src/internal/coverage/defs.go - toolchain/go - Git at Google

 // Copyright 2022 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package coverage

 // Types and constants related to the output files written
 // by code coverage tooling. When a coverage-instrumented binary
 // is run, it emits two output files: a meta-data output file, and
 // a counter data output file.

 //.....................................................................
 //
 // Meta-data definitions:
 //
 // The meta-data file is composed of a file header, a series of
 // meta-data blobs/sections (one per instrumented package), and an offsets
 // area storing the offsets of each section. Format of the meta-data
 // file looks like:
 //
 // --header----------
 //  | magic: [4]byte magic string
 //  | version
 //  | total length of meta-data file in bytes
 //  | numPkgs: number of package entries in file
 //  | hash: [16]byte hash of entire meta-data payload
 //  | offset to string table section
 //  | length of string table
 //  | number of entries in string table
 //  | counter mode
 //  | counter granularity
 //  --package offsets table------
 //  <offset to pkg 0>
 //  <offset to pkg 1>
 //  ...
 //  --package lengths table------
 //  <length of pkg 0>
 //  <length of pkg 1>
 //  ...
 //  --string table------
 //  <uleb128 len> 8
 //  <data> "somestring"
 //  ...
 //  --package payloads------
 //  <meta-symbol for pkg 0>
 //  <meta-symbol for pkg 1>
 //  ...
 //
 // Each package payload is a stand-alone blob emitted by the compiler,
 // and does not depend on anything else in the meta-data file. In
 // particular, each blob has it's own string table. Note that the
 // file-level string table is expected to be very short (most strings
 // will be in the meta-data blobs themselves).

 // CovMetaMagic holds the magic string for a meta-data file.
 var CovMetaMagic = [4]byte{'\x00', '\x63', '\x76', '\x6d'}

 // MetaFilePref is a prefix used when emitting meta-data files; these
 // files are of the form "covmeta.<hash>", where hash is a hash
 // computed from the hashes of all the package meta-data symbols in
 // the program.
 const MetaFilePref = "covmeta"

 // MetaFileVersion contains the current (most recent) meta-data file version.
 const MetaFileVersion = 1

 // MetaFileHeader stores file header information for a meta-data file.
 type MetaFileHeader struct {
 	Magic        [4]byte
 	Version      uint32
 	TotalLength  uint64
 	Entries      uint64
 	MetaFileHash [16]byte
 	StrTabOffset uint32
 	StrTabLength uint32
 	CMode        CounterMode
 	CGranularity CounterGranularity
 	_            [6]byte // padding
 }

 // MetaSymbolHeader stores header information for a single
 // meta-data blob, e.g. the coverage meta-data payload
 // computed for a given Go package.
 type MetaSymbolHeader struct {
 	Length     uint32 // size of meta-symbol payload in bytes
 	PkgName    uint32 // string table index
 	PkgPath    uint32 // string table index
 	ModulePath uint32 // string table index
 	MetaHash   [16]byte
 	_          byte    // currently unused
 	_          [3]byte // padding
 	NumFiles   uint32
 	NumFuncs   uint32
 }

 const CovMetaHeaderSize = 16 + 4 + 4 + 4 + 4 + 4 + 4 + 4 // keep in sync with above

