// Derived from Inferno utils/6l/l.h and related files. // https://bitbucket.org/inferno-os/inferno-os/src/master/utils/6l/l.h // // Copyright © 1994-1999 Lucent Technologies Inc. All rights reserved. // Portions Copyright © 1995-1997 C H Forsyth (forsyth@terzarima.net) // Portions Copyright © 1997-1999 Vita Nuova Limited // Portions Copyright © 2000-2007 Vita Nuova Holdings Limited (www.vitanuova.com) // Portions Copyright © 2004,2006 Bruce Ellis // Portions Copyright © 2005-2007 C H Forsyth (forsyth@terzarima.net) // Revisions Copyright © 2000-2007 Lucent Technologies Inc. and others // Portions Copyright © 2009 The Go Authors. All rights reserved. // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN // THE SOFTWARE. package objabi type RelocType int16 //go:generate stringer -type=RelocType 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. // 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 // Similar to R_USEIFACEMETHOD, except instead of indicating a type + // method offset with Sym+Add, Sym points to a symbol containing the name // of the method being called. See the description in // cmd/compile/internal/reflectdata/reflect.go:MarkUsedIfaceMethod for details. R_USEGENERICIFACEMETHOD // 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 // Platform dependent relocations. Architectures with fixed width instructions // have the inherent issue that a 32-bit (or 64-bit!) displacement cannot be // stuffed into a 32-bit instruction, so an address needs to be spread across // several instructions, and in turn this requires a sequence of relocations, each // updating a part of an instruction. This leads to relocation codes that are // inherently processor specific. // Arm64. // 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_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 // PPC64. // 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_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_PCREL relocates a D-form, DS-form instruction sequence like // R_ADDRPOWER_DS but inserts the offset of the GOT slot for the referenced symbol // from the TOC rather than the symbol's address. R_ADDRPOWER_GOT // 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 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 // RISC-V. // R_RISCV_CALL relocates a J-type instruction with a 21 bit PC-relative // address. R_RISCV_CALL // R_RISCV_CALL_TRAMP is the same as R_RISCV_CALL 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_CALL_TRAMP // R_RISCV_PCREL_ITYPE resolves a 32-bit PC-relative address using an // AUIPC + I-type instruction pair. R_RISCV_PCREL_ITYPE // R_RISCV_PCREL_STYPE resolves a 32-bit PC-relative address using an // AUIPC + S-type instruction pair. R_RISCV_PCREL_STYPE // R_RISCV_TLS_IE_ITYPE resolves a 32-bit TLS initial-exec TOC offset // address using an AUIPC + I-type instruction pair. R_RISCV_TLS_IE_ITYPE // R_RISCV_TLS_IE_STYPE resolves a 32-bit TLS initial-exec TOC offset // address using an AUIPC + S-type instruction pair. R_RISCV_TLS_IE_STYPE // R_PCRELDBL relocates s390x 2-byte aligned PC-relative addresses. // TODO(mundaym): remove once variants can be serialized - see issue 14218. R_PCRELDBL // 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_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 ) // 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, possibly // with limited width. An indirect call is a CALL instruction that takes // the target address in register or memory. func (r RelocType) IsDirectCall() bool { switch r { case R_CALL, R_CALLARM, R_CALLARM64, R_CALLMIPS, R_CALLPOWER, R_RISCV_CALL, R_RISCV_CALL_TRAMP: return true } return false } // 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 (r RelocType) IsDirectJump() bool { switch r { case R_JMPMIPS: return true } return false } // IsDirectCallOrJump reports whether r is a relocation for a direct // call or a direct jump. func (r RelocType) IsDirectCallOrJump() bool { return r.IsDirectCall() || r.IsDirectJump() }