zig/lib/std/pdb.zig
Jakub Konka 070282a96e libstd: fix off-by-one error in def of ProcSym in pdb
Make sure `ProcSym` includes a single element byte-array which delimits
the start of the symbol's name as part of its definition. This makes
the code more elegant in that accessing the name is equivalent to taking
the address of this one element array.
2022-08-17 16:36:02 -04:00

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const std = @import("std.zig");
const io = std.io;
const math = std.math;
const mem = std.mem;
const os = std.os;
const coff = std.coff;
const fs = std.fs;
const File = std.fs.File;
const debug = std.debug;
const ArrayList = std.ArrayList;
// Note: most of this is based on information gathered from LLVM source code,
// documentation and/or contributors.
// https://llvm.org/docs/PDB/DbiStream.html#stream-header
pub const DbiStreamHeader = extern struct {
VersionSignature: i32,
VersionHeader: u32,
Age: u32,
GlobalStreamIndex: u16,
BuildNumber: u16,
PublicStreamIndex: u16,
PdbDllVersion: u16,
SymRecordStream: u16,
PdbDllRbld: u16,
ModInfoSize: u32,
SectionContributionSize: u32,
SectionMapSize: u32,
SourceInfoSize: i32,
TypeServerSize: i32,
MFCTypeServerIndex: u32,
OptionalDbgHeaderSize: i32,
ECSubstreamSize: i32,
Flags: u16,
Machine: u16,
Padding: u32,
};
pub const SectionContribEntry = extern struct {
/// COFF Section index, 1-based
Section: u16,
Padding1: [2]u8,
Offset: u32,
Size: u32,
Characteristics: u32,
ModuleIndex: u16,
Padding2: [2]u8,
DataCrc: u32,
RelocCrc: u32,
};
pub const ModInfo = extern struct {
Unused1: u32,
SectionContr: SectionContribEntry,
Flags: u16,
ModuleSymStream: u16,
SymByteSize: u32,
C11ByteSize: u32,
C13ByteSize: u32,
SourceFileCount: u16,
Padding: [2]u8,
Unused2: u32,
SourceFileNameIndex: u32,
PdbFilePathNameIndex: u32,
// These fields are variable length
//ModuleName: char[],
//ObjFileName: char[],
};
pub const SectionMapHeader = extern struct {
/// Number of segment descriptors
Count: u16,
/// Number of logical segment descriptors
LogCount: u16,
};
pub const SectionMapEntry = extern struct {
/// See the SectionMapEntryFlags enum below.
Flags: u16,
/// Logical overlay number
Ovl: u16,
/// Group index into descriptor array.
Group: u16,
Frame: u16,
/// Byte index of segment / group name in string table, or 0xFFFF.
SectionName: u16,
/// Byte index of class in string table, or 0xFFFF.
ClassName: u16,
/// Byte offset of the logical segment within physical segment. If group is set in flags, this is the offset of the group.
Offset: u32,
/// Byte count of the segment or group.
SectionLength: u32,
};
pub const StreamType = enum(u16) {
Pdb = 1,
Tpi = 2,
Dbi = 3,
Ipi = 4,
};
/// Duplicate copy of SymbolRecordKind, but using the official CV names. Useful
/// for reference purposes and when dealing with unknown record types.
pub const SymbolKind = enum(u16) {
S_COMPILE = 1,
S_REGISTER_16t = 2,
S_CONSTANT_16t = 3,
S_UDT_16t = 4,
S_SSEARCH = 5,
S_SKIP = 7,
S_CVRESERVE = 8,
S_OBJNAME_ST = 9,
S_ENDARG = 10,
S_COBOLUDT_16t = 11,
S_MANYREG_16t = 12,
S_RETURN = 13,
S_ENTRYTHIS = 14,
S_BPREL16 = 256,
S_LDATA16 = 257,
S_GDATA16 = 258,
S_PUB16 = 259,
S_LPROC16 = 260,
S_GPROC16 = 261,
S_THUNK16 = 262,
S_BLOCK16 = 263,
S_WITH16 = 264,