 // As an example, consider the following Go package:
 //
 // 01: package p
 // 02:
 // 03: var v, w, z int
 // 04:
 // 05: func small(x, y int) int {
 // 06:   v++
 // 07:   // comment
 // 08:   if y == 0 {
 // 09:     return x
 // 10:   }
 // 11:   return (x << 1) ^ (9 / y)
 // 12: }
 // 13:
 // 14: func Medium(q, r int) int {
 // 15:   s1 := small(q, r)
 // 16:   z += s1
 // 17:   s2 := small(r, q)
 // 18:   w -= s2
 // 19:   return w + z
 // 20: }
 //
 // The meta-data blob for the single package above might look like the
 // following:
 //
 // -- MetaSymbolHeader header----------
 //  | size: size of this blob in bytes
 //  | packagepath: <path to p>
 //  | modulepath: <modpath for p>
 //  | nfiles: 1
 //  | nfunctions: 2
 //  --func offsets table------
 //  <offset to func 0>
 //  <offset to func 1>
 //  --string table (contains all files and functions)------
 //  | <uleb128 len> 4
 //  | <data> "p.go"
 //  | <uleb128 len> 5
 //  | <data> "small"
 //  | <uleb128 len> 6
 //  | <data> "Medium"
 //  --func 0------
 //  | <uleb128> num units: 3
 //  | <uleb128> func name: S1 (index into string table)
 //  | <uleb128> file: S0 (index into string table)
 //  | <unit 0>:  S0   L6     L8    2
 //  | <unit 1>:  S0   L9     L9    1
 //  | <unit 2>:  S0   L11    L11   1
 //  --func 1------
 //  | <uleb128> num units: 1
 //  | <uleb128> func name: S2 (index into string table)
 //  | <uleb128> file: S0 (index into string table)
 //  | <unit 0>:  S0   L15    L19   5
 //  ---end-----------

 // The following types and constants used by the meta-data encoder/decoder.

 // FuncDesc encapsulates the meta-data definitions for a single Go function.
 // This version assumes that we're looking at a function before inlining;
 // if we want to capture a post-inlining view of the world, the
 // representations of source positions would need to be a good deal more
 // complicated.
 type FuncDesc struct {
 	Funcname string
 	Srcfile  string
 	Units    []CoverableUnit
 	Lit      bool // true if this is a function literal
 }

 // CoverableUnit describes the source characteristics of a single
 // program unit for which we want to gather coverage info. Coverable
 // units are either "simple" or "intraline"; a "simple" coverable unit
 // corresponds to a basic block (region of straight-line code with no
 // jumps or control transfers). An "intraline" unit corresponds to a
 // logical clause nested within some other simple unit. A simple unit
 // will have a zero Parent value; for an intraline unit NxStmts will
 // be zero and Parent will be set to 1 plus the index of the
 // containing simple statement. Example:
 //
 //	L7:   q := 1
 //	L8:   x := (y == 101 || launch() == false)
 //	L9:   r := x * 2
 //
 // For the code above we would have three simple units (one for each
 // line), then an intraline unit describing the "launch() == false"
 // clause in line 8, with Parent pointing to the index of the line 8
 // unit in the units array.
 //
 // Note: in the initial version of the coverage revamp, only simple
 // units will be in use.
 type CoverableUnit struct {
 	StLine, StCol uint32
 	EnLine, EnCol uint32
 	NxStmts       uint32
 	Parent        uint32
 }

 // CounterMode tracks the "flavor" of the coverage counters being
 // used in a given coverage-instrumented program.
 type CounterMode uint8

 const (
 	CtrModeInvalid  CounterMode = iota
 	CtrModeSet                  // "set" mode
 	CtrModeCount                // "count" mode
 	CtrModeAtomic               // "atomic" mode
 	CtrModeRegOnly              // registration-only pseudo-mode
 	CtrModeTestMain             // testmain pseudo-mode
 )

 func (cm CounterMode) String() string {
 	switch cm {
 	case CtrModeSet:
 		return "set"
 	case CtrModeCount:
 		return "count"
 	case CtrModeAtomic:
 		return "atomic"
 	case CtrModeRegOnly:
 		return "regonly"
 	case CtrModeTestMain:
 		return "testmain"
 	}
 	return "<invalid>"
 }

 func ParseCounterMode(mode string) CounterMode {
 	var cm CounterMode
 	switch mode {
 	case "set":
 		cm = CtrModeSet
 	case "count":
 		cm = CtrModeCount
 	case "atomic":
 		cm = CtrModeAtomic
 	case "regonly":
 		cm = CtrModeRegOnly
 	case "testmain":
 		cm = CtrModeTestMain
 	default:
 		cm = CtrModeInvalid
 	}
 	return cm
 }

