const std = @import("std");
const builtin = @import("builtin");
const assert = std.debug.assert;
const io = std.io;
const mem = std.mem;
const meta = std.meta;
const testing = std.testing;

const Allocator = mem.Allocator;

pub const cpu_type_t = c_int;
pub const cpu_subtype_t = c_int;
pub const vm_prot_t = c_int;

pub const mach_header = extern struct {
    magic: u32,
    cputype: cpu_type_t,
    cpusubtype: cpu_subtype_t,
    filetype: u32,
    ncmds: u32,
    sizeofcmds: u32,
    flags: u32,
};

pub const mach_header_64 = extern struct {
    magic: u32 = MH_MAGIC_64,
    cputype: cpu_type_t = 0,
    cpusubtype: cpu_subtype_t = 0,
    filetype: u32 = 0,
    ncmds: u32 = 0,
    sizeofcmds: u32 = 0,
    flags: u32 = 0,
    reserved: u32 = 0,
};

pub const fat_header = extern struct {
    magic: u32,
    nfat_arch: u32,
};

pub const fat_arch = extern struct {
    cputype: cpu_type_t,
    cpusubtype: cpu_subtype_t,
    offset: u32,
    size: u32,
    @"align": u32,
};

pub const load_command = extern struct {
    cmd: LC,
    cmdsize: u32,
};

/// The uuid load command contains a single 128-bit unique random number that
/// identifies an object produced by the static link editor.
pub const uuid_command = extern struct {
    /// LC_UUID
    cmd: LC = .UUID,

    /// sizeof(struct uuid_command)
    cmdsize: u32,

    /// the 128-bit uuid
    uuid: [16]u8,
};

/// The version_min_command contains the min OS version on which this
/// binary was built to run.
pub const version_min_command = extern struct {
    /// LC_VERSION_MIN_MACOSX or LC_VERSION_MIN_IPHONEOS or LC_VERSION_MIN_WATCHOS or LC_VERSION_MIN_TVOS
    cmd: LC,

    /// sizeof(struct version_min_command)
    cmdsize: u32,

    /// X.Y.Z is encoded in nibbles xxxx.yy.zz
    version: u32,

    /// X.Y.Z is encoded in nibbles xxxx.yy.zz
    sdk: u32,
};

/// The source_version_command is an optional load command containing
/// the version of the sources used to build the binary.
pub const source_version_command = extern struct {
    /// LC_SOURCE_VERSION
    cmd: LC = .SOURCE_VERSION,

    /// sizeof(source_version_command)
    cmdsize: u32,

    /// A.B.C.D.E packed as a24.b10.c10.d10.e10
    version: u64,
};

/// The build_version_command contains the min OS version on which this
/// binary was built to run for its platform. The list of known platforms and
/// tool values following it.
pub const build_version_command = extern struct {
    /// LC_BUILD_VERSION
    cmd: LC = .BUILD_VERSION,

    /// sizeof(struct build_version_command) plus
    /// ntools * sizeof(struct build_version_command)
    cmdsize: u32,

    /// platform
    platform: PLATFORM,

    /// X.Y.Z is encoded in nibbles xxxx.yy.zz
    minos: u32,

    /// X.Y.Z is encoded in nibbles xxxx.yy.zz
    sdk: u32,

    /// number of tool entries following this
    ntools: u32,
};

pub const build_tool_version = extern struct {
    /// enum for the tool
    tool: TOOL,

    /// version number of the tool
    version: u32,
};

pub const PLATFORM = enum(u32) {
    MACOS = 0x1,
    IOS = 0x2,
    TVOS = 0x3,
    WATCHOS = 0x4,
    BRIDGEOS = 0x5,
    MACCATALYST = 0x6,
    IOSSIMULATOR = 0x7,
    TVOSSIMULATOR = 0x8,
    WATCHOSSIMULATOR = 0x9,
    DRIVERKIT = 0x10,
    _,
};

pub const TOOL = enum(u32) {
    CLANG = 0x1,
    SWIFT = 0x2,
    LD = 0x3,
    _,
};

/// The entry_point_command is a replacement for thread_command.
/// It is used for main executables to specify the location (file offset)
/// of main(). If -stack_size was used at link time, the stacksize
/// field will contain the stack size needed for the main thread.
pub const entry_point_command = extern struct {
    /// LC_MAIN only used in MH_EXECUTE filetypes
    cmd: LC = .MAIN,

    /// sizeof(struct entry_point_command)
    cmdsize: u32,

    /// file (__TEXT) offset of main()
    entryoff: u64,

    /// if not zero, initial stack size
    stacksize: u64,
};

/// The symtab_command contains the offsets and sizes of the link-edit 4.3BSD
/// "stab" style symbol table information as described in the header files
/// <nlist.h> and <stab.h>.
pub const symtab_command = extern struct {
    /// LC_SYMTAB
    cmd: LC = .SYMTAB,

    /// sizeof(struct symtab_command)
    cmdsize: u32,

    /// symbol table offset
    symoff: u32,

    /// number of symbol table entries
    nsyms: u32,

    /// string table offset
    stroff: u32,

    /// string table size in bytes
    strsize: u32,
};

/// This is the second set of the symbolic information which is used to support
/// the data structures for the dynamically link editor.
///
/// The original set of symbolic information in the symtab_command which contains
/// the symbol and string tables must also be present when this load command is
/// present.  When this load command is present the symbol table is organized
/// into three groups of symbols:
///  local symbols (static and debugging symbols) - grouped by module
///  defined external symbols - grouped by module (sorted by name if not lib)
///  undefined external symbols (sorted by name if MH_BINDATLOAD is not set,
///       			    and in order the were seen by the static
///  			    linker if MH_BINDATLOAD is set)
/// In this load command there are offsets and counts to each of the three groups
/// of symbols.
///
/// This load command contains a the offsets and sizes of the following new
/// symbolic information tables:
///  table of contents
///  module table
///  reference symbol table
///  indirect symbol table
/// The first three tables above (the table of contents, module table and
/// reference symbol table) are only present if the file is a dynamically linked
/// shared library.  For executable and object modules, which are files
/// containing only one module, the information that would be in these three
/// tables is determined as follows:
/// 	table of contents - the defined external symbols are sorted by name
///  module table - the file contains only one module so everything in the
///  	       file is part of the module.
///  reference symbol table - is the defined and undefined external symbols
///
/// For dynamically linked shared library files this load command also contains
/// offsets and sizes to the pool of relocation entries for all sections
/// separated into two groups:
///  external relocation entries
///  local relocation entries
/// For executable and object modules the relocation entries continue to hang
/// off the section structures.
pub const dysymtab_command = extern struct {
    /// LC_DYSYMTAB
    cmd: LC = .DYSYMTAB,

    /// sizeof(struct dysymtab_command)
    cmdsize: u32,

    // The symbols indicated by symoff and nsyms of the LC_SYMTAB load command

    // are grouped into the following three groups:

    //    local symbols (further grouped by the module they are from)

    //    defined external symbols (further grouped by the module they are from)

    //    undefined symbols

    //

    // The local symbols are used only for debugging.  The dynamic binding

    // process may have to use them to indicate to the debugger the local

    // symbols for a module that is being bound.

    //

    // The last two groups are used by the dynamic binding process to do the

    // binding (indirectly through the module table and the reference symbol

    // table when this is a dynamically linked shared library file).


    /// index of local symbols
    ilocalsym: u32,

    /// number of local symbols
    nlocalsym: u32,

    /// index to externally defined symbols
    iextdefsym: u32,

    /// number of externally defined symbols
    nextdefsym: u32,

    /// index to undefined symbols
    iundefsym: u32,

    /// number of undefined symbols
    nundefsym: u32,

    // For the for the dynamic binding process to find which module a symbol

    // is defined in the table of contents is used (analogous to the ranlib

    // structure in an archive) which maps defined external symbols to modules

    // they are defined in.  This exists only in a dynamically linked shared

    // library file.  For executable and object modules the defined external

    // symbols are sorted by name and is use as the table of contents.


    /// file offset to table of contents
    tocoff: u32,

    /// number of entries in table of contents
    ntoc: u32,

    // To support dynamic binding of "modules" (whole object files) the symbol

    // table must reflect the modules that the file was created from.  This is

    // done by having a module table that has indexes and counts into the merged

    // tables for each module.  The module structure that these two entries

    // refer to is described below.  This exists only in a dynamically linked

    // shared library file.  For executable and object modules the file only

    // contains one module so everything in the file belongs to the module.


