ollama/llm/gguf.go
Michael Yang 125d0a013a ggufv3
ggufv3 adds support for big endianness, mainly for s390x architecture.
while that's not currently supported for ollama, the change is simple.

loosen version check to be more forward compatible. unless specified,
gguf versions other v1 will be decoded into v2.
2023-10-23 09:35:49 -07:00

382 lines
7 KiB
Go

package llm
import (
"bytes"
"encoding/binary"
"fmt"
"io"
)
type containerGGUF struct {
bo binary.ByteOrder
Version uint32
V1 struct {
NumTensor uint32
NumKV uint32
}
V2 struct {
NumTensor uint64
NumKV uint64
}
}
func (c *containerGGUF) Name() string {
return "gguf"
}
func (c *containerGGUF) Decode(r io.Reader) (model, error) {
binary.Read(r, c.bo, &c.Version)
switch c.Version {
case 1:
binary.Read(r, c.bo, &c.V1)
default:
binary.Read(r, c.bo, &c.V2)
}
model := newGGUFModel(c)
if err := model.Decode(r); err != nil {
return nil, err
}
return model, nil
}
const (
ggufTypeUint8 uint32 = iota
ggufTypeInt8
ggufTypeUint16
ggufTypeInt16
ggufTypeUint32
ggufTypeInt32
ggufTypeFloat32
ggufTypeBool
ggufTypeString
ggufTypeArray
ggufTypeUint64
ggufTypeInt64
ggufTypeFloat64
)
type kv map[string]any
type ggufModel struct {
*containerGGUF
kv
}
func newGGUFModel(container *containerGGUF) *ggufModel {
return &ggufModel{
containerGGUF: container,
kv: make(kv),
}
}
func (llm *ggufModel) NumKV() uint64 {
if llm.Version == 1 {
return uint64(llm.V1.NumKV)
}
return llm.V2.NumKV
}
func (llm *ggufModel) ModelFamily() string {
t, ok := llm.kv["general.architecture"].(string)
if ok {
return t
}
return "unknown"
}
func (llm *ggufModel) ModelType() string {
switch llm.ModelFamily() {
case "llama":
if blocks, ok := llm.kv["llama.block_count"].(uint32); ok {
heads, headsOK := llm.kv["llama.head_count"].(uint32)
headKVs, headsKVsOK := llm.kv["llama.head_count_kv"].(uint32)
if headsOK && headsKVsOK && heads/headKVs == 8 {
return "70B"
}
return llamaModelType(blocks)
}
case "falcon":
if blocks, ok := llm.kv["falcon.block_count"].(uint32); ok {
return falconModelType(blocks)
}
case "starcoder":
if blocks, ok := llm.kv["starcoder.block_count"].(uint32); ok {
return starCoderModelType(blocks)
}
}
return "unknown"
}
func (llm *ggufModel) FileType() string {
t, ok := llm.kv["general.file_type"].(uint32)
if ok {
return fileType(t)
}
return "unknown"
}
func (llm *ggufModel) Decode(r io.Reader) error {
read := llm.readString
if llm.Version == 1 {
read = llm.readStringV1
}
for i := 0; uint64(i) < llm.NumKV(); i++ {
k, err := read(r)
if err != nil {
return err
}
vtype := llm.readU32(r)
var v any
switch vtype {
case ggufTypeUint8:
v = llm.readU8(r)
case ggufTypeInt8:
v = llm.readI8(r)
case ggufTypeUint16:
v = llm.readU16(r)
case ggufTypeInt16:
v = llm.readI16(r)
case ggufTypeUint32:
v = llm.readU32(r)
case ggufTypeInt32:
v = llm.readI32(r)
case ggufTypeUint64:
v = llm.readU64(r)
case ggufTypeInt64:
v = llm.readI64(r)
case ggufTypeFloat32:
v = llm.readF32(r)
case ggufTypeFloat64:
v = llm.readF64(r)
case ggufTypeBool:
v = llm.readBool(r)
case ggufTypeString:
fn := llm.readString
if llm.Version == 1 {
fn = llm.readStringV1
}
s, err := fn(r)
if err != nil {
return err
}
v = s
case ggufTypeArray:
fn := llm.readArray
if llm.Version == 1 {
fn = llm.readArrayV1
}
a, err := fn(r)
if err != nil {
return err
}
v = a
default:
return fmt.Errorf("invalid type: %d", vtype)
}
llm.kv[k] = v
}
return nil
}
func (llm *ggufModel) NumLayers() int64 {