 // CounterGranularity tracks the granularity of the coverage counters being
 // used in a given coverage-instrumented program.
 type CounterGranularity uint8

 const (
 	CtrGranularityInvalid CounterGranularity = iota
 	CtrGranularityPerBlock
 	CtrGranularityPerFunc
 )

 func (cm CounterGranularity) String() string {
 	switch cm {
 	case CtrGranularityPerBlock:
 		return "perblock"
 	case CtrGranularityPerFunc:
 		return "perfunc"
 	}
 	return "<invalid>"
 }

 //.....................................................................
 //
 // Counter data definitions:
 //

 // A counter data file is composed of a file header followed by one or
 // more "segments" (each segment representing a given run or partial
 // run of a give binary) followed by a footer.

 // CovCounterMagic holds the magic string for a coverage counter-data file.
 var CovCounterMagic = [4]byte{'\x00', '\x63', '\x77', '\x6d'}

 // CounterFileVersion stores the most recent counter data file version.
 const CounterFileVersion = 1

 // CounterFileHeader stores files header information for a counter-data file.
 type CounterFileHeader struct {
 	Magic     [4]byte
 	Version   uint32
 	MetaHash  [16]byte
 	CFlavor   CounterFlavor
 	BigEndian bool
 	_         [6]byte // padding
 }

 // CounterSegmentHeader encapsulates information about a specific
 // segment in a counter data file, which at the moment contains
 // counters data from a single execution of a coverage-instrumented
 // program. Following the segment header will be the string table and
 // args table, and then (possibly) padding bytes to bring the byte
 // size of the preamble up to a multiple of 4. Immediately following
 // that will be the counter payloads.
 //
 // The "args" section of a segment is used to store annotations
 // describing where the counter data came from; this section is
 // basically a series of key-value pairs (can be thought of as an
 // encoded 'map[string]string'). At the moment we only write os.Args()
 // data to this section, using pairs of the form "argc=<integer>",
 // "argv0=<os.Args[0]>", "argv1=<os.Args[1]>", and so on. In the
 // future the args table may also include things like GOOS/GOARCH
 // values, and/or tags indicating which tests were run to generate the
 // counter data.
 type CounterSegmentHeader struct {
 	FcnEntries uint64
 	StrTabLen  uint32
 	ArgsLen    uint32
 }

 // CounterFileFooter appears at the tail end of a counter data file,
 // and stores the number of segments it contains.
 type CounterFileFooter struct {
 	Magic       [4]byte
 	_           [4]byte // padding
 	NumSegments uint32
 	_           [4]byte // padding
 }

 // CounterFilePref is the file prefix used when emitting coverage data
 // output files. CounterFileTemplate describes the format of the file
 // name: prefix followed by meta-file hash followed by process ID
 // followed by emit UnixNanoTime.
 const CounterFilePref = "covcounters"
 const CounterFileTempl = "%s.%x.%d.%d"
 const CounterFileRegexp = `^%s\.(\S+)\.(\d+)\.(\d+)+$`

 // CounterFlavor describes how function and counters are
 // stored/represented in the counter section of the file.
 type CounterFlavor uint8

 const (
 	// "Raw" representation: all values (pkg ID, func ID, num counters,
 	// and counters themselves) are stored as uint32's.
 	CtrRaw CounterFlavor = iota + 1

 	// "ULeb" representation: all values (pkg ID, func ID, num counters,
 	// and counters themselves) are stored with ULEB128 encoding.
 	CtrULeb128
 )

 func Round4(x int) int {
 	return (x + 3) &^ 3
 }

 //.....................................................................
 //
 // Runtime counter data definitions.
 //

 // At runtime within a coverage-instrumented program, the "counters"
 // object we associated with instrumented function can be thought of
 // as a struct of the following form:
 //
 // struct {
 //     numCtrs uint32
 //     pkgid uint32
 //     funcid uint32
 //     counterArray [numBlocks]uint32
 // }
 //
 // where "numCtrs" is the number of blocks / coverable units within the
 // function, "pkgid" is the unique index assigned to this package by
 // the runtime, "funcid" is the index of this function within its containing
 // package, and "counterArray" stores the actual counters.
 //
 // The counter variable itself is created not as a struct but as a flat
 // array of uint32's; we then use the offsets below to index into it.

 const NumCtrsOffset = 0
 const PkgIdOffset = 1
 const FuncIdOffset = 2
 const FirstCtrOffset = 3
	// Copyright 2022 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package coverage

	// Types and constants related to the output files written
	// by code coverage tooling. When a coverage-instrumented binary
	// is run, it emits two output files: a meta-data output file, and
	// a counter data output file.