    /// file offset to module table
    modtaboff: u32,

    /// number of module table entries
    nmodtab: u32,

    // To support dynamic module binding the module structure for each module

    // indicates the external references (defined and undefined) each module

    // makes.  For each module there is an offset and a count into the

    // reference symbol table for the symbols that the module references.

    // This exists only in a dynamically linked shared library file.  For

    // executable and object modules the defined external symbols and the

    // undefined external symbols indicates the external references.


    /// offset to referenced symbol table
    extrefsymoff: u32,

    /// number of referenced symbol table entries
    nextrefsyms: u32,

    // The sections that contain "symbol pointers" and "routine stubs" have

    // indexes and (implied counts based on the size of the section and fixed

    // size of the entry) into the "indirect symbol" table for each pointer

    // and stub.  For every section of these two types the index into the

    // indirect symbol table is stored in the section header in the field

    // reserved1.  An indirect symbol table entry is simply a 32bit index into

    // the symbol table to the symbol that the pointer or stub is referring to.

    // The indirect symbol table is ordered to match the entries in the section.


    /// file offset to the indirect symbol table
    indirectsymoff: u32,

    /// number of indirect symbol table entries
    nindirectsyms: u32,

    // To support relocating an individual module in a library file quickly the

    // external relocation entries for each module in the library need to be

    // accessed efficiently.  Since the relocation entries can't be accessed

    // through the section headers for a library file they are separated into

    // groups of local and external entries further grouped by module.  In this

    // case the presents of this load command who's extreloff, nextrel,

    // locreloff and nlocrel fields are non-zero indicates that the relocation

    // entries of non-merged sections are not referenced through the section

    // structures (and the reloff and nreloc fields in the section headers are

    // set to zero).

    //

    // Since the relocation entries are not accessed through the section headers

    // this requires the r_address field to be something other than a section

    // offset to identify the item to be relocated.  In this case r_address is

    // set to the offset from the vmaddr of the first LC_SEGMENT command.

    // For MH_SPLIT_SEGS images r_address is set to the the offset from the

    // vmaddr of the first read-write LC_SEGMENT command.

    //

    // The relocation entries are grouped by module and the module table

    // entries have indexes and counts into them for the group of external

    // relocation entries for that the module.

    //

    // For sections that are merged across modules there must not be any

    // remaining external relocation entries for them (for merged sections

    // remaining relocation entries must be local).


    /// offset to external relocation entries
    extreloff: u32,

    /// number of external relocation entries
    nextrel: u32,

    // All the local relocation entries are grouped together (they are not

    // grouped by their module since they are only used if the object is moved

    // from it staticly link edited address).


    /// offset to local relocation entries
    locreloff: u32,

    /// number of local relocation entries
    nlocrel: u32,
};

/// The linkedit_data_command contains the offsets and sizes of a blob
/// of data in the __LINKEDIT segment.
pub const linkedit_data_command = extern struct {
    /// LC_CODE_SIGNATURE, LC_SEGMENT_SPLIT_INFO, LC_FUNCTION_STARTS, LC_DATA_IN_CODE, LC_DYLIB_CODE_SIGN_DRS or LC_LINKER_OPTIMIZATION_HINT.
    cmd: LC,

    /// sizeof(struct linkedit_data_command)
    cmdsize: u32,

    /// file offset of data in __LINKEDIT segment
    dataoff: u32,

    /// file size of data in __LINKEDIT segment
    datasize: u32,
};

/// The dyld_info_command contains the file offsets and sizes of
/// the new compressed form of the information dyld needs to
/// load the image.  This information is used by dyld on Mac OS X
/// 10.6 and later.  All information pointed to by this command
/// is encoded using byte streams, so no endian swapping is needed
/// to interpret it.
pub const dyld_info_command = extern struct {
    /// LC_DYLD_INFO or LC_DYLD_INFO_ONLY
    cmd: LC,

    /// sizeof(struct dyld_info_command)
    cmdsize: u32,

    // Dyld rebases an image whenever dyld loads it at an address different

    // from its preferred address.  The rebase information is a stream

    // of byte sized opcodes whose symbolic names start with REBASE_OPCODE_.

    // Conceptually the rebase information is a table of tuples:

    //    <seg-index, seg-offset, type>

    // The opcodes are a compressed way to encode the table by only

    // encoding when a column changes.  In addition simple patterns

    // like "every n'th offset for m times" can be encoded in a few

    // bytes.


    /// file offset to rebase info
    rebase_off: u32,

    /// size of rebase info
    rebase_size: u32,

    // Dyld binds an image during the loading process, if the image

    // requires any pointers to be initialized to symbols in other images.

    // The bind information is a stream of byte sized

    // opcodes whose symbolic names start with BIND_OPCODE_.

    // Conceptually the bind information is a table of tuples:

    //    <seg-index, seg-offset, type, symbol-library-ordinal, symbol-name, addend>

    // The opcodes are a compressed way to encode the table by only

    // encoding when a column changes.  In addition simple patterns

    // like for runs of pointers initialzed to the same value can be

    // encoded in a few bytes.


    /// file offset to binding info
    bind_off: u32,

    /// size of binding info
    bind_size: u32,

    // Some C++ programs require dyld to unique symbols so that all

    // images in the process use the same copy of some code/data.

    // This step is done after binding. The content of the weak_bind

    // info is an opcode stream like the bind_info.  But it is sorted

    // alphabetically by symbol name.  This enable dyld to walk

    // all images with weak binding information in order and look

    // for collisions.  If there are no collisions, dyld does

    // no updating.  That means that some fixups are also encoded

    // in the bind_info.  For instance, all calls to "operator new"

    // are first bound to libstdc++.dylib using the information

    // in bind_info.  Then if some image overrides operator new

    // that is detected when the weak_bind information is processed

    // and the call to operator new is then rebound.


    /// file offset to weak binding info
    weak_bind_off: u32,

    /// size of weak binding info
    weak_bind_size: u32,

    // Some uses of external symbols do not need to be bound immediately.

    // Instead they can be lazily bound on first use.  The lazy_bind

    // are contains a stream of BIND opcodes to bind all lazy symbols.

    // Normal use is that dyld ignores the lazy_bind section when

    // loading an image.  Instead the static linker arranged for the

    // lazy pointer to initially point to a helper function which

    // pushes the offset into the lazy_bind area for the symbol

    // needing to be bound, then jumps to dyld which simply adds

    // the offset to lazy_bind_off to get the information on what

    // to bind.


    /// file offset to lazy binding info
    lazy_bind_off: u32,

    /// size of lazy binding info
    lazy_bind_size: u32,

    // The symbols exported by a dylib are encoded in a trie.  This

    // is a compact representation that factors out common prefixes.

    // It also reduces LINKEDIT pages in RAM because it encodes all

    // information (name, address, flags) in one small, contiguous range.

    // The export area is a stream of nodes.  The first node sequentially

    // is the start node for the trie.

    //

    // Nodes for a symbol start with a uleb128 that is the length of

    // the exported symbol information for the string so far.

    // If there is no exported symbol, the node starts with a zero byte.

    // If there is exported info, it follows the length.

    //

    // First is a uleb128 containing flags. Normally, it is followed by

    // a uleb128 encoded offset which is location of the content named

    // by the symbol from the mach_header for the image.  If the flags

    // is EXPORT_SYMBOL_FLAGS_REEXPORT, then following the flags is

    // a uleb128 encoded library ordinal, then a zero terminated

    // UTF8 string.  If the string is zero length, then the symbol

    // is re-export from the specified dylib with the same name.

    // If the flags is EXPORT_SYMBOL_FLAGS_STUB_AND_RESOLVER, then following

    // the flags is two uleb128s: the stub offset and the resolver offset.

    // The stub is used by non-lazy pointers.  The resolver is used

    // by lazy pointers and must be called to get the actual address to use.

    //

    // After the optional exported symbol information is a byte of

    // how many edges (0-255) that this node has leaving it,

    // followed by each edge.

    // Each edge is a zero terminated UTF8 of the addition chars

    // in the symbol, followed by a uleb128 offset for the node that

    // edge points to.


