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195 lines
10 KiB
C
195 lines
10 KiB
C
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/* insndec.h - readable per-instruction operand decode (generic, ABI-agnostic).
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*
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* Handler layer: a RICH decode of ONE x86-64 instruction into concrete operands
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* (concrete registers as a backend-neutral stable id, memory base/index/scale/
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* disp, immediate VALUES, sizes), per-operand read/write, AND the full aggregate
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* register read/write sets INCLUDING IMPLICIT operands/effects (rsp on push/pop,
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* rdx:rax on mul/div, FLAGS on cmp/jcc, ...). This is the "perception" primitive
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* the register def-use analysis (codetrace.h) is built on.
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*
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* Relationship to semsig.h (shared backend, DIFFERENT purpose). semsig_hash
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* folds a NORMALIZED, LOSSY token stream: it erases register identity (keeps only
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* a class), erases immediate/displacement values, and carries no read/write - by
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* design, so the hash is register-/value-/reorder-stable. That makes semsig
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* irreversible: you cannot trace registers through it. insn_decode is the
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* opposite: it KEEPS register identity, values, and read/write, so an analysis
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* can reason about WHICH physical register an instruction touches. Both ride the
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* SAME optional external disassembler (Zydis/Capstone) behind the same private
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* seam, but insn_decode is NOT a hash and NOT lossy.
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*
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* Operand decode is NOT in the light decoder (x86dec.h is deliberately pure and
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* length-only) and NOT a second hand-rolled operand decoder: it is supplied by
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* the optional backend, so this primitive is FEATURE-GATED exactly like semsig.
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* With no backend the symbol still exists (ABI stable) but returns 0, and
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* VMIE_HAVE_DISASM is 0.
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*
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* ABI-AGNOSTIC. insn_decode reports ONLY what an instruction does
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* ARCHITECTURALLY. In particular a `call` writes rsp and rip and (for an
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* indirect call) reads its target register/memory - that is ALL. It does NOT
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* mark caller-saved (volatile) registers as written: that is a property of the
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* CALLED function / the calling convention, not of the instruction. The Win64
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* volatile clobber lives in the def-use layer (codetrace.h/.c) behind an explicit
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* trace_abi, never here.
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*/
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#ifndef VMIE_INSNDEC_H
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#define VMIE_INSNDEC_H
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#include <stdint.h>
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#include <stddef.h>
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/* Compile-time feature availability, shared with semsig (one backend, one gate).
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* Pushed from CMake as a PUBLIC compile definition so consumers see the SAME
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* value the library was built with:
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* VMIE_HAVE_DISASM == 1 built with a disassembler backend; insn_decode is
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* live, insndec_backend_name() names the backend.
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* VMIE_HAVE_DISASM == 0 built without a backend (the default); insn_decode
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* always returns 0 and insndec_backend_name() == "none".
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* The default here keeps the header valid when compiled outside the project. */
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#ifndef VMIE_HAVE_DISASM
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#define VMIE_HAVE_DISASM 0
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#endif
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/* Canonical full-register root id. al/ah/ax/eax/rax all map to REGID_RAX;
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* xmm0/ymm0/zmm0 -> REGID_VEC0; etc. Identity is KEPT here (unlike sem_insn,
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* which erases it) so def-use can reason about WHICH physical register. The
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* concrete backend register enum is NEVER carried across the seam - the backend
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* TU normalizes into THIS stable id, exactly as it does for mnemonic classes. */
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typedef enum {
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REGID_NONE = 0,
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/* 16 GPR roots; al/ax/eax/rax -> REGID_RAX, etc. */
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REGID_RAX, REGID_RCX, REGID_RDX, REGID_RBX,
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REGID_RSP, REGID_RBP, REGID_RSI, REGID_RDI,
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REGID_R8, REGID_R9, REGID_R10, REGID_R11,
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REGID_R12, REGID_R13, REGID_R14, REGID_R15,
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/* 32 vector roots (zmm0..zmm31; xmm/ymm fold into the zmm root). */
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REGID_VEC0,
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REGID_VEC31 = REGID_VEC0 + 31,
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/* AVX-512 mask k0..k7. */
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REGID_K0,
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REGID_K7 = REGID_K0 + 7,
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/* FLAGS as ONE pseudo-register root (NOT per-bit CF/ZF/...): enough for
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* def-use "cmp writes flags, jcc/cmov/setcc read flags"; per-bit is not v1. */
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REGID_FLAGS,
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/* rip / segment / other roots kept coarse (def-use rarely tracks them). */
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REGID_OTHER,
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REGID_COUNT
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} reg_id;
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/* Per-operand / per-register access, normalized (raw backend enums never leak). */
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typedef enum {
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ACC_NONE = 0,
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ACC_READ, /* read only */
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ACC_WRITE, /* write only */
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ACC_READWRITE, /* read-modify-write (add, sub, ...) */
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ACC_COND_READ, /* conditionally read (cmovcc src, ...) */
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ACC_COND_WRITE /* conditionally written (cmovcc dst, setcc) */
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} reg_access;
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/* Explicit-operand kind (the readable, perception side of the decode). */
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typedef enum {
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OPND_NONE = 0,
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OPND_REG, /* register operand */
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OPND_MEM, /* memory operand (base/index/scale/disp) */
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OPND_IMM /* immediate operand (value kept) */
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} operand_kind;
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/* One register reference, used both for explicit register operands and for the
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* aggregate implicit-or-explicit read/write sets. Sub-register overlap is modeled
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* EXPLICITLY and backend-neutrally:
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* root - canonical full-register root (al/ax/eax/rax -> REGID_RAX)
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* width_log2 - ACCESS width in log2 bytes (0=1B .. 4=16B), as
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* width_log2_of already computes for semsig
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* writes_zero_extend- on a WRITE, 1 if the upper part of the root is zeroed
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* (a 32-bit GPR write, e.g. `eax`, zeroes the upper 32 bits
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* of `rax`; a VEX/EVEX vector write zeroes the upper YMM/ZMM)
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* and 0 if it is a PARTIAL write that preserves the upper
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* part (8/16-bit GPR write, legacy-SSE vector write). This
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* ONE flag is what def-use needs to decide overlap without
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* carrying a raw bit mask.