	//.....................................................................
	//
	// Meta-data definitions:
	//
	// The meta-data file is composed of a file header, a series of
	// meta-data blobs/sections (one per instrumented package), and an offsets
	// area storing the offsets of each section. Format of the meta-data
	// file looks like:
	//
	// --header----------
	// \| magic: [4]byte magic string
	// \| version
	// \| total length of meta-data file in bytes
	// \| numPkgs: number of package entries in file
	// \| hash: [16]byte hash of entire meta-data payload
	// \| offset to string table section
	// \| length of string table
	// \| number of entries in string table
	// \| counter mode
	// \| counter granularity
	// --package offsets table------
	// <offset to pkg 0>
	// <offset to pkg 1>
	// ...
	// --package lengths table------
	// <length of pkg 0>
	// <length of pkg 1>
	// ...
	// --string table------
	// <uleb128 len> 8
	// <data> "somestring"
	// ...
	// --package payloads------
	// <meta-symbol for pkg 0>
	// <meta-symbol for pkg 1>
	// ...
	//
	// Each package payload is a stand-alone blob emitted by the compiler,
	// and does not depend on anything else in the meta-data file. In
	// particular, each blob has it's own string table. Note that the
	// file-level string table is expected to be very short (most strings
	// will be in the meta-data blobs themselves).

	// CovMetaMagic holds the magic string for a meta-data file.
	var CovMetaMagic = [4]byte{'\x00', '\x63', '\x76', '\x6d'}

	// MetaFilePref is a prefix used when emitting meta-data files; these
	// files are of the form "covmeta.<hash>", where hash is a hash
	// computed from the hashes of all the package meta-data symbols in
	// the program.
	const MetaFilePref = "covmeta"

	// MetaFileVersion contains the current (most recent) meta-data file version.
	const MetaFileVersion = 1

	// MetaFileHeader stores file header information for a meta-data file.
	type MetaFileHeader struct {
	Magic [4]byte
	Version uint32
	TotalLength uint64
	Entries uint64
	MetaFileHash [16]byte
	StrTabOffset uint32
	StrTabLength uint32
	CMode CounterMode
	CGranularity CounterGranularity
	_ [6]byte // padding
	}

	// MetaSymbolHeader stores header information for a single
	// meta-data blob, e.g. the coverage meta-data payload
	// computed for a given Go package.
	type MetaSymbolHeader struct {
	Length uint32 // size of meta-symbol payload in bytes
	PkgName uint32 // string table index
	PkgPath uint32 // string table index
	ModulePath uint32 // string table index
	MetaHash [16]byte
	_ byte // currently unused
	_ [3]byte // padding
	NumFiles uint32
	NumFuncs uint32
	}

	const CovMetaHeaderSize = 16 + 4 + 4 + 4 + 4 + 4 + 4 + 4 // keep in sync with above