S_LABEL16 = 265,
S_CEXMODEL16 = 266,
S_VFTABLE16 = 267,
S_REGREL16 = 268,
S_BPREL32_16t = 512,
S_LDATA32_16t = 513,
S_GDATA32_16t = 514,
S_PUB32_16t = 515,
S_LPROC32_16t = 516,
S_GPROC32_16t = 517,
S_THUNK32_ST = 518,
S_BLOCK32_ST = 519,
S_WITH32_ST = 520,
S_LABEL32_ST = 521,
S_CEXMODEL32 = 522,
S_VFTABLE32_16t = 523,
S_REGREL32_16t = 524,
S_LTHREAD32_16t = 525,
S_GTHREAD32_16t = 526,
S_SLINK32 = 527,
S_LPROCMIPS_16t = 768,
S_GPROCMIPS_16t = 769,
S_PROCREF_ST = 1024,
S_DATAREF_ST = 1025,
S_ALIGN = 1026,
S_LPROCREF_ST = 1027,
S_OEM = 1028,
S_TI16_MAX = 4096,
S_REGISTER_ST = 4097,
S_CONSTANT_ST = 4098,
S_UDT_ST = 4099,
S_COBOLUDT_ST = 4100,
S_MANYREG_ST = 4101,
S_BPREL32_ST = 4102,
S_LDATA32_ST = 4103,
S_GDATA32_ST = 4104,
S_PUB32_ST = 4105,
S_LPROC32_ST = 4106,
S_GPROC32_ST = 4107,
S_VFTABLE32 = 4108,
S_REGREL32_ST = 4109,
S_LTHREAD32_ST = 4110,
S_GTHREAD32_ST = 4111,
S_LPROCMIPS_ST = 4112,
S_GPROCMIPS_ST = 4113,
S_COMPILE2_ST = 4115,
S_MANYREG2_ST = 4116,
S_LPROCIA64_ST = 4117,
S_GPROCIA64_ST = 4118,
S_LOCALSLOT_ST = 4119,
S_PARAMSLOT_ST = 4120,
S_ANNOTATION = 4121,
S_GMANPROC_ST = 4122,
S_LMANPROC_ST = 4123,
S_RESERVED1 = 4124,
S_RESERVED2 = 4125,
S_RESERVED3 = 4126,
S_RESERVED4 = 4127,
S_LMANDATA_ST = 4128,
S_GMANDATA_ST = 4129,
S_MANFRAMEREL_ST = 4130,
S_MANREGISTER_ST = 4131,
S_MANSLOT_ST = 4132,
S_MANMANYREG_ST = 4133,
S_MANREGREL_ST = 4134,
S_MANMANYREG2_ST = 4135,
S_MANTYPREF = 4136,
S_UNAMESPACE_ST = 4137,
S_ST_MAX = 4352,
S_WITH32 = 4356,
S_MANYREG = 4362,
S_LPROCMIPS = 4372,
S_GPROCMIPS = 4373,
S_MANYREG2 = 4375,
S_LPROCIA64 = 4376,
S_GPROCIA64 = 4377,
S_LOCALSLOT = 4378,
S_PARAMSLOT = 4379,
S_MANFRAMEREL = 4382,
S_MANREGISTER = 4383,
S_MANSLOT = 4384,
S_MANMANYREG = 4385,
S_MANREGREL = 4386,
S_MANMANYREG2 = 4387,
S_UNAMESPACE = 4388,
S_DATAREF = 4390,
S_ANNOTATIONREF = 4392,
S_TOKENREF = 4393,
S_GMANPROC = 4394,
S_LMANPROC = 4395,
S_ATTR_FRAMEREL = 4398,
S_ATTR_REGISTER = 4399,
S_ATTR_REGREL = 4400,
S_ATTR_MANYREG = 4401,
S_SEPCODE = 4402,
S_LOCAL_2005 = 4403,
S_DEFRANGE_2005 = 4404,
S_DEFRANGE2_2005 = 4405,
S_DISCARDED = 4411,
S_LPROCMIPS_ID = 4424,
S_GPROCMIPS_ID = 4425,
S_LPROCIA64_ID = 4426,
S_GPROCIA64_ID = 4427,
S_DEFRANGE_HLSL = 4432,
S_GDATA_HLSL = 4433,
S_LDATA_HLSL = 4434,
S_LOCAL_DPC_GROUPSHARED = 4436,
S_DEFRANGE_DPC_PTR_TAG = 4439,
S_DPC_SYM_TAG_MAP = 4440,
S_ARMSWITCHTABLE = 4441,
S_POGODATA = 4444,
S_INLINESITE2 = 4445,
S_MOD_TYPEREF = 4447,
S_REF_MINIPDB = 4448,
S_PDBMAP = 4449,
S_GDATA_HLSL32 = 4450,
S_LDATA_HLSL32 = 4451,
S_GDATA_HLSL32_EX = 4452,
S_LDATA_HLSL32_EX = 4453,
S_FASTLINK = 4455,
S_INLINEES = 4456,
S_END = 6,
S_INLINESITE_END = 4430,
S_PROC_ID_END = 4431,
S_THUNK32 = 4354,
S_TRAMPOLINE = 4396,
S_SECTION = 4406,
S_COFFGROUP = 4407,
S_EXPORT = 4408,
S_LPROC32 = 4367,
S_GPROC32 = 4368,
S_LPROC32_ID = 4422,
S_GPROC32_ID = 4423,
S_LPROC32_DPC = 4437,
S_LPROC32_DPC_ID = 4438,
S_REGISTER = 4358,
S_PUB32 = 4366,
S_PROCREF = 4389,
S_LPROCREF = 4391,
S_ENVBLOCK = 4413,
S_INLINESITE = 4429,
S_LOCAL = 4414,
S_DEFRANGE = 4415,
S_DEFRANGE_SUBFIELD = 4416,
S_DEFRANGE_REGISTER = 4417,
S_DEFRANGE_FRAMEPOINTER_REL = 4418,
S_DEFRANGE_SUBFIELD_REGISTER = 4419,
S_DEFRANGE_FRAMEPOINTER_REL_FULL_SCOPE = 4420,
S_DEFRANGE_REGISTER_REL = 4421,
