ollama/types/model/name.go
Blake Mizerany 9df6c85c3a
types/model: add FilepathNoBuild (#3680)
Also, add test for DisplayLongest.

Also, plumb fill param to ParseName in MustParseName
2024-04-16 18:35:43 -07:00

688 lines
18 KiB
Go

package model
import (
"cmp"
"errors"
"fmt"
"hash/maphash"
"io"
"log/slog"
"path/filepath"
"slices"
"strings"
"sync"
"github.com/ollama/ollama/types/structs"
)
// Errors
var (
// ErrInvalidName, ErrIncompleteName, and ErrInvalidDigest are not
// used by this package, but are exported so that other packages can
// use them, instead of defining their own errors for them.
ErrInvalidName = errors.New("invalid model name")
ErrIncompleteName = errors.New("incomplete model name")
ErrInvalidDigest = errors.New("invalid digest")
)
// Defaults
const (
// MaskDefault is the default mask used by [Name.DisplayShortest].
MaskDefault = "registry.ollama.ai/library/?:latest"
// MaskNothing is a mask that masks nothing.
MaskNothing = "?/?/?:?"
// DefaultFill is the default fill used by [ParseName].
FillDefault = "registry.ollama.ai/library/?:latest+Q4_0"
// FillNothing is a fill that fills nothing.
FillNothing = "?/?/?:?+?"
)
const MaxNamePartLen = 128
type PartKind int
// Levels of concreteness
const (
// Each value aligns with its index in the Name.parts array.
PartHost PartKind = iota
PartNamespace
PartModel
PartTag
PartBuild
PartDigest
// NumParts is the number of parts in a Name. In this list, it must
// follow the final part.
NumParts
PartExtraneous = -1
)
var kindNames = map[PartKind]string{
PartHost: "Host",
PartNamespace: "Namespace",
PartModel: "Name",
PartTag: "Tag",
PartBuild: "Build",
PartDigest: "Digest",
}
func (k PartKind) String() string {
return cmp.Or(kindNames[k], "Unknown")
}
// Name is an opaque reference to a model. It holds the parts of a model
// with the case preserved, but is not directly comparable with other Names
// since model names can be represented with different casing depending on
// the use case. For instance, "Mistral" and "mistral" are the same model
// but each version may have come from different sources (e.g. copied from a
// Web page, or from a file path).
//
// Valid Names can ONLY be constructed by calling [ParseName].
//
// A Name is valid if and only if is have a valid Model part. The other parts
// are optional.
//
// A Name is considered "complete" if it has all parts present. To check if a
// Name is complete, use [Name.IsComplete].
//
// To compare two names in a case-insensitive manner, use [Name.EqualFold].
//
// The parts of a Name are:
//
// - Host: the domain of the model (optional)
// - Namespace: the namespace of the model (optional)
// - Model: the name of the model (required)
// - Tag: the tag of the model (optional)
// - Build: the build of the model; usually the quantization or "file type" (optional)
//
// The parts can be obtained in their original form by calling [Name.Parts].
//
// To check if a Name has at minimum a valid model part, use [Name.IsValid].
type Name struct {
_ structs.Incomparable
parts [NumParts]string // host, namespace, model, tag, build, digest
// TODO(bmizerany): track offsets and hold s (raw string) here? We
// could pack the offsets all into a single uint64 since the first
// parts take less bits since their max offset is less than the max
// offset of the next part. This would save a ton of bytes per Name
// and mean zero allocations for String.
}
// ParseName parses s into a Name, and returns the result of filling it with
// defaults. The input string must be a valid string
// representation of a model name in the form:
//
// [host/][namespace/]<model>[:tag][+build][@<digest-type>-<digest>]
//
// The name part is required, all others are optional. If a part is missing,
// it is left empty in the returned Name. If a part is invalid, the zero Ref
// value is returned.
//
// The build part is normalized to uppercase.
//
// Examples of valid paths:
//
// "example.com/library/mistral:7b+x"
// "example.com/eva/mistral:7b+Q4_0"
// "mistral:7b+x"
// "example.com/mike/mistral:latest+Q4_0"
// "example.com/bruce/mistral:latest"
// "example.com/pdevine/thisisfine:7b+Q4_0@sha256-1234567890abcdef"
//
// Examples of invalid paths:
//
// "example.com/mistral:7b+"
// "example.com/mistral:7b+Q4_0+"
// "x/y/z/z:8n+I"
// ""
//
// It returns the zero value if any part is invalid.