	// As an example, consider the following Go package:
	//
	// 01: package p
	// 02:
	// 03: var v, w, z int
	// 04:
	// 05: func small(x, y int) int {
	// 06: v++
	// 07: // comment
	// 08: if y == 0 {
	// 09: return x
	// 10: }
	// 11: return (x << 1) ^ (9 / y)
	// 12: }
	// 13:
	// 14: func Medium(q, r int) int {
	// 15: s1 := small(q, r)
	// 16: z += s1
	// 17: s2 := small(r, q)
	// 18: w -= s2
	// 19: return w + z
	// 20: }
	//
	// The meta-data blob for the single package above might look like the
	// following:
	//
	// -- MetaSymbolHeader header----------
	// \| size: size of this blob in bytes
	// \| packagepath: <path to p>
	// \| modulepath: <modpath for p>
	// \| nfiles: 1
	// \| nfunctions: 2
	// --func offsets table------
	// <offset to func 0>
	// <offset to func 1>
	// --string table (contains all files and functions)------
	// \| <uleb128 len> 4
	// \| <data> "p.go"
	// \| <uleb128 len> 5
	// \| <data> "small"
	// \| <uleb128 len> 6
	// \| <data> "Medium"
	// --func 0------
	// \| <uleb128> num units: 3
	// \| <uleb128> func name: S1 (index into string table)
	// \| <uleb128> file: S0 (index into string table)
	// \| <unit 0>: S0 L6 L8 2
	// \| <unit 1>: S0 L9 L9 1
	// \| <unit 2>: S0 L11 L11 1
	// --func 1------
	// \| <uleb128> num units: 1
	// \| <uleb128> func name: S2 (index into string table)
	// \| <uleb128> file: S0 (index into string table)
	// \| <unit 0>: S0 L15 L19 5
	// ---end-----------

	// The following types and constants used by the meta-data encoder/decoder.

	// FuncDesc encapsulates the meta-data definitions for a single Go function.
	// This version assumes that we're looking at a function before inlining;
	// if we want to capture a post-inlining view of the world, the
	// representations of source positions would need to be a good deal more
	// complicated.
	type FuncDesc struct {
	Funcname string
	Srcfile string
	Units []CoverableUnit
	Lit bool // true if this is a function literal
	}

	// CoverableUnit describes the source characteristics of a single
	// program unit for which we want to gather coverage info. Coverable
	// units are either "simple" or "intraline"; a "simple" coverable unit
	// corresponds to a basic block (region of straight-line code with no
	// jumps or control transfers). An "intraline" unit corresponds to a
	// logical clause nested within some other simple unit. A simple unit
	// will have a zero Parent value; for an intraline unit NxStmts will
	// be zero and Parent will be set to 1 plus the index of the
	// containing simple statement. Example:
	//
	// L7: q := 1
	// L8: x := (y == 101 \|\| launch() == false)
	// L9: r := x * 2
	//
	// For the code above we would have three simple units (one for each
	// line), then an intraline unit describing the "launch() == false"
	// clause in line 8, with Parent pointing to the index of the line 8
	// unit in the units array.
	//
	// Note: in the initial version of the coverage revamp, only simple
	// units will be in use.
	type CoverableUnit struct {
	StLine, StCol uint32
	EnLine, EnCol uint32
	NxStmts uint32
	Parent uint32
	}

	// CounterMode tracks the "flavor" of the coverage counters being
	// used in a given coverage-instrumented program.
	type CounterMode uint8

	const (
	CtrModeInvalid CounterMode = iota
	CtrModeSet // "set" mode
	CtrModeCount // "count" mode
	CtrModeAtomic // "atomic" mode
	CtrModeRegOnly // registration-only pseudo-mode
	CtrModeTestMain // testmain pseudo-mode
	)

	func (cm CounterMode) String() string {
	switch cm {
	case CtrModeSet:
	return "set"
	case CtrModeCount:
	return "count"
	case CtrModeAtomic:
	return "atomic"
	case CtrModeRegOnly:
	return "regonly"
	case CtrModeTestMain:
	return "testmain"
	}
	return "<invalid>"
	}

	func ParseCounterMode(mode string) CounterMode {
	var cm CounterMode
	switch mode {
	case "set":
	cm = CtrModeSet
	case "count":
	cm = CtrModeCount
	case "atomic":
	cm = CtrModeAtomic
	case "regonly":
	cm = CtrModeRegOnly
	case "testmain":
	cm = CtrModeTestMain
	default:
	cm = CtrModeInvalid
	}
	return cm
	}

	// CounterGranularity tracks the granularity of the coverage counters being
	// used in a given coverage-instrumented program.
	type CounterGranularity uint8

	const (
	CtrGranularityInvalid CounterGranularity = iota
	CtrGranularityPerBlock
	CtrGranularityPerFunc
	)

	func (cm CounterGranularity) String() string {
	switch cm {
	case CtrGranularityPerBlock:
	return "perblock"
	case CtrGranularityPerFunc:
	return "perfunc"
	}
	return "<invalid>"
	}

	//.....................................................................
	//
	// Counter data definitions:
	//

	// A counter data file is composed of a file header followed by one or
	// more "segments" (each segment representing a given run or partial
	// run of a give binary) followed by a footer.