S_BLOCK32 = 4355,
S_LABEL32 = 4357,
S_OBJNAME = 4353,
S_COMPILE2 = 4374,
S_COMPILE3 = 4412,
S_FRAMEPROC = 4114,
S_CALLSITEINFO = 4409,
S_FILESTATIC = 4435,
S_HEAPALLOCSITE = 4446,
S_FRAMECOOKIE = 4410,
S_CALLEES = 4442,
S_CALLERS = 4443,
S_UDT = 4360,
S_COBOLUDT = 4361,
S_BUILDINFO = 4428,
S_BPREL32 = 4363,
S_REGREL32 = 4369,
S_CONSTANT = 4359,
S_MANCONSTANT = 4397,
S_LDATA32 = 4364,
S_GDATA32 = 4365,
S_LMANDATA = 4380,
S_GMANDATA = 4381,
S_LTHREAD32 = 4370,
S_GTHREAD32 = 4371,
};
pub const TypeIndex = u32;
// TODO According to this header:
// https://github.com/microsoft/microsoft-pdb/blob/082c5290e5aff028ae84e43affa8be717aa7af73/include/cvinfo.h#L3722
// we should define RecordPrefix as part of the ProcSym structure.
// This might be important when we start generating PDB in self-hosted with our own PE linker.
pub const ProcSym = extern struct {
Parent: u32,
End: u32,
Next: u32,
CodeSize: u32,
DbgStart: u32,
DbgEnd: u32,
FunctionType: TypeIndex,
CodeOffset: u32,
Segment: u16,
Flags: ProcSymFlags,
Name: [1]u8, // null-terminated
};
pub const ProcSymFlags = packed struct {
HasFP: bool,
HasIRET: bool,
HasFRET: bool,
IsNoReturn: bool,
IsUnreachable: bool,
HasCustomCallingConv: bool,
IsNoInline: bool,
HasOptimizedDebugInfo: bool,
};
pub const SectionContrSubstreamVersion = enum(u32) {
Ver60 = 0xeffe0000 + 19970605,
V2 = 0xeffe0000 + 20140516,
_,
};
pub const RecordPrefix = extern struct {
/// Record length, starting from &RecordKind.
RecordLen: u16,
/// Record kind enum (SymRecordKind or TypeRecordKind)
RecordKind: SymbolKind,
};
/// The following variable length array appears immediately after the header.
/// The structure definition follows.
/// LineBlockFragmentHeader Blocks[]
/// Each `LineBlockFragmentHeader` as specified below.
pub const LineFragmentHeader = extern struct {
/// Code offset of line contribution.
RelocOffset: u32,
/// Code segment of line contribution.
RelocSegment: u16,
Flags: LineFlags,
/// Code size of this line contribution.
CodeSize: u32,
};
pub const LineFlags = packed struct {
/// CV_LINES_HAVE_COLUMNS
LF_HaveColumns: bool,
unused: u15,
};
/// The following two variable length arrays appear immediately after the
/// header. The structure definitions follow.
/// LineNumberEntry Lines[NumLines];
/// ColumnNumberEntry Columns[NumLines];
pub const LineBlockFragmentHeader = extern struct {
/// Offset of FileChecksum entry in File
/// checksums buffer. The checksum entry then
/// contains another offset into the string
/// table of the actual name.
NameIndex: u32,
NumLines: u32,
/// code size of block, in bytes
BlockSize: u32,
};
pub const LineNumberEntry = extern struct {
/// Offset to start of code bytes for line number
Offset: u32,
Flags: u32,
/// TODO runtime crash when I make the actual type of Flags this
pub const Flags = packed struct {
/// Start line number
Start: u24,
/// Delta of lines to the end of the expression. Still unclear.
// TODO figure out the point of this field.
End: u7,
IsStatement: bool,
};
};
pub const ColumnNumberEntry = extern struct {
StartColumn: u16,
EndColumn: u16,
};
/// Checksum bytes follow.
pub const FileChecksumEntryHeader = extern struct {
/// Byte offset of filename in global string table.