//
// # Fills
//
// For any valid s, the fill string is used to fill in missing parts of the
// Name. The fill string must be a valid Name with the exception that any part
// may be the string ("?"), which will not be considered for filling.
func ParseName(s, fill string) Name {
var r Name
parts(s)(func(kind PartKind, part string) bool {
if kind == PartDigest && !ParseDigest(part).IsValid() {
r = Name{}
return false
}
if kind == PartExtraneous || !isValidPart(kind, part) {
r = Name{}
return false
}
r.parts[kind] = part
return true
})
if r.IsValid() || r.IsResolved() {
return fillName(r, fill)
}
return Name{}
}
func parseMask(s string) Name {
var r Name
parts(s)(func(kind PartKind, part string) bool {
if part == "?" {
// mask part; treat as empty but valid
return true
}
if !isValidPart(kind, part) {
panic(fmt.Errorf("invalid mask part %s: %q", kind, part))
}
r.parts[kind] = part
return true
})
return r
}
func MustParseName(s, fill string) Name {
r := ParseName(s, fill)
if !r.IsValid() {
panic("invalid Name: " + s)
}
return r
}
// fillName fills in the missing parts of dst with the parts of src.
//
// The returned Name will only be valid if dst is valid.
//
// It skipps fill parts that are "?".
func fillName(r Name, fill string) Name {
fill = cmp.Or(fill, FillDefault)
f := parseMask(fill)
if fill != FillNothing && f.IsZero() {
panic("invalid fill")
}
for i := range r.parts {
if f.parts[i] == "?" {
continue
}
r.parts[i] = cmp.Or(r.parts[i], f.parts[i])
}
return r
}
// WithBuild returns a copy of r with the build set to the given string.
func (r Name) WithBuild(build string) Name {
r.parts[PartBuild] = build
return r
}
func (r Name) WithDigest(digest Digest) Name {
r.parts[PartDigest] = digest.String()
return r
}
var mapHashSeed = maphash.MakeSeed()
// MapHash returns a case insensitive hash for use in maps and equality
// checks. For a convenient way to compare names, use [Name.EqualFold].
//
//nolint:errcheck
func (r Name) MapHash() uint64 {
// correctly hash the parts with case insensitive comparison
var h maphash.Hash
h.SetSeed(mapHashSeed)
for _, part := range r.parts {
// downcase the part for hashing
for i := range part {
c := part[i]
if c >= 'A' && c <= 'Z' {
c = c - 'A' + 'a'
}
h.WriteByte(c)
}
}
return h.Sum64()
}
func (r Name) slice(from, to PartKind) Name {
var v Name
copy(v.parts[from:to+1], r.parts[from:to+1])
return v
}
// DisplayShortest returns the shortest possible, masked display string in form:
//
// [host/][<namespace>/]<model>[:<tag>]
//
// # Masks
//
// The mask is a string that specifies which parts of the name to omit based
// on case-insensitive comparison. [Name.DisplayShortest] omits parts of the name
// that are the same as the mask, moving from left to right until the first
// unequal part is found. It then moves right to left until the first unequal
// part is found. The result is the shortest possible display string.
//
// Unlike a [Name] the mask can contain "?" characters which are treated as
// wildcards. A "?" will never match a part of the name, since a valid name
// can never contain a "?" character.
//
// For example: Given a Name ("registry.ollama.ai/library/mistral:latest") masked
// with ("registry.ollama.ai/library/?:latest") will produce the display string
// ("mistral").
//
// If mask is the empty string, then [MaskDefault] is used.
//
// DisplayShortest panics if the mask is not the empty string, MaskNothing, and
// invalid.
//
// # Builds
//
// For now, DisplayShortest does consider the build or return one in the
// result. We can lift this restriction when needed.
func (r Name) DisplayShortest(mask string) string {
mask = cmp.Or(mask, MaskDefault)
d := parseMask(mask)
if mask != MaskNothing && r.IsZero() {
panic("invalid Name")
}
for i := range PartTag {
if !strings.EqualFold(r.parts[i], d.parts[i]) {
break
}
r.parts[i] = ""
}
for i := PartTag; i >= 0; i-- {
if !strings.EqualFold(r.parts[i], d.parts[i]) {
break
}
r.parts[i] = ""
}
return r.slice(PartHost, PartTag).DisplayLong()
}
// DisplayLongest returns the result of r.DisplayShortest(MaskNothing).
func (r Name) DisplayLongest() string {
return r.DisplayShortest(MaskNothing)
}
var seps = [...]string{
PartHost: "/",
PartNamespace: "/",
PartModel: ":",
PartTag: "+",
PartBuild: "@",
PartDigest: "",
}
// WriteTo implements io.WriterTo. It writes the fullest possible display
// string in form:
//
// <host>/<namespace>/<model>:<tag>+<build>@<digest-type>-<digest>
//
// Missing parts and their separators are not written.