    /// file offset to lazy binding info
    export_off: u32,

    /// size of lazy binding info
    export_size: u32,
};

/// A program that uses a dynamic linker contains a dylinker_command to identify
/// the name of the dynamic linker (LC_LOAD_DYLINKER). And a dynamic linker
/// contains a dylinker_command to identify the dynamic linker (LC_ID_DYLINKER).
/// A file can have at most one of these.
/// This struct is also used for the LC_DYLD_ENVIRONMENT load command and contains
/// string for dyld to treat like an environment variable.
pub const dylinker_command = extern struct {
    /// LC_ID_DYLINKER, LC_LOAD_DYLINKER, or LC_DYLD_ENVIRONMENT
    cmd: LC,

    /// includes pathname string
    cmdsize: u32,

    /// A variable length string in a load command is represented by an lc_str
    /// union.  The strings are stored just after the load command structure and
    /// the offset is from the start of the load command structure.  The size
    /// of the string is reflected in the cmdsize field of the load command.
    /// Once again any padded bytes to bring the cmdsize field to a multiple
    /// of 4 bytes must be zero.
    name: u32,
};

/// A dynamically linked shared library (filetype == MH_DYLIB in the mach header)
/// contains a dylib_command (cmd == LC_ID_DYLIB) to identify the library.
/// An object that uses a dynamically linked shared library also contains a
/// dylib_command (cmd == LC_LOAD_DYLIB, LC_LOAD_WEAK_DYLIB, or
/// LC_REEXPORT_DYLIB) for each library it uses.
pub const dylib_command = extern struct {
    /// LC_ID_DYLIB, LC_LOAD_WEAK_DYLIB, LC_LOAD_DYLIB, LC_REEXPORT_DYLIB
    cmd: LC,

    /// includes pathname string
    cmdsize: u32,

    /// the library identification
    dylib: dylib,
};

/// Dynamicaly linked shared libraries are identified by two things.  The
/// pathname (the name of the library as found for execution), and the
/// compatibility version number.  The pathname must match and the compatibility
/// number in the user of the library must be greater than or equal to the
/// library being used.  The time stamp is used to record the time a library was
/// built and copied into user so it can be use to determined if the library used
/// at runtime is exactly the same as used to built the program.
pub const dylib = extern struct {
    /// library's pathname (offset pointing at the end of dylib_command)
    name: u32,

    /// library's build timestamp
    timestamp: u32,

    /// library's current version number
    current_version: u32,

    /// library's compatibility version number
    compatibility_version: u32,
};

/// The rpath_command contains a path which at runtime should be added to the current
/// run path used to find @rpath prefixed dylibs.
pub const rpath_command = extern struct {
    /// LC_RPATH
    cmd: LC = .RPATH,

    /// includes string
    cmdsize: u32,

    /// path to add to run path
    path: u32,
};

/// The segment load command indicates that a part of this file is to be
/// mapped into the task's address space.  The size of this segment in memory,
/// vmsize, maybe equal to or larger than the amount to map from this file,
/// filesize.  The file is mapped starting at fileoff to the beginning of
/// the segment in memory, vmaddr.  The rest of the memory of the segment,
/// if any, is allocated zero fill on demand.  The segment's maximum virtual
/// memory protection and initial virtual memory protection are specified
/// by the maxprot and initprot fields.  If the segment has sections then the
/// section structures directly follow the segment command and their size is
/// reflected in cmdsize.
pub const segment_command = extern struct {
    /// LC_SEGMENT
    cmd: LC = .SEGMENT,

    /// includes sizeof section structs
    cmdsize: u32,

    /// segment name
    segname: [16]u8,

    /// memory address of this segment
    vmaddr: u32,

    /// memory size of this segment
    vmsize: u32,

    /// file offset of this segment
    fileoff: u32,

    /// amount to map from the file
    filesize: u32,

    /// maximum VM protection
    maxprot: vm_prot_t,

    /// initial VM protection
    initprot: vm_prot_t,

    /// number of sections in segment
    nsects: u32,
    flags: u32,
};

/// The 64-bit segment load command indicates that a part of this file is to be
/// mapped into a 64-bit task's address space.  If the 64-bit segment has
/// sections then section_64 structures directly follow the 64-bit segment
/// command and their size is reflected in cmdsize.
pub const segment_command_64 = extern struct {
    /// LC_SEGMENT_64
    cmd: LC = .SEGMENT_64,

    /// includes sizeof section_64 structs
    cmdsize: u32,
    // TODO lazy values in stage2

    // cmdsize: u32 = @sizeOf(segment_command_64),


    /// segment name
    segname: [16]u8,

    /// memory address of this segment
    vmaddr: u64 = 0,

    /// memory size of this segment
    vmsize: u64 = 0,

    /// file offset of this segment
    fileoff: u64 = 0,

    /// amount to map from the file
    filesize: u64 = 0,

    /// maximum VM protection
    maxprot: vm_prot_t = PROT.NONE,

    /// initial VM protection
    initprot: vm_prot_t = PROT.NONE,

    /// number of sections in segment
    nsects: u32 = 0,
    flags: u32 = 0,

    pub fn segName(seg: *const segment_command_64) []const u8 {
        return parseName(&seg.segname);
    }
};

pub const PROT = struct {
    /// [MC2] no permissions
    pub const NONE: vm_prot_t = 0x00;
    /// [MC2] pages can be read
    pub const READ: vm_prot_t = 0x01;
    /// [MC2] pages can be written
    pub const WRITE: vm_prot_t = 0x02;
    /// [MC2] pages can be executed
    pub const EXEC: vm_prot_t = 0x04;
    /// When a caller finds that they cannot obtain write permission on a
    /// mapped entry, the following flag can be used. The entry will be
    /// made "needs copy" effectively copying the object (using COW),
    /// and write permission will be added to the maximum protections for
    /// the associated entry.
    pub const COPY: vm_prot_t = 0x10;
};

/// A segment is made up of zero or more sections.  Non-MH_OBJECT files have
/// all of their segments with the proper sections in each, and padded to the
/// specified segment alignment when produced by the link editor.  The first
/// segment of a MH_EXECUTE and MH_FVMLIB format file contains the mach_header
/// and load commands of the object file before its first section.  The zero
/// fill sections are always last in their segment (in all formats).  This
/// allows the zeroed segment padding to be mapped into memory where zero fill
/// sections might be. The gigabyte zero fill sections, those with the section
/// type S_GB_ZEROFILL, can only be in a segment with sections of this type.
/// These segments are then placed after all other segments.
///
/// The MH_OBJECT format has all of its sections in one segment for
/// compactness.  There is no padding to a specified segment boundary and the
/// mach_header and load commands are not part of the segment.
///
/// Sections with the same section name, sectname, going into the same segment,
/// segname, are combined by the link editor.  The resulting section is aligned
/// to the maximum alignment of the combined sections and is the new section's
/// alignment.  The combined sections are aligned to their original alignment in
/// the combined section.  Any padded bytes to get the specified alignment are
/// zeroed.
///
/// The format of the relocation entries referenced by the reloff and nreloc
/// fields of the section structure for mach object files is described in the
/// header file <reloc.h>.
pub const @"section" = extern struct {
    /// name of this section
    sectname: [16]u8,

    /// segment this section goes in
    segname: [16]u8,

    /// memory address of this section
    addr: u32,

    /// size in bytes of this section
    size: u32,

    /// file offset of this section
    offset: u32,

    /// section alignment (power of 2)
    @"align": u32,

    /// file offset of relocation entries
    reloff: u32,

    /// number of relocation entries
    nreloc: u32,

    /// flags (section type and attributes
    flags: u32,

    /// reserved (for offset or index)
    reserved1: u32,

    /// reserved (for count or sizeof)
    reserved2: u32,
};

pub const section_64 = extern struct {
    /// name of this section
    sectname: [16]u8,