FileNameOffset: u32,
/// Number of bytes of checksum.
ChecksumSize: u8,
/// FileChecksumKind
ChecksumKind: u8,
};
pub const DebugSubsectionKind = enum(u32) {
None = 0,
Symbols = 0xf1,
Lines = 0xf2,
StringTable = 0xf3,
FileChecksums = 0xf4,
FrameData = 0xf5,
InlineeLines = 0xf6,
CrossScopeImports = 0xf7,
CrossScopeExports = 0xf8,
// These appear to relate to .Net assembly info.
ILLines = 0xf9,
FuncMDTokenMap = 0xfa,
TypeMDTokenMap = 0xfb,
MergedAssemblyInput = 0xfc,
CoffSymbolRVA = 0xfd,
};
pub const DebugSubsectionHeader = extern struct {
/// codeview::DebugSubsectionKind enum
Kind: DebugSubsectionKind,
/// number of bytes occupied by this record.
Length: u32,
};
pub const PDBStringTableHeader = extern struct {
/// PDBStringTableSignature
Signature: u32,
/// 1 or 2
HashVersion: u32,
/// Number of bytes of names buffer.
ByteSize: u32,
};
fn readSparseBitVector(stream: anytype, allocator: mem.Allocator) ![]u32 {
const num_words = try stream.readIntLittle(u32);
var list = ArrayList(u32).init(allocator);
errdefer list.deinit();
var word_i: u32 = 0;
while (word_i != num_words) : (word_i += 1) {
const word = try stream.readIntLittle(u32);
var bit_i: u5 = 0;
while (true) : (bit_i += 1) {
if (word & (@as(u32, 1) << bit_i) != 0) {
try list.append(word_i * 32 + bit_i);
}
if (bit_i == std.math.maxInt(u5)) break;
}
}
return list.toOwnedSlice();
}
pub const Pdb = struct {
in_file: File,
msf: Msf,
allocator: mem.Allocator,
string_table: ?*MsfStream,
dbi: ?*MsfStream,
modules: []Module,
sect_contribs: []SectionContribEntry,
guid: [16]u8,
age: u32,
pub const Module = struct {
mod_info: ModInfo,
module_name: []u8,
obj_file_name: []u8,
// The fields below are filled on demand.
populated: bool,
symbols: []u8,
subsect_info: []u8,
checksum_offset: ?usize,
pub fn deinit(self: *Module, allocator: mem.Allocator) void {
allocator.free(self.module_name);
allocator.free(self.obj_file_name);
if (self.populated) {
allocator.free(self.symbols);
allocator.free(self.subsect_info);
}
}
};
pub fn init(allocator: mem.Allocator, path: []const u8) !Pdb {
const file = try fs.cwd().openFile(path, .{ .intended_io_mode = .blocking });
errdefer file.close();
return Pdb{
.in_file = file,
.allocator = allocator,
.string_table = null,
.dbi = null,
.msf = try Msf.init(allocator, file),
.modules = &[_]Module{},
.sect_contribs = &[_]SectionContribEntry{},
.guid = undefined,
.age = undefined,
};
}
pub fn deinit(self: *Pdb) void {
self.in_file.close();
self.msf.deinit(self.allocator);
for (self.modules) |*module| {
module.deinit(self.allocator);
}
self.allocator.free(self.modules);
self.allocator.free(self.sect_contribs);
}
pub fn parseDbiStream(self: *Pdb) !void {
var stream = self.getStream(StreamType.Dbi) orelse
return error.InvalidDebugInfo;
const reader = stream.reader();
const header = try reader.readStruct(DbiStreamHeader);
if (header.VersionHeader != 19990903) // V70, only value observed by LLVM team
return error.UnknownPDBVersion;
// if (header.Age != age)
// return error.UnmatchingPDB;
const mod_info_size = header.ModInfoSize;
const section_contrib_size = header.SectionContributionSize;
var modules = ArrayList(Module).init(self.allocator);
errdefer modules.deinit();
// Module Info Substream
var mod_info_offset: usize = 0;
while (mod_info_offset != mod_info_size) {
const mod_info = try reader.readStruct(ModInfo);
var this_record_len: usize = @sizeOf(ModInfo);
const module_name = try reader.readUntilDelimiterAlloc(self.allocator, 0, 1024);
errdefer self.allocator.free(module_name);
this_record_len += module_name.len + 1;
const obj_file_name = try reader.readUntilDelimiterAlloc(self.allocator, 0, 1024);
errdefer self.allocator.free(obj_file_name);
this_record_len += obj_file_name.len + 1;
if (this_record_len % 4 != 0) {
const round_to_next_4 = (this_record_len | 0x3) + 1;
const march_forward_bytes = round_to_next_4 - this_record_len;
try stream.seekBy(@intCast(isize, march_forward_bytes));
this_record_len += march_forward_bytes;
}
try modules.append(Module{
.mod_info = mod_info,
.module_name = module_name,
.obj_file_name = obj_file_name,
.populated = false,
.symbols = undefined,
.subsect_info = undefined,
.checksum_offset = null,
});
mod_info_offset += this_record_len;
if (mod_info_offset > mod_info_size)
return error.InvalidDebugInfo;
}
// Section Contribution Substream
var sect_contribs = ArrayList(SectionContribEntry).init(self.allocator);
errdefer sect_contribs.deinit();
var sect_cont_offset: usize = 0;
if (section_contrib_size != 0) {