//
// The full digest is always prefixed with "@". That is if [Name.IsValid]
// reports false and [Name.IsResolved] reports true, then the string is
// returned as "@<digest-type>-<digest>".
func (r Name) writeTo(w io.StringWriter) error {
var partsWritten int
for i := range r.parts {
if r.parts[i] == "" {
continue
}
if partsWritten > 0 || i == int(PartDigest) {
if _, err := w.WriteString(seps[i-1]); err != nil {
return err
}
}
if _, err := w.WriteString(r.parts[i]); err != nil {
return err
}
partsWritten++
}
return nil
}
var builderPool = sync.Pool{
New: func() interface{} {
return &strings.Builder{}
},
}
// DisplayLong returns the fullest possible display string in form:
//
// <host>/<namespace>/<model>:<tag>+<build>
//
// If any part is missing, it is omitted from the display string.
func (r Name) DisplayLong() string {
b := builderPool.Get().(*strings.Builder)
defer builderPool.Put(b)
b.Reset()
b.Grow(50) // arbitrarily long enough for most names
_ = r.writeTo(b)
return b.String()
}
// GoString implements fmt.GoStringer. It returns a string suitable for
// debugging and logging. It is similar to [Name.DisplayLong] but it always
// returns a string that includes all parts of the Name, with missing parts
// replaced with a ("?").
func (r Name) GoString() string {
for i := range r.parts {
r.parts[i] = cmp.Or(r.parts[i], "?")
}
return r.DisplayLong()
}
// LogValue implements slog.Valuer.
func (r Name) LogValue() slog.Value {
return slog.StringValue(r.GoString())
}
// IsComplete reports whether the Name is fully qualified. That is it has a
// domain, namespace, name, tag, and build.
func (r Name) IsComplete() bool {
return !slices.Contains(r.parts[:PartDigest], "")
}
// IsCompleteNoBuild is like [Name.IsComplete] but it does not require the
// build part to be present.
func (r Name) IsCompleteNoBuild() bool {
return !slices.Contains(r.parts[:PartBuild], "")
}
// IsResolved reports true if the Name has a valid digest.
//
// It is possible to have a valid Name, or a complete Name that is not
// resolved.
func (r Name) IsResolved() bool {
return r.Digest().IsValid()
}
// Digest returns the digest part of the Name, if any.
//
// If Digest returns a non-empty string, then [Name.IsResolved] will return
// true, and digest is considered valid.
func (r Name) Digest() Digest {
// This was already validated by ParseName, so we can just return it.
return Digest{r.parts[PartDigest]}
}
// EqualFold reports whether r and o are equivalent model names, ignoring
// case.
func (r Name) EqualFold(o Name) bool {
return r.CompareFold(o) == 0
}
// CompareFold performs a case-insensitive cmp.Compare on r and o.
//
// This can be used with [slices.SortFunc].
//
// For simple equality checks, use [Name.EqualFold].
func (r Name) CompareFold(o Name) int {
return slices.CompareFunc(r.parts[:], o.parts[:], compareFold)
}
func compareFold(a, b string) int {
return slices.CompareFunc([]rune(a), []rune(b), func(a, b rune) int {
return cmp.Compare(downcase(a), downcase(b))
})
}
func downcase(r rune) rune {
if r >= 'A' && r <= 'Z' {
return r - 'A' + 'a'
}
return r
}
func (r Name) Host() string { return r.parts[PartHost] }
func (r Name) Namespace() string { return r.parts[PartNamespace] }
func (r Name) Model() string { return r.parts[PartModel] }
func (r Name) Build() string { return r.parts[PartBuild] }
func (r Name) Tag() string { return r.parts[PartTag] }
// iter_Seq2 is a iter.Seq2 defined here to avoid the current build
// restrictions in the go1.22 iter package requiring the
// goexperiment.rangefunc tag to be set via the GOEXPERIMENT=rangefunc flag,
// which we are not yet ready to support.
//
// Once we are ready to support rangefunc, this can be removed and replaced
// with the iter.Seq2 type.
type iter_Seq2[A, B any] func(func(A, B) bool)
// Parts returns a sequence of the parts of a Name string from most specific
// to least specific.
//
// It normalizes the input string by removing "http://" and "https://" only.
// No other normalizations are performed.
func parts(s string) iter_Seq2[PartKind, string] {
return func(yield func(PartKind, string) bool) {
if strings.HasPrefix(s, "http://") {
s = strings.TrimPrefix(s, "http://")
} else {
s = strings.TrimPrefix(s, "https://")
}
if len(s) > MaxNamePartLen || len(s) == 0 {
return
}
numConsecutiveDots := 0
partLen := 0
state, j := PartDigest, len(s)
for i := len(s) - 1; i >= 0; i-- {
if partLen++; partLen > MaxNamePartLen {
// catch a part that is too long early, so
// we don't keep spinning on it, waiting for
// an isInValidPart check which would scan
// over it again.
yield(state, s[i+1:j])
return
}
switch s[i] {
case '@':
switch state {
case PartDigest:
if !yield(PartDigest, s[i+1:j]) {
return
}
if i == 0 {
// This is the form
// "@<digest>" which is valid.