    /// segment this section goes in
    segname: [16]u8,

    /// memory address of this section
    addr: u64 = 0,

    /// size in bytes of this section
    size: u64 = 0,

    /// file offset of this section
    offset: u32 = 0,

    /// section alignment (power of 2)
    @"align": u32 = 0,

    /// file offset of relocation entries
    reloff: u32 = 0,

    /// number of relocation entries
    nreloc: u32 = 0,

    /// flags (section type and attributes
    flags: u32 = S_REGULAR,

    /// reserved (for offset or index)
    reserved1: u32 = 0,

    /// reserved (for count or sizeof)
    reserved2: u32 = 0,

    /// reserved
    reserved3: u32 = 0,

    pub fn sectName(sect: *const section_64) []const u8 {
        return parseName(&sect.sectname);
    }

    pub fn segName(sect: *const section_64) []const u8 {
        return parseName(&sect.segname);
    }

    pub fn @"type"(sect: section_64) u8 {
        return @truncate(u8, sect.flags & 0xff);
    }

    pub fn attrs(sect: section_64) u32 {
        return sect.flags & 0xffffff00;
    }

    pub fn isCode(sect: section_64) bool {
        const attr = sect.attrs();
        return attr & S_ATTR_PURE_INSTRUCTIONS != 0 or attr & S_ATTR_SOME_INSTRUCTIONS != 0;
    }

    pub fn isZerofill(sect: section_64) bool {
        const tt = sect.@"type"();
        return tt == S_ZEROFILL or tt == S_GB_ZEROFILL or tt == S_THREAD_LOCAL_ZEROFILL;
    }

    pub fn isSymbolStubs(sect: section_64) bool {
        const tt = sect.@"type"();
        return tt == S_SYMBOL_STUBS;
    }

    pub fn isDebug(sect: section_64) bool {
        return sect.attrs() & S_ATTR_DEBUG != 0;
    }

    pub fn isDontDeadStrip(sect: section_64) bool {
        return sect.attrs() & S_ATTR_NO_DEAD_STRIP != 0;
    }

    pub fn isDontDeadStripIfReferencesLive(sect: section_64) bool {
        return sect.attrs() & S_ATTR_LIVE_SUPPORT != 0;
    }
};

fn parseName(name: *const [16]u8) []const u8 {
    const len = mem.indexOfScalar(u8, name, @as(u8, 0)) orelse name.len;
    return name[0..len];
}

pub const nlist = extern struct {
    n_strx: u32,
    n_type: u8,
    n_sect: u8,
    n_desc: i16,
    n_value: u32,
};

pub const nlist_64 = extern struct {
    n_strx: u32,
    n_type: u8,
    n_sect: u8,
    n_desc: u16,
    n_value: u64,

    pub fn stab(sym: nlist_64) bool {
        return (N_STAB & sym.n_type) != 0;
    }

    pub fn pext(sym: nlist_64) bool {
        return (N_PEXT & sym.n_type) != 0;
    }

    pub fn ext(sym: nlist_64) bool {
        return (N_EXT & sym.n_type) != 0;
    }

    pub fn sect(sym: nlist_64) bool {
        const type_ = N_TYPE & sym.n_type;
        return type_ == N_SECT;
    }

    pub fn undf(sym: nlist_64) bool {
        const type_ = N_TYPE & sym.n_type;
        return type_ == N_UNDF;
    }

    pub fn indr(sym: nlist_64) bool {
        const type_ = N_TYPE & sym.n_type;
        return type_ == N_INDR;
    }

    pub fn abs(sym: nlist_64) bool {
        const type_ = N_TYPE & sym.n_type;
        return type_ == N_ABS;
    }

    pub fn weakDef(sym: nlist_64) bool {
        return (sym.n_desc & N_WEAK_DEF) != 0;
    }

    pub fn weakRef(sym: nlist_64) bool {
        return (sym.n_desc & N_WEAK_REF) != 0;
    }

    pub fn discarded(sym: nlist_64) bool {
        return (sym.n_desc & N_DESC_DISCARDED) != 0;
    }

    pub fn tentative(sym: nlist_64) bool {
        if (!sym.undf()) return false;
        return sym.n_value != 0;
    }
};

/// Format of a relocation entry of a Mach-O file.  Modified from the 4.3BSD
/// format.  The modifications from the original format were changing the value
/// of the r_symbolnum field for "local" (r_extern == 0) relocation entries.
/// This modification is required to support symbols in an arbitrary number of
/// sections not just the three sections (text, data and bss) in a 4.3BSD file.
/// Also the last 4 bits have had the r_type tag added to them.
pub const relocation_info = packed struct {
    /// offset in the section to what is being relocated
    r_address: i32,

    /// symbol index if r_extern == 1 or section ordinal if r_extern == 0
    r_symbolnum: u24,

    /// was relocated pc relative already
    r_pcrel: u1,

    /// 0=byte, 1=word, 2=long, 3=quad
    r_length: u2,

    /// does not include value of sym referenced
    r_extern: u1,

    /// if not 0, machine specific relocation type
    r_type: u4,
};

/// After MacOS X 10.1 when a new load command is added that is required to be
/// understood by the dynamic linker for the image to execute properly the
/// LC_REQ_DYLD bit will be or'ed into the load command constant.  If the dynamic
/// linker sees such a load command it it does not understand will issue a
/// "unknown load command required for execution" error and refuse to use the
/// image.  Other load commands without this bit that are not understood will
/// simply be ignored.
pub const LC_REQ_DYLD = 0x80000000;

pub const LC = enum(u32) {
    /// No load command - invalid
    NONE = 0x0,

    /// segment of this file to be mapped
    SEGMENT = 0x1,

    /// link-edit stab symbol table info
    SYMTAB = 0x2,

    /// link-edit gdb symbol table info (obsolete)
    SYMSEG = 0x3,

    /// thread
    THREAD = 0x4,

    /// unix thread (includes a stack)
    UNIXTHREAD = 0x5,

    /// load a specified fixed VM shared library
    LOADFVMLIB = 0x6,

    /// fixed VM shared library identification
    IDFVMLIB = 0x7,

    /// object identification info (obsolete)
    IDENT = 0x8,

    /// fixed VM file inclusion (internal use)
    FVMFILE = 0x9,

    /// prepage command (internal use)
    PREPAGE = 0xa,

    /// dynamic link-edit symbol table info
    DYSYMTAB = 0xb,

    /// load a dynamically linked shared library
    LOAD_DYLIB = 0xc,

    /// dynamically linked shared lib ident
    ID_DYLIB = 0xd,

    /// load a dynamic linker
    LOAD_DYLINKER = 0xe,

    /// dynamic linker identification
    ID_DYLINKER = 0xf,

    /// modules prebound for a dynamically
    PREBOUND_DYLIB = 0x10,

    /// image routines
    ROUTINES = 0x11,

    /// sub framework
    SUB_FRAMEWORK = 0x12,

    /// sub umbrella
    SUB_UMBRELLA = 0x13,

    /// sub client
    SUB_CLIENT = 0x14,

    /// sub library
    SUB_LIBRARY = 0x15,

    /// two-level namespace lookup hints
    TWOLEVEL_HINTS = 0x16,

    /// prebind checksum
    PREBIND_CKSUM = 0x17,

    /// load a dynamically linked shared library that is allowed to be missing
    /// (all symbols are weak imported).
    LOAD_WEAK_DYLIB = (0x18 | LC_REQ_DYLD),

    /// 64-bit segment of this file to be mapped
    SEGMENT_64 = 0x19,

    /// 64-bit image routines
    ROUTINES_64 = 0x1a,

    /// the uuid
    UUID = 0x1b,

    /// runpath additions
    RPATH = (0x1c | LC_REQ_DYLD),

    /// local of code signature
    CODE_SIGNATURE = 0x1d,

    /// local of info to split segments
    SEGMENT_SPLIT_INFO = 0x1e,

    /// load and re-export dylib
    REEXPORT_DYLIB = (0x1f | LC_REQ_DYLD),

    /// delay load of dylib until first use
    LAZY_LOAD_DYLIB = 0x20,

    /// encrypted segment information
    ENCRYPTION_INFO = 0x21,

    /// compressed dyld information
    DYLD_INFO = 0x22,

    /// compressed dyld information only
    DYLD_INFO_ONLY = (0x22 | LC_REQ_DYLD),

    /// load upward dylib
    LOAD_UPWARD_DYLIB = (0x23 | LC_REQ_DYLD),

    /// build for MacOSX min OS version
    VERSION_MIN_MACOSX = 0x24,

    /// build for iPhoneOS min OS version
    VERSION_MIN_IPHONEOS = 0x25,

    /// compressed table of function start addresses
    FUNCTION_STARTS = 0x26,

    /// string for dyld to treat like environment variable
    DYLD_ENVIRONMENT = 0x27,