const version = reader.readEnum(SectionContrSubstreamVersion, .Little) catch |err| switch (err) {
error.InvalidValue => return error.InvalidDebugInfo,
else => |e| return e,
};
_ = version;
sect_cont_offset += @sizeOf(u32);
}
while (sect_cont_offset != section_contrib_size) {
const entry = try sect_contribs.addOne();
entry.* = try reader.readStruct(SectionContribEntry);
sect_cont_offset += @sizeOf(SectionContribEntry);
if (sect_cont_offset > section_contrib_size)
return error.InvalidDebugInfo;
}
self.modules = modules.toOwnedSlice();
self.sect_contribs = sect_contribs.toOwnedSlice();
}
pub fn parseInfoStream(self: *Pdb) !void {
var stream = self.getStream(StreamType.Pdb) orelse
return error.InvalidDebugInfo;
const reader = stream.reader();
// Parse the InfoStreamHeader.
const version = try reader.readIntLittle(u32);
const signature = try reader.readIntLittle(u32);
_ = signature;
const age = try reader.readIntLittle(u32);
const guid = try reader.readBytesNoEof(16);
if (version != 20000404) // VC70, only value observed by LLVM team
return error.UnknownPDBVersion;
self.guid = guid;
self.age = age;
// Find the string table.
const string_table_index = str_tab_index: {
const name_bytes_len = try reader.readIntLittle(u32);
const name_bytes = try self.allocator.alloc(u8, name_bytes_len);
defer self.allocator.free(name_bytes);
try reader.readNoEof(name_bytes);
const HashTableHeader = extern struct {
Size: u32,
Capacity: u32,
fn maxLoad(cap: u32) u32 {
return cap * 2 / 3 + 1;
}
};
const hash_tbl_hdr = try reader.readStruct(HashTableHeader);
if (hash_tbl_hdr.Capacity == 0)
return error.InvalidDebugInfo;
if (hash_tbl_hdr.Size > HashTableHeader.maxLoad(hash_tbl_hdr.Capacity))
return error.InvalidDebugInfo;
const present = try readSparseBitVector(&reader, self.allocator);
defer self.allocator.free(present);
if (present.len != hash_tbl_hdr.Size)
return error.InvalidDebugInfo;
const deleted = try readSparseBitVector(&reader, self.allocator);
defer self.allocator.free(deleted);
for (present) |_| {
const name_offset = try reader.readIntLittle(u32);
const name_index = try reader.readIntLittle(u32);
if (name_offset > name_bytes.len)
return error.InvalidDebugInfo;
const name = mem.sliceTo(std.meta.assumeSentinel(name_bytes.ptr + name_offset, 0), 0);
if (mem.eql(u8, name, "/names")) {
break :str_tab_index name_index;
}
}
return error.MissingDebugInfo;
};
self.string_table = self.getStreamById(string_table_index) orelse
return error.MissingDebugInfo;
}
pub fn getSymbolName(self: *Pdb, module: *Module, address: u64) ?[]const u8 {
_ = self;
std.debug.assert(module.populated);
var symbol_i: usize = 0;
while (symbol_i != module.symbols.len) {
const prefix = @ptrCast(*align(1) RecordPrefix, &module.symbols[symbol_i]);
if (prefix.RecordLen < 2)
return null;
switch (prefix.RecordKind) {
.S_LPROC32, .S_GPROC32 => {
const proc_sym = @ptrCast(*align(1) ProcSym, &module.symbols[symbol_i + @sizeOf(RecordPrefix)]);
if (address >= proc_sym.CodeOffset and address < proc_sym.CodeOffset + proc_sym.CodeSize) {
return mem.sliceTo(@ptrCast([*:0]u8, &proc_sym.Name[0]), 0);
}
},
else => {},
}
symbol_i += prefix.RecordLen + @sizeOf(u16);
}
return null;
}
pub fn getLineNumberInfo(self: *Pdb, module: *Module, address: u64) !debug.LineInfo {
std.debug.assert(module.populated);
const subsect_info = module.subsect_info;
var sect_offset: usize = 0;
var skip_len: usize = undefined;
const checksum_offset = module.checksum_offset orelse return error.MissingDebugInfo;
while (sect_offset != subsect_info.len) : (sect_offset += skip_len) {
const subsect_hdr = @ptrCast(*align(1) DebugSubsectionHeader, &subsect_info[sect_offset]);
skip_len = subsect_hdr.Length;
sect_offset += @sizeOf(DebugSubsectionHeader);
switch (subsect_hdr.Kind) {
.Lines => {
var line_index = sect_offset;
const line_hdr = @ptrCast(*align(1) LineFragmentHeader, &subsect_info[line_index]);
if (line_hdr.RelocSegment == 0)
return error.MissingDebugInfo;
line_index += @sizeOf(LineFragmentHeader);
const frag_vaddr_start = line_hdr.RelocOffset;
const frag_vaddr_end = frag_vaddr_start + line_hdr.CodeSize;
if (address >= frag_vaddr_start and address < frag_vaddr_end) {
// There is an unknown number of LineBlockFragmentHeaders (and their accompanying line and column records)
// from now on. We will iterate through them, and eventually find a LineInfo that we're interested in,
// breaking out to :subsections. If not, we will make sure to not read anything outside of this subsection.
