymKind values. These are used to index into cmd/link/internal/sym/AbiSymKindToSymKind
TODO(rsc): Give idiomatic Go names.
const ( // An otherwise invalid zero value for the type Sxxx SymKind = iota // Executable instructions STEXT // Read only static data SRODATA // Static data that does not contain any pointers SNOPTRDATA // Static data SDATA // Statically data that is initially all 0s SBSS // Statically data that is initially all 0s and does not contain pointers SNOPTRBSS // Thread-local data that is initially all 0s STLSBSS // Debugging data SDWARFCUINFO SDWARFCONST SDWARFFCN SDWARFABSFCN SDWARFTYPE SDWARFVAR SDWARFRANGE SDWARFLOC SDWARFLINES // Coverage instrumentation counter for libfuzzer. SLIBFUZZER_8BIT_COUNTER // Coverage instrumentation counter, aux variable for cmd/cover SCOVERAGE_COUNTER SCOVERAGE_AUXVAR SSEHUNWINDINFO )
func (i SymKind) String() string