//
// We're done.
return
}
state, j, partLen = PartBuild, i, 0
default:
yield(PartExtraneous, s[i+1:j])
return
}
case '+':
switch state {
case PartBuild, PartDigest:
if !yield(PartBuild, s[i+1:j]) {
return
}
state, j, partLen = PartTag, i, 0
default:
yield(PartExtraneous, s[i+1:j])
return
}
case ':':
switch state {
case PartTag, PartBuild, PartDigest:
if !yield(PartTag, s[i+1:j]) {
return
}
state, j, partLen = PartModel, i, 0
default:
yield(PartExtraneous, s[i+1:j])
return
}
case '/':
switch state {
case PartModel, PartTag, PartBuild, PartDigest:
if !yield(PartModel, s[i+1:j]) {
return
}
state, j = PartNamespace, i
case PartNamespace:
if !yield(PartNamespace, s[i+1:j]) {
return
}
state, j, partLen = PartHost, i, 0
default:
yield(PartExtraneous, s[i+1:j])
return
}
default:
if s[i] == '.' {
if numConsecutiveDots++; numConsecutiveDots > 1 {
yield(state, "")
return
}
} else {
numConsecutiveDots = 0
}
}
}
if state <= PartNamespace {
yield(state, s[:j])
} else {
yield(PartModel, s[:j])
}
}
}
func (r Name) IsZero() bool {
return r.parts == [NumParts]string{}
}
// IsValid reports if a model has at minimum a valid model part.
func (r Name) IsValid() bool {
// Parts ensures we only have valid parts, so no need to validate
// them here, only check if we have a name or not.
return r.parts[PartModel] != ""
}
// ParseNameFromURLPath parses forms of a URL path into a Name. Specifically,
// it trims any leading "/" and then calls [ParseName] with fill.
func ParseNameFromURLPath(s, fill string) Name {
s = strings.TrimPrefix(s, "/")
return ParseName(s, fill)
}
// URLPath returns a complete, canonicalized, relative URL path using the parts of a
// complete Name.
//
// The parts maintain their original case.
//
// Example:
//
// ParseName("example.com/namespace/model:tag+build").URLPath() // returns "/example.com/namespace/model:tag"
func (r Name) URLPath() string {
return r.DisplayShortest(MaskNothing)
}
// ParseNameFromFilepath parses a file path into a Name. The input string must be a
// valid file path representation of a model name in the form:
//
// host/namespace/model/tag/build
//
// The zero valid is returned if s does not contain all path elements
// leading up to the model part, or if any path element is an invalid part
// for the its corresponding part kind.
//
// The fill string is used to fill in missing parts of any constructed Name.
// See [ParseName] for more information on the fill string.
func ParseNameFromFilepath(s, fill string) Name {
var r Name
for i := range PartBuild + 1 {
part, rest, _ := strings.Cut(s, string(filepath.Separator))
if !isValidPart(i, part) {
return Name{}
}
r.parts[i] = part
s = rest
if s == "" {
break
}
}
if s != "" {
return Name{}
}
if !r.IsValid() {
return Name{}
}
return fillName(r, fill)
}
// Filepath returns a complete, canonicalized, relative file path using the
// parts of a complete Name.
//
// Each parts is downcased, except for the build part which is upcased.
//
// Example:
//
// ParseName("example.com/namespace/model:tag+build").Filepath() // returns "example.com/namespace/model/tag/BUILD"
func (r Name) Filepath() string {
for i := range r.parts {
if PartKind(i) == PartBuild {
r.parts[i] = strings.ToUpper(r.parts[i])
} else {
r.parts[i] = strings.ToLower(r.parts[i])
}
}
return filepath.Join(r.parts[:]...)
}
// FilepathNoBuild returns a complete, canonicalized, relative file path using
// the parts of a complete Name, but without the build part.
func (r Name) FilepathNoBuild() string {
for i := range PartBuild {
r.parts[i] = strings.ToLower(r.parts[i])
}
return filepath.Join(r.parts[:PartBuild]...)
}
// isValidPart reports if s contains all valid characters for the given
// part kind.
func isValidPart(kind PartKind, s string) bool {
if s == "" {
return false
}
var consecutiveDots int
for _, c := range []byte(s) {
if c == '.' {
if consecutiveDots++; consecutiveDots >= 2 {
return false
}
} else {
consecutiveDots = 0
}
if !isValidByteFor(kind, c) {
return false
}
}
return true
}
func isValidByteFor(kind PartKind, c byte) bool {
if kind == PartNamespace && c == '.' {
return false
}
if c == '.' || c == '-' {
return true
}
if c >= 'a' && c <= 'z' || c >= 'A' && c <= 'Z' || c >= '0' && c <= '9' || c == '_' {
return true
}
return false
}