const subsection_end_index = sect_offset + subsect_hdr.Length;
while (line_index < subsection_end_index) {
const block_hdr = @ptrCast(*align(1) LineBlockFragmentHeader, &subsect_info[line_index]);
line_index += @sizeOf(LineBlockFragmentHeader);
const start_line_index = line_index;
const has_column = line_hdr.Flags.LF_HaveColumns;
// All line entries are stored inside their line block by ascending start address.
// Heuristic: we want to find the last line entry
// that has a vaddr_start <= address.
// This is done with a simple linear search.
var line_i: u32 = 0;
while (line_i < block_hdr.NumLines) : (line_i += 1) {
const line_num_entry = @ptrCast(*align(1) LineNumberEntry, &subsect_info[line_index]);
line_index += @sizeOf(LineNumberEntry);
const vaddr_start = frag_vaddr_start + line_num_entry.Offset;
if (address < vaddr_start) {
break;
}
}
// line_i == 0 would mean that no matching LineNumberEntry was found.
if (line_i > 0) {
const subsect_index = checksum_offset + block_hdr.NameIndex;
const chksum_hdr = @ptrCast(*align(1) FileChecksumEntryHeader, &module.subsect_info[subsect_index]);
const strtab_offset = @sizeOf(PDBStringTableHeader) + chksum_hdr.FileNameOffset;
try self.string_table.?.seekTo(strtab_offset);
const source_file_name = try self.string_table.?.reader().readUntilDelimiterAlloc(self.allocator, 0, 1024);
const line_entry_idx = line_i - 1;
const column = if (has_column) blk: {
const start_col_index = start_line_index + @sizeOf(LineNumberEntry) * block_hdr.NumLines;
const col_index = start_col_index + @sizeOf(ColumnNumberEntry) * line_entry_idx;
const col_num_entry = @ptrCast(*align(1) ColumnNumberEntry, &subsect_info[col_index]);
break :blk col_num_entry.StartColumn;
} else 0;
const found_line_index = start_line_index + line_entry_idx * @sizeOf(LineNumberEntry);
const line_num_entry = @ptrCast(*align(1) LineNumberEntry, &subsect_info[found_line_index]);
const flags = @ptrCast(*LineNumberEntry.Flags, &line_num_entry.Flags);
return debug.LineInfo{
.file_name = source_file_name,
.line = flags.Start,
.column = column,
};
}
}
// Checking that we are not reading garbage after the (possibly) multiple block fragments.
if (line_index != subsection_end_index) {
return error.InvalidDebugInfo;
}
}
},
else => {},
}
if (sect_offset > subsect_info.len)
return error.InvalidDebugInfo;
}
return error.MissingDebugInfo;
}
pub fn getModule(self: *Pdb, index: usize) !?*Module {
if (index >= self.modules.len)
return null;
const mod = &self.modules[index];
if (mod.populated)
return mod;
// At most one can be non-zero.