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* access - ACC_* for this reference */
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typedef struct {
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uint8_t root; /* reg_id */
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uint8_t width_log2; /* access width, log2 bytes (0..4+) */
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uint8_t writes_zero_extend;
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uint8_t access; /* reg_access */
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} reg_ref;
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/* One explicit operand (readable / perception view). */
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typedef struct {
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uint8_t kind; /* operand_kind */
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uint8_t access; /* reg_access for the operand as a whole */
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uint8_t width_log2; /* access width, log2 bytes */
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uint8_t mem_scale; /* MEM: index scale (1/2/4/8), 0 if no index */
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uint8_t mem_is_riprel; /* MEM: 1 if RIP-relative */
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uint8_t reg_root; /* REG: reg_id of the operand register */
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uint8_t reg_zero_extend; /* REG: writes_zero_extend for a write operand */
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uint8_t imm_width_log2; /* IMM: value width, log2 bytes */
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uint8_t mem_base; /* MEM: reg_id of the base register (read) */
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uint8_t mem_index; /* MEM: reg_id of the index register (read) */
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int64_t mem_disp; /* MEM: displacement value (signed) */
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int64_t imm_value; /* IMM: immediate value (sign-extended) */
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} operand;
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/* Mnemonic-class group, backend-neutral. Mirrors the semsig SEM_MN_* groups so a
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* consumer can switch on the instruction kind without backend enums; def-use uses
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* only INSN_CALL (call sites) but the rest aids readability of the decode. */
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typedef enum {
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INSN_OTHER = 0,
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INSN_MOV, INSN_ARITH, INSN_LOGIC, INSN_CMP, INSN_TEST,
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INSN_BRANCH, /* conditional jcc / setcc / cmovcc */
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INSN_JMP, /* unconditional jmp */
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INSN_CALL, INSN_RET, INSN_PUSH, INSN_POP, INSN_LEA, INSN_NOP,
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INSN_FLOAT, INSN_VEC
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} insn_class;
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/* Caps on the rich decode. Four explicit operands cover x86-64; eight register
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* refs per side cover the widest implicit sets (e.g. mul touching rax/rdx plus an
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* explicit source) with margin. Anything beyond is truncated (count still grows
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* past the cap so a caller can detect it), which never happens for real code. */
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#define INSN_MAX_OPERANDS 4
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#define INSN_MAX_REGREFS 8
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/* A fully decoded instruction. Two complementary representations:
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* op[] - explicit operands, in instruction operand order (readability);
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* reads[] / writes[] - aggregate register sets over canonical roots, UNIONING
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* explicit AND implicit effects (this is what def-use consumes). A
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* memory operand's base/index registers appear in reads[] as address
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* reads; FLAGS appears as REGID_FLAGS; rsp/rdx:rax appear via the
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* backend's implicit operands. */
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typedef struct {
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uint8_t length; /* full instruction length in bytes (>= 1) */
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uint8_t mnemonic_class; /* insn_class */
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uint8_t is_control_flow; /* 1 if branch/call/ret */
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uint8_t noperands; /* explicit operands in op[] (<= INSN_MAX_OPERANDS)*/
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uint8_t nreads; /* register refs in reads[] */
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uint8_t nwrites; /* register refs in writes[] */
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operand op[INSN_MAX_OPERANDS];
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reg_ref reads[INSN_MAX_REGREFS];
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reg_ref writes[INSN_MAX_REGREFS];
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} insn_decoded;
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/* Decode ONE instruction at view[off .. ]. `view` is a flat byte span and `off`
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* is the byte offset of the instruction within it; at most (view_size - off)
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* bytes are available to the backend. Returns 1 on success (fills *out), 0 on
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* undecodable / not enough bytes / a build with no backend (VMIE_HAVE_DISASM==0).
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* out->length == 0 is also treated as a desync by callers. PURE: only the byte
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* span and the decoder, no I/O, no allocation, reentrant.
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*
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* `view` / `view_size` are a flat buffer (not mem_view_t) so this primitive
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* stays dependency-light; the caller owns the buffer.
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*
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* Example - read the registers an instruction writes:
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* insn_decoded d;
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* if (insn_decode(code, n, 0, &d))
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* for (int i = 0; i < d.nwrites; i++)
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* printf("writes root %u (zx=%u)\n",
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* d.writes[i].root, d.writes[i].writes_zero_extend); */
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int insn_decode(const uint8_t* view, size_t view_size, size_t off,
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insn_decoded* out);
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/* Stable identity of the compiled disassembler backend ("zydis"/"capstone", or
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* "none" without a backend). Shares the backend with semsig; this name is the
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* same backend. Static, never-NULL. */
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const char* insndec_backend_name(void);
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#endif /* VMIE_INSNDEC_H */
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