    /// replacement for LC_UNIXTHREAD
    MAIN = (0x28 | LC_REQ_DYLD),

    /// table of non-instructions in __text
    DATA_IN_CODE = 0x29,

    /// source version used to build binary
    SOURCE_VERSION = 0x2A,

    /// Code signing DRs copied from linked dylibs
    DYLIB_CODE_SIGN_DRS = 0x2B,

    /// 64-bit encrypted segment information
    ENCRYPTION_INFO_64 = 0x2C,

    /// linker options in MH_OBJECT files
    LINKER_OPTION = 0x2D,

    /// optimization hints in MH_OBJECT files
    LINKER_OPTIMIZATION_HINT = 0x2E,

    /// build for AppleTV min OS version
    VERSION_MIN_TVOS = 0x2F,

    /// build for Watch min OS version
    VERSION_MIN_WATCHOS = 0x30,

    /// arbitrary data included within a Mach-O file
    NOTE = 0x31,

    /// build for platform min OS version
    BUILD_VERSION = 0x32,

    _,
};

/// the mach magic number
pub const MH_MAGIC = 0xfeedface;

/// NXSwapInt(MH_MAGIC)
pub const MH_CIGAM = 0xcefaedfe;

/// the 64-bit mach magic number
pub const MH_MAGIC_64 = 0xfeedfacf;

/// NXSwapInt(MH_MAGIC_64)
pub const MH_CIGAM_64 = 0xcffaedfe;

/// relocatable object file
pub const MH_OBJECT = 0x1;

/// demand paged executable file
pub const MH_EXECUTE = 0x2;

/// fixed VM shared library file
pub const MH_FVMLIB = 0x3;

/// core file
pub const MH_CORE = 0x4;

/// preloaded executable file
pub const MH_PRELOAD = 0x5;

/// dynamically bound shared library
pub const MH_DYLIB = 0x6;

/// dynamic link editor
pub const MH_DYLINKER = 0x7;

/// dynamically bound bundle file
pub const MH_BUNDLE = 0x8;

/// shared library stub for static linking only, no section contents
pub const MH_DYLIB_STUB = 0x9;

/// companion file with only debug sections
pub const MH_DSYM = 0xa;

/// x86_64 kexts
pub const MH_KEXT_BUNDLE = 0xb;

// Constants for the flags field of the mach_header


/// the object file has no undefined references
pub const MH_NOUNDEFS = 0x1;

/// the object file is the output of an incremental link against a base file and can't be link edited again
pub const MH_INCRLINK = 0x2;

/// the object file is input for the dynamic linker and can't be staticly link edited again
pub const MH_DYLDLINK = 0x4;

/// the object file's undefined references are bound by the dynamic linker when loaded.
pub const MH_BINDATLOAD = 0x8;

/// the file has its dynamic undefined references prebound.
pub const MH_PREBOUND = 0x10;

/// the file has its read-only and read-write segments split
pub const MH_SPLIT_SEGS = 0x20;

/// the shared library init routine is to be run lazily via catching memory faults to its writeable segments (obsolete)
pub const MH_LAZY_INIT = 0x40;

/// the image is using two-level name space bindings
pub const MH_TWOLEVEL = 0x80;

/// the executable is forcing all images to use flat name space bindings
pub const MH_FORCE_FLAT = 0x100;

/// this umbrella guarantees no multiple defintions of symbols in its sub-images so the two-level namespace hints can always be used.
pub const MH_NOMULTIDEFS = 0x200;

/// do not have dyld notify the prebinding agent about this executable
pub const MH_NOFIXPREBINDING = 0x400;

/// the binary is not prebound but can have its prebinding redone. only used when MH_PREBOUND is not set.
pub const MH_PREBINDABLE = 0x800;

/// indicates that this binary binds to all two-level namespace modules of its dependent libraries. only used when MH_PREBINDABLE and MH_TWOLEVEL are both set.
pub const MH_ALLMODSBOUND = 0x1000;

/// safe to divide up the sections into sub-sections via symbols for dead code stripping
pub const MH_SUBSECTIONS_VIA_SYMBOLS = 0x2000;

/// the binary has been canonicalized via the unprebind operation
pub const MH_CANONICAL = 0x4000;

/// the final linked image contains external weak symbols
pub const MH_WEAK_DEFINES = 0x8000;

/// the final linked image uses weak symbols
pub const MH_BINDS_TO_WEAK = 0x10000;

/// When this bit is set, all stacks in the task will be given stack execution privilege.  Only used in MH_EXECUTE filetypes.
pub const MH_ALLOW_STACK_EXECUTION = 0x20000;

/// When this bit is set, the binary declares it is safe for use in processes with uid zero
pub const MH_ROOT_SAFE = 0x40000;

/// When this bit is set, the binary declares it is safe for use in processes when issetugid() is true
pub const MH_SETUID_SAFE = 0x80000;

/// When this bit is set on a dylib, the static linker does not need to examine dependent dylibs to see if any are re-exported
pub const MH_NO_REEXPORTED_DYLIBS = 0x100000;

/// When this bit is set, the OS will load the main executable at a random address.  Only used in MH_EXECUTE filetypes.
pub const MH_PIE = 0x200000;

/// Only for use on dylibs.  When linking against a dylib that has this bit set, the static linker will automatically not create a LC_LOAD_DYLIB load command to the dylib if no symbols are being referenced from the dylib.
pub const MH_DEAD_STRIPPABLE_DYLIB = 0x400000;

/// Contains a section of type S_THREAD_LOCAL_VARIABLES
pub const MH_HAS_TLV_DESCRIPTORS = 0x800000;

/// When this bit is set, the OS will run the main executable with a non-executable heap even on platforms (e.g. i386) that don't require it. Only used in MH_EXECUTE filetypes.
pub const MH_NO_HEAP_EXECUTION = 0x1000000;

/// The code was linked for use in an application extension.
pub const MH_APP_EXTENSION_SAFE = 0x02000000;

/// The external symbols listed in the nlist symbol table do not include all the symbols listed in the dyld info.
pub const MH_NLIST_OUTOFSYNC_WITH_DYLDINFO = 0x04000000;

// Constants for the flags field of the fat_header


/// the fat magic number
pub const FAT_MAGIC = 0xcafebabe;

/// NXSwapLong(FAT_MAGIC)
pub const FAT_CIGAM = 0xbebafeca;

/// the 64-bit fat magic number
pub const FAT_MAGIC_64 = 0xcafebabf;

/// NXSwapLong(FAT_MAGIC_64)
pub const FAT_CIGAM_64 = 0xbfbafeca;

/// The flags field of a section structure is separated into two parts a section
/// type and section attributes.  The section types are mutually exclusive (it
/// can only have one type) but the section attributes are not (it may have more
/// than one attribute).
/// 256 section types
pub const SECTION_TYPE = 0x000000ff;

///  24 section attributes
pub const SECTION_ATTRIBUTES = 0xffffff00;

/// regular section
pub const S_REGULAR = 0x0;

/// zero fill on demand section
pub const S_ZEROFILL = 0x1;

/// section with only literal C string
pub const S_CSTRING_LITERALS = 0x2;

/// section with only 4 byte literals
pub const S_4BYTE_LITERALS = 0x3;

/// section with only 8 byte literals
pub const S_8BYTE_LITERALS = 0x4;

/// section with only pointers to
pub const S_LITERAL_POINTERS = 0x5;

/// if any of these bits set, a symbolic debugging entry
pub const N_STAB = 0xe0;

/// private external symbol bit
pub const N_PEXT = 0x10;

/// mask for the type bits
pub const N_TYPE = 0x0e;

/// external symbol bit, set for external symbols
pub const N_EXT = 0x01;

/// symbol is undefined
pub const N_UNDF = 0x0;

/// symbol is absolute
pub const N_ABS = 0x2;

/// symbol is defined in the section number given in n_sect
pub const N_SECT = 0xe;

/// symbol is undefined  and the image is using a prebound
/// value  for the symbol
pub const N_PBUD = 0xc;

/// symbol is defined to be the same as another symbol; the n_value
/// field is an index into the string table specifying the name of the
/// other symbol
pub const N_INDR = 0xa;

/// global symbol: name,,NO_SECT,type,0
pub const N_GSYM = 0x20;

/// procedure name (f77 kludge): name,,NO_SECT,0,0
pub const N_FNAME = 0x22;

/// procedure: name,,n_sect,linenumber,address
pub const N_FUN = 0x24;

/// static symbol: name,,n_sect,type,address
pub const N_STSYM = 0x26;

/// .lcomm symbol: name,,n_sect,type,address
pub const N_LCSYM = 0x28;

/// begin nsect sym: 0,,n_sect,0,address
pub const N_BNSYM = 0x2e;