if (mod.mod_info.C11ByteSize != 0 and mod.mod_info.C13ByteSize != 0)
return error.InvalidDebugInfo;
if (mod.mod_info.C13ByteSize == 0)
return error.InvalidDebugInfo;
const stream = self.getStreamById(mod.mod_info.ModuleSymStream) orelse
return error.MissingDebugInfo;
const reader = stream.reader();
const signature = try reader.readIntLittle(u32);
if (signature != 4)
return error.InvalidDebugInfo;
mod.symbols = try self.allocator.alloc(u8, mod.mod_info.SymByteSize - 4);
errdefer self.allocator.free(mod.symbols);
try reader.readNoEof(mod.symbols);
mod.subsect_info = try self.allocator.alloc(u8, mod.mod_info.C13ByteSize);
errdefer self.allocator.free(mod.subsect_info);
try reader.readNoEof(mod.subsect_info);
var sect_offset: usize = 0;
var skip_len: usize = undefined;
while (sect_offset != mod.subsect_info.len) : (sect_offset += skip_len) {
const subsect_hdr = @ptrCast(*align(1) DebugSubsectionHeader, &mod.subsect_info[sect_offset]);
skip_len = subsect_hdr.Length;
sect_offset += @sizeOf(DebugSubsectionHeader);
switch (subsect_hdr.Kind) {
.FileChecksums => {
mod.checksum_offset = sect_offset;
break;
},
else => {},
}
if (sect_offset > mod.subsect_info.len)
return error.InvalidDebugInfo;
}
mod.populated = true;
return mod;
}
pub fn getStreamById(self: *Pdb, id: u32) ?*MsfStream {
if (id >= self.msf.streams.len)
return null;
return &self.msf.streams[id];
}
pub fn getStream(self: *Pdb, stream: StreamType) ?*MsfStream {
const id = @enumToInt(stream);
return self.getStreamById(id);
}
};
// see https://llvm.org/docs/PDB/MsfFile.html
const Msf = struct {
directory: MsfStream,
streams: []MsfStream,
fn init(allocator: mem.Allocator, file: File) !Msf {
const in = file.reader();
const superblock = try in.readStruct(SuperBlock);
// Sanity checks
if (!mem.eql(u8, &superblock.FileMagic, SuperBlock.file_magic))
return error.InvalidDebugInfo;
if (superblock.FreeBlockMapBlock != 1 and superblock.FreeBlockMapBlock != 2)
return error.InvalidDebugInfo;
const file_len = try file.getEndPos();
if (superblock.NumBlocks * superblock.BlockSize != file_len)
return error.InvalidDebugInfo;
switch (superblock.BlockSize) {
// llvm only supports 4096 but we can handle any of these values
512, 1024, 2048, 4096 => {},
else => return error.InvalidDebugInfo,
}
const dir_block_count = blockCountFromSize(superblock.NumDirectoryBytes, superblock.BlockSize);
if (dir_block_count > superblock.BlockSize / @sizeOf(u32))
return error.UnhandledBigDirectoryStream; // cf. BlockMapAddr comment.
try file.seekTo(superblock.BlockSize * superblock.BlockMapAddr);
var dir_blocks = try allocator.alloc(u32, dir_block_count);
for (dir_blocks) |*b| {
b.* = try in.readIntLittle(u32);
}
var directory = MsfStream.init(
superblock.BlockSize,
file,
dir_blocks,
);
const begin = directory.pos;
const stream_count = try directory.reader().readIntLittle(u32);
const stream_sizes = try allocator.alloc(u32, stream_count);
defer allocator.free(stream_sizes);
// Microsoft's implementation uses @as(u32, -1) for inexistant streams.
// These streams are not used, but still participate in the file
// and must be taken into account when resolving stream indices.
const Nil = 0xFFFFFFFF;
for (stream_sizes) |*s| {
const size = try directory.reader().readIntLittle(u32);
s.* = if (size == Nil) 0 else blockCountFromSize(size, superblock.BlockSize);
}
const streams = try allocator.alloc(MsfStream, stream_count);
for (streams) |*stream, i| {
const size = stream_sizes[i];
if (size == 0) {
stream.* = MsfStream{
.blocks = &[_]u32{},
};
} else {
var blocks = try allocator.alloc(u32, size);
var j: u32 = 0;
while (j < size) : (j += 1) {
const block_id = try directory.reader().readIntLittle(u32);
const n = (block_id % superblock.BlockSize);
// 0 is for SuperBlock, 1 and 2 for FPMs.
if (block_id == 0 or n == 1 or n == 2 or block_id * superblock.BlockSize > file_len)
return error.InvalidBlockIndex;
blocks[j] = block_id;
}
stream.* = MsfStream.init(
superblock.BlockSize,
file,
blocks,
);
}
}
const end = directory.pos;
if (end - begin != superblock.NumDirectoryBytes)
return error.InvalidStreamDirectory;
return Msf{
.directory = directory,
.streams = streams,
};
}
fn deinit(self: *Msf, allocator: mem.Allocator) void {
allocator.free(self.directory.blocks);
for (self.streams) |*stream| {
allocator.free(stream.blocks);
}
allocator.free(self.streams);
}
};
fn blockCountFromSize(size: u32, block_size: u32) u32 {
return (size + block_size - 1) / block_size;
}
// https://llvm.org/docs/PDB/MsfFile.html#the-superblock
const SuperBlock = extern struct {
/// The LLVM docs list a space between C / C++ but empirically this is not the case.