	// CovCounterMagic holds the magic string for a coverage counter-data file.
	var CovCounterMagic = [4]byte{'\x00', '\x63', '\x77', '\x6d'}

	// CounterFileVersion stores the most recent counter data file version.
	const CounterFileVersion = 1

	// CounterFileHeader stores files header information for a counter-data file.
	type CounterFileHeader struct {
	Magic [4]byte
	Version uint32
	MetaHash [16]byte
	CFlavor CounterFlavor
	BigEndian bool
	_ [6]byte // padding
	}

	// CounterSegmentHeader encapsulates information about a specific
	// segment in a counter data file, which at the moment contains
	// counters data from a single execution of a coverage-instrumented
	// program. Following the segment header will be the string table and
	// args table, and then (possibly) padding bytes to bring the byte
	// size of the preamble up to a multiple of 4. Immediately following
	// that will be the counter payloads.
	//
	// The "args" section of a segment is used to store annotations
	// describing where the counter data came from; this section is
	// basically a series of key-value pairs (can be thought of as an
	// encoded 'map[string]string'). At the moment we only write os.Args()
	// data to this section, using pairs of the form "argc=<integer>",
	// "argv0=<os.Args[0]>", "argv1=<os.Args[1]>", and so on. In the
	// future the args table may also include things like GOOS/GOARCH
	// values, and/or tags indicating which tests were run to generate the
	// counter data.
	type CounterSegmentHeader struct {
	FcnEntries uint64
	StrTabLen uint32
	ArgsLen uint32
	}

	// CounterFileFooter appears at the tail end of a counter data file,
	// and stores the number of segments it contains.
	type CounterFileFooter struct {
	Magic [4]byte
	_ [4]byte // padding
	NumSegments uint32
	_ [4]byte // padding
	}

	// CounterFilePref is the file prefix used when emitting coverage data
	// output files. CounterFileTemplate describes the format of the file
	// name: prefix followed by meta-file hash followed by process ID
	// followed by emit UnixNanoTime.
	const CounterFilePref = "covcounters"
	const CounterFileTempl = "%s.%x.%d.%d"
	const CounterFileRegexp = `^%s\.(\S+)\.(\d+)\.(\d+)+$`

	// CounterFlavor describes how function and counters are
	// stored/represented in the counter section of the file.
	type CounterFlavor uint8

	const (
	// "Raw" representation: all values (pkg ID, func ID, num counters,
	// and counters themselves) are stored as uint32's.
	CtrRaw CounterFlavor = iota + 1

	// "ULeb" representation: all values (pkg ID, func ID, num counters,
	// and counters themselves) are stored with ULEB128 encoding.
	CtrULeb128
	)

	func Round4(x int) int {
	return (x + 3) &^ 3
	}

	//.....................................................................
	//
	// Runtime counter data definitions.
	//

	// At runtime within a coverage-instrumented program, the "counters"
	// object we associated with instrumented function can be thought of
	// as a struct of the following form:
	//
	// struct {
	// numCtrs uint32
	// pkgid uint32
	// funcid uint32
	// counterArray [numBlocks]uint32
	// }
	//
	// where "numCtrs" is the number of blocks / coverable units within the
	// function, "pkgid" is the unique index assigned to this package by
	// the runtime, "funcid" is the index of this function within its containing
	// package, and "counterArray" stores the actual counters.
	//
	// The counter variable itself is created not as a struct but as a flat
	// array of uint32's; we then use the offsets below to index into it.

	const NumCtrsOffset = 0
	const PkgIdOffset = 1
	const FuncIdOffset = 2
	const FirstCtrOffset = 3