/// AST file path: name,,NO_SECT,0,0
pub const N_AST = 0x32;

/// emitted with gcc2_compiled and in gcc source
pub const N_OPT = 0x3c;

/// register sym: name,,NO_SECT,type,register
pub const N_RSYM = 0x40;

/// src line: 0,,n_sect,linenumber,address
pub const N_SLINE = 0x44;

/// end nsect sym: 0,,n_sect,0,address
pub const N_ENSYM = 0x4e;

/// structure elt: name,,NO_SECT,type,struct_offset
pub const N_SSYM = 0x60;

/// source file name: name,,n_sect,0,address
pub const N_SO = 0x64;

/// object file name: name,,0,0,st_mtime
pub const N_OSO = 0x66;

/// local sym: name,,NO_SECT,type,offset
pub const N_LSYM = 0x80;

/// include file beginning: name,,NO_SECT,0,sum
pub const N_BINCL = 0x82;

/// #included file name: name,,n_sect,0,address
pub const N_SOL = 0x84;

/// compiler parameters: name,,NO_SECT,0,0
pub const N_PARAMS = 0x86;

/// compiler version: name,,NO_SECT,0,0
pub const N_VERSION = 0x88;

/// compiler -O level: name,,NO_SECT,0,0
pub const N_OLEVEL = 0x8A;

/// parameter: name,,NO_SECT,type,offset
pub const N_PSYM = 0xa0;

/// include file end: name,,NO_SECT,0,0
pub const N_EINCL = 0xa2;

/// alternate entry: name,,n_sect,linenumber,address
pub const N_ENTRY = 0xa4;

/// left bracket: 0,,NO_SECT,nesting level,address
pub const N_LBRAC = 0xc0;

/// deleted include file: name,,NO_SECT,0,sum
pub const N_EXCL = 0xc2;

/// right bracket: 0,,NO_SECT,nesting level,address
pub const N_RBRAC = 0xe0;

/// begin common: name,,NO_SECT,0,0
pub const N_BCOMM = 0xe2;

/// end common: name,,n_sect,0,0
pub const N_ECOMM = 0xe4;

/// end common (local name): 0,,n_sect,0,address
pub const N_ECOML = 0xe8;

/// second stab entry with length information
pub const N_LENG = 0xfe;

// For the two types of symbol pointers sections and the symbol stubs section

// they have indirect symbol table entries.  For each of the entries in the

// section the indirect symbol table entries, in corresponding order in the

// indirect symbol table, start at the index stored in the reserved1 field

// of the section structure.  Since the indirect symbol table entries

// correspond to the entries in the section the number of indirect symbol table

// entries is inferred from the size of the section divided by the size of the

// entries in the section.  For symbol pointers sections the size of the entries

// in the section is 4 bytes and for symbol stubs sections the byte size of the

// stubs is stored in the reserved2 field of the section structure.


/// section with only non-lazy symbol pointers
pub const S_NON_LAZY_SYMBOL_POINTERS = 0x6;

/// section with only lazy symbol pointers
pub const S_LAZY_SYMBOL_POINTERS = 0x7;

/// section with only symbol stubs, byte size of stub in the reserved2 field
pub const S_SYMBOL_STUBS = 0x8;

/// section with only function pointers for initialization
pub const S_MOD_INIT_FUNC_POINTERS = 0x9;

/// section with only function pointers for termination
pub const S_MOD_TERM_FUNC_POINTERS = 0xa;

/// section contains symbols that are to be coalesced
pub const S_COALESCED = 0xb;

/// zero fill on demand section (that can be larger than 4 gigabytes)
pub const S_GB_ZEROFILL = 0xc;

/// section with only pairs of function pointers for interposing
pub const S_INTERPOSING = 0xd;

/// section with only 16 byte literals
pub const S_16BYTE_LITERALS = 0xe;

/// section contains DTrace Object Format
pub const S_DTRACE_DOF = 0xf;

/// section with only lazy symbol pointers to lazy loaded dylibs
pub const S_LAZY_DYLIB_SYMBOL_POINTERS = 0x10;

// If a segment contains any sections marked with S_ATTR_DEBUG then all

// sections in that segment must have this attribute.  No section other than

// a section marked with this attribute may reference the contents of this

// section.  A section with this attribute may contain no symbols and must have

// a section type S_REGULAR.  The static linker will not copy section contents

// from sections with this attribute into its output file.  These sections

// generally contain DWARF debugging info.


/// a debug section
pub const S_ATTR_DEBUG = 0x02000000;

/// section contains only true machine instructions
pub const S_ATTR_PURE_INSTRUCTIONS = 0x80000000;

/// section contains coalesced symbols that are not to be in a ranlib
/// table of contents
pub const S_ATTR_NO_TOC = 0x40000000;

/// ok to strip static symbols in this section in files with the
/// MH_DYLDLINK flag
pub const S_ATTR_STRIP_STATIC_SYMS = 0x20000000;

/// no dead stripping
pub const S_ATTR_NO_DEAD_STRIP = 0x10000000;

/// blocks are live if they reference live blocks
pub const S_ATTR_LIVE_SUPPORT = 0x8000000;

/// used with i386 code stubs written on by dyld
pub const S_ATTR_SELF_MODIFYING_CODE = 0x4000000;

/// section contains some machine instructions
pub const S_ATTR_SOME_INSTRUCTIONS = 0x400;

/// section has external relocation entries
pub const S_ATTR_EXT_RELOC = 0x200;

/// section has local relocation entries
pub const S_ATTR_LOC_RELOC = 0x100;

/// template of initial values for TLVs
pub const S_THREAD_LOCAL_REGULAR = 0x11;

/// template of initial values for TLVs
pub const S_THREAD_LOCAL_ZEROFILL = 0x12;

/// TLV descriptors
pub const S_THREAD_LOCAL_VARIABLES = 0x13;

/// pointers to TLV descriptors
pub const S_THREAD_LOCAL_VARIABLE_POINTERS = 0x14;

/// functions to call to initialize TLV values
pub const S_THREAD_LOCAL_INIT_FUNCTION_POINTERS = 0x15;

/// 32-bit offsets to initializers
pub const S_INIT_FUNC_OFFSETS = 0x16;

/// CPU type targeting 64-bit Intel-based Macs
pub const CPU_TYPE_X86_64: cpu_type_t = 0x01000007;

/// CPU type targeting 64-bit ARM-based Macs
pub const CPU_TYPE_ARM64: cpu_type_t = 0x0100000C;

/// All Intel-based Macs
pub const CPU_SUBTYPE_X86_64_ALL: cpu_subtype_t = 0x3;

/// All ARM-based Macs
pub const CPU_SUBTYPE_ARM_ALL: cpu_subtype_t = 0x0;

// The following are used to encode rebasing information

pub const REBASE_TYPE_POINTER: u8 = 1;
pub const REBASE_TYPE_TEXT_ABSOLUTE32: u8 = 2;
pub const REBASE_TYPE_TEXT_PCREL32: u8 = 3;

pub const REBASE_OPCODE_MASK: u8 = 0xF0;
pub const REBASE_IMMEDIATE_MASK: u8 = 0x0F;
pub const REBASE_OPCODE_DONE: u8 = 0x00;
pub const REBASE_OPCODE_SET_TYPE_IMM: u8 = 0x10;
pub const REBASE_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB: u8 = 0x20;
pub const REBASE_OPCODE_ADD_ADDR_ULEB: u8 = 0x30;
pub const REBASE_OPCODE_ADD_ADDR_IMM_SCALED: u8 = 0x40;
pub const REBASE_OPCODE_DO_REBASE_IMM_TIMES: u8 = 0x50;
pub const REBASE_OPCODE_DO_REBASE_ULEB_TIMES: u8 = 0x60;
pub const REBASE_OPCODE_DO_REBASE_ADD_ADDR_ULEB: u8 = 0x70;
pub const REBASE_OPCODE_DO_REBASE_ULEB_TIMES_SKIPPING_ULEB: u8 = 0x80;