const file_magic = "Microsoft C/C++ MSF 7.00\r\n\x1a\x44\x53\x00\x00\x00";
FileMagic: [file_magic.len]u8,
/// The block size of the internal file system. Valid values are 512, 1024,
/// 2048, and 4096 bytes. Certain aspects of the MSF file layout vary depending
/// on the block sizes. For the purposes of LLVM, we handle only block sizes of
/// 4KiB, and all further discussion assumes a block size of 4KiB.
BlockSize: u32,
/// The index of a block within the file, at which begins a bitfield representing
/// the set of all blocks within the file which are “free” (i.e. the data within
/// that block is not used). See The Free Block Map for more information. Important:
/// FreeBlockMapBlock can only be 1 or 2!
FreeBlockMapBlock: u32,
/// The total number of blocks in the file. NumBlocks * BlockSize should equal the
/// size of the file on disk.
NumBlocks: u32,
/// The size of the stream directory, in bytes. The stream directory contains
/// information about each streams size and the set of blocks that it occupies.
/// It will be described in more detail later.
NumDirectoryBytes: u32,
Unknown: u32,
/// The index of a block within the MSF file. At this block is an array of
/// ulittle32_ts listing the blocks that the stream directory resides on.
/// For large MSF files, the stream directory (which describes the block
/// layout of each stream) may not fit entirely on a single block. As a
/// result, this extra layer of indirection is introduced, whereby this
/// block contains the list of blocks that the stream directory occupies,
/// and the stream directory itself can be stitched together accordingly.
/// The number of ulittle32_ts in this array is given by
/// ceil(NumDirectoryBytes / BlockSize).
// Note: microsoft-pdb code actually suggests this is a variable-length
// array. If the indices of blocks occupied by the Stream Directory didn't
// fit in one page, there would be other u32 following it.
// This would mean the Stream Directory is bigger than BlockSize / sizeof(u32)
// blocks. We're not even close to this with a 1GB pdb file, and LLVM didn't
// implement it so we're kind of safe making this assumption for now.
BlockMapAddr: u32,
};
const MsfStream = struct {
in_file: File = undefined,
pos: u64 = undefined,
blocks: []u32 = undefined,
block_size: u32 = undefined,
pub const Error = @typeInfo(@typeInfo(@TypeOf(read)).Fn.return_type.?).ErrorUnion.error_set;
fn init(block_size: u32, file: File, blocks: []u32) MsfStream {
const stream = MsfStream{
.in_file = file,
.pos = 0,
.blocks = blocks,
.block_size = block_size,
};
return stream;
}
fn read(self: *MsfStream, buffer: []u8) !usize {
var block_id = @intCast(usize, self.pos / self.block_size);
if (block_id >= self.blocks.len) return 0; // End of Stream
var block = self.blocks[block_id];
var offset = self.pos % self.block_size;
try self.in_file.seekTo(block * self.block_size + offset);
const in = self.in_file.reader();
var size: usize = 0;
var rem_buffer = buffer;
while (size < buffer.len) {
const size_to_read = math.min(self.block_size - offset, rem_buffer.len);
size += try in.read(rem_buffer[0..size_to_read]);
rem_buffer = buffer[size..];
offset += size_to_read;
// If we're at the end of a block, go to the next one.
if (offset == self.block_size) {
offset = 0;
block_id += 1;
if (block_id >= self.blocks.len) break; // End of Stream
block = self.blocks[block_id];
try self.in_file.seekTo(block * self.block_size);
}
}
self.pos += buffer.len;
return buffer.len;
}
pub fn seekBy(self: *MsfStream, len: i64) !void {
self.pos = @intCast(u64, @intCast(i64, self.pos) + len);
if (self.pos >= self.blocks.len * self.block_size)
return error.EOF;
}
pub fn seekTo(self: *MsfStream, len: u64) !void {
self.pos = len;
if (self.pos >= self.blocks.len * self.block_size)
return error.EOF;
}
fn getSize(self: *const MsfStream) u64 {
return self.blocks.len * self.block_size;
}
fn getFilePos(self: MsfStream) u64 {
const block_id = self.pos / self.block_size;
const block = self.blocks[block_id];
const offset = self.pos % self.block_size;
return block * self.block_size + offset;
}
pub fn reader(self: *MsfStream) std.io.Reader(*MsfStream, Error, read) {
return .{ .context = self };
}
};