// The following are used to encode binding information

pub const BIND_TYPE_POINTER: u8 = 1;
pub const BIND_TYPE_TEXT_ABSOLUTE32: u8 = 2;
pub const BIND_TYPE_TEXT_PCREL32: u8 = 3;

pub const BIND_SPECIAL_DYLIB_SELF: i8 = 0;
pub const BIND_SPECIAL_DYLIB_MAIN_EXECUTABLE: i8 = -1;
pub const BIND_SPECIAL_DYLIB_FLAT_LOOKUP: i8 = -2;

pub const BIND_SYMBOL_FLAGS_WEAK_IMPORT: u8 = 0x1;
pub const BIND_SYMBOL_FLAGS_NON_WEAK_DEFINITION: u8 = 0x8;

pub const BIND_OPCODE_MASK: u8 = 0xf0;
pub const BIND_IMMEDIATE_MASK: u8 = 0x0f;
pub const BIND_OPCODE_DONE: u8 = 0x00;
pub const BIND_OPCODE_SET_DYLIB_ORDINAL_IMM: u8 = 0x10;
pub const BIND_OPCODE_SET_DYLIB_ORDINAL_ULEB: u8 = 0x20;
pub const BIND_OPCODE_SET_DYLIB_SPECIAL_IMM: u8 = 0x30;
pub const BIND_OPCODE_SET_SYMBOL_TRAILING_FLAGS_IMM: u8 = 0x40;
pub const BIND_OPCODE_SET_TYPE_IMM: u8 = 0x50;
pub const BIND_OPCODE_SET_ADDEND_SLEB: u8 = 0x60;
pub const BIND_OPCODE_SET_SEGMENT_AND_OFFSET_ULEB: u8 = 0x70;
pub const BIND_OPCODE_ADD_ADDR_ULEB: u8 = 0x80;
pub const BIND_OPCODE_DO_BIND: u8 = 0x90;
pub const BIND_OPCODE_DO_BIND_ADD_ADDR_ULEB: u8 = 0xa0;
pub const BIND_OPCODE_DO_BIND_ADD_ADDR_IMM_SCALED: u8 = 0xb0;
pub const BIND_OPCODE_DO_BIND_ULEB_TIMES_SKIPPING_ULEB: u8 = 0xc0;

pub const reloc_type_x86_64 = enum(u4) {
    /// for absolute addresses
    X86_64_RELOC_UNSIGNED = 0,

    /// for signed 32-bit displacement
    X86_64_RELOC_SIGNED,

    /// a CALL/JMP instruction with 32-bit displacement
    X86_64_RELOC_BRANCH,

    /// a MOVQ load of a GOT entry
    X86_64_RELOC_GOT_LOAD,

    /// other GOT references
    X86_64_RELOC_GOT,

    /// must be followed by a X86_64_RELOC_UNSIGNED
    X86_64_RELOC_SUBTRACTOR,

    /// for signed 32-bit displacement with a -1 addend
    X86_64_RELOC_SIGNED_1,

    /// for signed 32-bit displacement with a -2 addend
    X86_64_RELOC_SIGNED_2,

    /// for signed 32-bit displacement with a -4 addend
    X86_64_RELOC_SIGNED_4,

    /// for thread local variables
    X86_64_RELOC_TLV,
};

pub const reloc_type_arm64 = enum(u4) {
    /// For pointers.
    ARM64_RELOC_UNSIGNED = 0,

    /// Must be followed by a ARM64_RELOC_UNSIGNED.
    ARM64_RELOC_SUBTRACTOR,

    /// A B/BL instruction with 26-bit displacement.
    ARM64_RELOC_BRANCH26,

    /// Pc-rel distance to page of target.
    ARM64_RELOC_PAGE21,

    /// Offset within page, scaled by r_length.
    ARM64_RELOC_PAGEOFF12,

    /// Pc-rel distance to page of GOT slot.
    ARM64_RELOC_GOT_LOAD_PAGE21,

    /// Offset within page of GOT slot, scaled by r_length.
    ARM64_RELOC_GOT_LOAD_PAGEOFF12,

    /// For pointers to GOT slots.
    ARM64_RELOC_POINTER_TO_GOT,

    /// Pc-rel distance to page of TLVP slot.
    ARM64_RELOC_TLVP_LOAD_PAGE21,

    /// Offset within page of TLVP slot, scaled by r_length.
    ARM64_RELOC_TLVP_LOAD_PAGEOFF12,

    /// Must be followed by PAGE21 or PAGEOFF12.
    ARM64_RELOC_ADDEND,
};

/// This symbol is a reference to an external non-lazy (data) symbol.
pub const REFERENCE_FLAG_UNDEFINED_NON_LAZY: u16 = 0x0;

/// This symbol is a reference to an external lazy symbol—that is, to a function call.
pub const REFERENCE_FLAG_UNDEFINED_LAZY: u16 = 0x1;

/// This symbol is defined in this module.
pub const REFERENCE_FLAG_DEFINED: u16 = 0x2;

/// This symbol is defined in this module and is visible only to modules within this shared library.
pub const REFERENCE_FLAG_PRIVATE_DEFINED: u16 = 3;

/// This symbol is defined in another module in this file, is a non-lazy (data) symbol, and is visible
/// only to modules within this shared library.
pub const REFERENCE_FLAG_PRIVATE_UNDEFINED_NON_LAZY: u16 = 4;

/// This symbol is defined in another module in this file, is a lazy (function) symbol, and is visible
/// only to modules within this shared library.
pub const REFERENCE_FLAG_PRIVATE_UNDEFINED_LAZY: u16 = 5;

/// Must be set for any defined symbol that is referenced by dynamic-loader APIs (such as dlsym and
/// NSLookupSymbolInImage) and not ordinary undefined symbol references. The strip tool uses this bit
/// to avoid removing symbols that must exist: If the symbol has this bit set, strip does not strip it.
pub const REFERENCED_DYNAMICALLY: u16 = 0x10;

/// Used by the dynamic linker at runtime. Do not set this bit.
pub const N_DESC_DISCARDED: u16 = 0x20;

/// Indicates that this symbol is a weak reference. If the dynamic linker cannot find a definition
/// for this symbol, it sets the address of this symbol to 0. The static linker sets this symbol given
/// the appropriate weak-linking flags.
pub const N_WEAK_REF: u16 = 0x40;

/// Indicates that this symbol is a weak definition. If the static linker or the dynamic linker finds
/// another (non-weak) definition for this symbol, the weak definition is ignored. Only symbols in a
/// coalesced section (page 23) can be marked as a weak definition.
pub const N_WEAK_DEF: u16 = 0x80;

/// The N_SYMBOL_RESOLVER bit of the n_desc field indicates that the
/// that the function is actually a resolver function and should
/// be called to get the address of the real function to use.
/// This bit is only available in .o files (MH_OBJECT filetype)
pub const N_SYMBOL_RESOLVER: u16 = 0x100;

// The following are used on the flags byte of a terminal node in the export information.

pub const EXPORT_SYMBOL_FLAGS_KIND_MASK: u8 = 0x03;
pub const EXPORT_SYMBOL_FLAGS_KIND_REGULAR: u8 = 0x00;
pub const EXPORT_SYMBOL_FLAGS_KIND_THREAD_LOCAL: u8 = 0x01;
pub const EXPORT_SYMBOL_FLAGS_KIND_ABSOLUTE: u8 = 0x02;
pub const EXPORT_SYMBOL_FLAGS_KIND_WEAK_DEFINITION: u8 = 0x04;
pub const EXPORT_SYMBOL_FLAGS_REEXPORT: u8 = 0x08;
pub const EXPORT_SYMBOL_FLAGS_STUB_AND_RESOLVER: u8 = 0x10;

// An indirect symbol table entry is simply a 32bit index into the symbol table

// to the symbol that the pointer or stub is refering to.  Unless it is for a

// non-lazy symbol pointer section for a defined symbol which strip(1) as

// removed.  In which case it has the value INDIRECT_SYMBOL_LOCAL.  If the

// symbol was also absolute INDIRECT_SYMBOL_ABS is or'ed with that.

pub const INDIRECT_SYMBOL_LOCAL: u32 = 0x80000000;
pub const INDIRECT_SYMBOL_ABS: u32 = 0x40000000;

// Codesign consts and structs taken from:

// https://opensource.apple.com/source/xnu/xnu-6153.81.5/osfmk/kern/cs_blobs.h.auto.html


/// Single Requirement blob
pub const CSMAGIC_REQUIREMENT: u32 = 0xfade0c00;
/// Requirements vector (internal requirements)
pub const CSMAGIC_REQUIREMENTS: u32 = 0xfade0c01;
/// CodeDirectory blob
pub const CSMAGIC_CODEDIRECTORY: u32 = 0xfade0c02;
/// embedded form of signature data
pub const CSMAGIC_EMBEDDED_SIGNATURE: u32 = 0xfade0cc0;
/// XXX
pub const CSMAGIC_EMBEDDED_SIGNATURE_OLD: u32 = 0xfade0b02;
/// Embedded entitlements
pub const CSMAGIC_EMBEDDED_ENTITLEMENTS: u32 = 0xfade7171;
/// Embedded DER encoded entitlements
pub const CSMAGIC_EMBEDDED_DER_ENTITLEMENTS: u32 = 0xfade7172;
/// Multi-arch collection of embedded signatures
pub const CSMAGIC_DETACHED_SIGNATURE: u32 = 0xfade0cc1;
/// CMS Signature, among other things
pub const CSMAGIC_BLOBWRAPPER: u32 = 0xfade0b01;

pub const CS_SUPPORTSSCATTER: u32 = 0x20100;
pub const CS_SUPPORTSTEAMID: u32 = 0x20200;
pub const CS_SUPPORTSCODELIMIT64: u32 = 0x20300;
pub const CS_SUPPORTSEXECSEG: u32 = 0x20400;

/// Slot index for CodeDirectory
pub const CSSLOT_CODEDIRECTORY: u32 = 0;
pub const CSSLOT_INFOSLOT: u32 = 1;
pub const CSSLOT_REQUIREMENTS: u32 = 2;
pub const CSSLOT_RESOURCEDIR: u32 = 3;
pub const CSSLOT_APPLICATION: u32 = 4;
pub const CSSLOT_ENTITLEMENTS: u32 = 5;
pub const CSSLOT_DER_ENTITLEMENTS: u32 = 7;

/// first alternate CodeDirectory, if any
pub const CSSLOT_ALTERNATE_CODEDIRECTORIES: u32 = 0x1000;
/// Max number of alternate CD slots
pub const CSSLOT_ALTERNATE_CODEDIRECTORY_MAX: u32 = 5;
/// One past the last
pub const CSSLOT_ALTERNATE_CODEDIRECTORY_LIMIT: u32 = CSSLOT_ALTERNATE_CODEDIRECTORIES + CSSLOT_ALTERNATE_CODEDIRECTORY_MAX;

/// CMS Signature
pub const CSSLOT_SIGNATURESLOT: u32 = 0x10000;
pub const CSSLOT_IDENTIFICATIONSLOT: u32 = 0x10001;
pub const CSSLOT_TICKETSLOT: u32 = 0x10002;

/// Compat with amfi
pub const CSTYPE_INDEX_REQUIREMENTS: u32 = 0x00000002;
/// Compat with amfi
pub const CSTYPE_INDEX_ENTITLEMENTS: u32 = 0x00000005;

pub const CS_HASHTYPE_SHA1: u8 = 1;
pub const CS_HASHTYPE_SHA256: u8 = 2;
pub const CS_HASHTYPE_SHA256_TRUNCATED: u8 = 3;
pub const CS_HASHTYPE_SHA384: u8 = 4;

pub const CS_SHA1_LEN: u32 = 20;
pub const CS_SHA256_LEN: u32 = 32;
pub const CS_SHA256_TRUNCATED_LEN: u32 = 20;

/// Always - larger hashes are truncated
pub const CS_CDHASH_LEN: u32 = 20;
/// Max size of the hash we'll support
pub const CS_HASH_MAX_SIZE: u32 = 48;

pub const CS_SIGNER_TYPE_UNKNOWN: u32 = 0;
pub const CS_SIGNER_TYPE_LEGACYVPN: u32 = 5;
pub const CS_SIGNER_TYPE_MAC_APP_STORE: u32 = 6;

pub const CS_ADHOC: u32 = 0x2;
pub const CS_LINKER_SIGNED: u32 = 0x20000;

pub const CS_EXECSEG_MAIN_BINARY: u32 = 0x1;

/// This CodeDirectory is tailored specfically at version 0x20400.
pub const CodeDirectory = extern struct {
    /// Magic number (CSMAGIC_CODEDIRECTORY)
    magic: u32,

    /// Total length of CodeDirectory blob
    length: u32,

    /// Compatibility version
    version: u32,

    /// Setup and mode flags
    flags: u32,

    /// Offset of hash slot element at index zero
    hashOffset: u32,

    /// Offset of identifier string
    identOffset: u32,

    /// Number of special hash slots
    nSpecialSlots: u32,

    /// Number of ordinary (code) hash slots
    nCodeSlots: u32,

    /// Limit to main image signature range
    codeLimit: u32,

    /// Size of each hash in bytes
    hashSize: u8,

    /// Type of hash (cdHashType* constants)
    hashType: u8,

    /// Platform identifier; zero if not platform binary
    platform: u8,

    /// log2(page size in bytes); 0 => infinite
    pageSize: u8,

    /// Unused (must be zero)
    spare2: u32,

    ///
    scatterOffset: u32,

    ///
    teamOffset: u32,

    ///
    spare3: u32,

    ///
    codeLimit64: u64,

    /// Offset of executable segment
    execSegBase: u64,

    /// Limit of executable segment
    execSegLimit: u64,

    /// Executable segment flags
    execSegFlags: u64,
};

/// Structure of an embedded-signature SuperBlob
pub const BlobIndex = extern struct {
    /// Type of entry
    @"type": u32,

    /// Offset of entry
    offset: u32,
};

/// This structure is followed by GenericBlobs in no particular
/// order as indicated by offsets in index
pub const SuperBlob = extern struct {
    /// Magic number
    magic: u32,

    /// Total length of SuperBlob
    length: u32,

    /// Number of index BlobIndex entries following this struct
    count: u32,
};

pub const GenericBlob = extern struct {
    /// Magic number
    magic: u32,

    /// Total length of blob
    length: u32,
};

/// The LC_DATA_IN_CODE load commands uses a linkedit_data_command
/// to point to an array of data_in_code_entry entries. Each entry
/// describes a range of data in a code section.
pub const data_in_code_entry = extern struct {
    /// From mach_header to start of data range.
    offset: u32,

    /// Number of bytes in data range.
    length: u16,

    /// A DICE_KIND value.
    kind: u16,
};

pub const LoadCommandIterator = struct {
    ncmds: usize,
    buffer: []align(@alignOf(u64)) const u8,
    index: usize = 0,

    pub const LoadCommand = struct {
        hdr: load_command,
        data: []const u8,

        pub fn cmd(lc: LoadCommand) LC {
            return lc.hdr.cmd;
        }

        pub fn cmdsize(lc: LoadCommand) u32 {
            return lc.hdr.cmdsize;
        }

        pub fn cast(lc: LoadCommand, comptime Cmd: type) ?Cmd {
            if (lc.data.len < @sizeOf(Cmd)) return null;
            return @ptrCast(*const Cmd, @alignCast(@alignOf(Cmd), &lc.data[0])).*;
        }

        /// Asserts LoadCommand is of type segment_command_64.
        pub fn getSections(lc: LoadCommand) []const section_64 {
            const segment_lc = lc.cast(segment_command_64).?;
            if (segment_lc.nsects == 0) return &[0]section_64{};
            const data = lc.data[@sizeOf(segment_command_64)..];
            const sections = @ptrCast(
                [*]const section_64,
                @alignCast(@alignOf(section_64), &data[0]),
            )[0..segment_lc.nsects];
            return sections;
        }

        /// Asserts LoadCommand is of type dylib_command.
        pub fn getDylibPathName(lc: LoadCommand) []const u8 {
            const dylib_lc = lc.cast(dylib_command).?;
            const data = lc.data[dylib_lc.dylib.name..];
            return mem.sliceTo(data, 0);
        }

        /// Asserts LoadCommand is of type rpath_command.
        pub fn getRpathPathName(lc: LoadCommand) []const u8 {
            const rpath_lc = lc.cast(rpath_command).?;
            const data = lc.data[rpath_lc.path..];
            return mem.sliceTo(data, 0);
        }
    };

    pub fn next(it: *LoadCommandIterator) ?LoadCommand {
        if (it.index >= it.ncmds) return null;

        const hdr = @ptrCast(
            *const load_command,
            @alignCast(@alignOf(load_command), &it.buffer[0]),
        ).*;
        const cmd = LoadCommand{
            .hdr = hdr,
            .data = it.buffer[0..hdr.cmdsize],
        };

        it.buffer = @alignCast(@alignOf(u64), it.buffer[hdr.cmdsize..]);
        it.index += 1;

        return cmd;
    }
};