value, exists := llm.kv[fmt.Sprintf("%s.block_count", llm.ModelFamily())]
if !exists {
return 0
}
v := value.(uint32)
return int64(v)
}
func (llm ggufModel) readU8(r io.Reader) uint8 {
var u8 uint8
binary.Read(r, llm.bo, &u8)
return u8
}
func (llm ggufModel) readI8(r io.Reader) int8 {
var i8 int8
binary.Read(r, llm.bo, &i8)
return i8
}
func (llm ggufModel) readU16(r io.Reader) uint16 {
var u16 uint16
binary.Read(r, llm.bo, &u16)
return u16
}
func (llm ggufModel) readI16(r io.Reader) int16 {
var i16 int16
binary.Read(r, llm.bo, &i16)
return i16
}
func (llm ggufModel) readU32(r io.Reader) uint32 {
var u32 uint32
binary.Read(r, llm.bo, &u32)
return u32
}
func (llm ggufModel) readI32(r io.Reader) int32 {
var i32 int32
binary.Read(r, llm.bo, &i32)
return i32
}
func (llm ggufModel) readU64(r io.Reader) uint64 {
var u64 uint64
binary.Read(r, llm.bo, &u64)
return u64
}
func (llm ggufModel) readI64(r io.Reader) int64 {
var i64 int64
binary.Read(r, llm.bo, &i64)
return i64
}
func (llm ggufModel) readF32(r io.Reader) float32 {
var f32 float32
binary.Read(r, llm.bo, &f32)
return f32
}
func (llm ggufModel) readF64(r io.Reader) float64 {
var f64 float64
binary.Read(r, llm.bo, &f64)
return f64
}
func (llm ggufModel) readBool(r io.Reader) bool {
var b bool
binary.Read(r, llm.bo, &b)
return b
}
func (llm ggufModel) readStringV1(r io.Reader) (string, error) {
var nameLength uint32
binary.Read(r, llm.bo, &nameLength)
var b bytes.Buffer
if _, err := io.CopyN(&b, r, int64(nameLength)); err != nil {
return "", err
}
// gguf v1 strings are null-terminated
b.Truncate(b.Len() - 1)
return b.String(), nil
}
func (llm ggufModel) readString(r io.Reader) (string, error) {
var nameLength uint64
binary.Read(r, llm.bo, &nameLength)
var b bytes.Buffer
if _, err := io.CopyN(&b, r, int64(nameLength)); err != nil {
return "", err
}
return b.String(), nil
}
func (llm *ggufModel) readArrayV1(r io.Reader) (arr []any, err error) {
atype := llm.readU32(r)
n := llm.readU32(r)
for i := 0; uint32(i) < n; i++ {
switch atype {
case ggufTypeUint8:
arr = append(arr, llm.readU8(r))
case ggufTypeInt8:
arr = append(arr, llm.readU8(r))
case ggufTypeUint16:
arr = append(arr, llm.readU16(r))
case ggufTypeInt16:
arr = append(arr, llm.readI16(r))
case ggufTypeUint32:
arr = append(arr, llm.readU32(r))
case ggufTypeInt32:
arr = append(arr, llm.readI32(r))
case ggufTypeFloat32:
arr = append(arr, llm.readF32(r))
case ggufTypeBool:
arr = append(arr, llm.readBool(r))
case ggufTypeString:
s, err := llm.readStringV1(r)
if err != nil {
return nil, err
}
arr = append(arr, s)
default:
return nil, fmt.Errorf("invalid array type: %d", atype)
}
}
return
}
func (llm *ggufModel) readArray(r io.Reader) (arr []any, err error) {
atype := llm.readU32(r)
n := llm.readU64(r)
for i := 0; uint64(i) < n; i++ {
switch atype {
case ggufTypeUint8:
arr = append(arr, llm.readU8(r))
case ggufTypeInt8:
arr = append(arr, llm.readU8(r))
case ggufTypeUint16:
arr = append(arr, llm.readU16(r))
case ggufTypeInt16:
arr = append(arr, llm.readI16(r))
case ggufTypeUint32:
arr = append(arr, llm.readU32(r))
case ggufTypeInt32:
arr = append(arr, llm.readI32(r))
case ggufTypeUint64:
arr = append(arr, llm.readU64(r))
case ggufTypeInt64:
arr = append(arr, llm.readI64(r))
case ggufTypeFloat32:
arr = append(arr, llm.readF32(r))
case ggufTypeFloat64:
arr = append(arr, llm.readF64(r))
case ggufTypeBool:
arr = append(arr, llm.readBool(r))
case ggufTypeString:
s, err := llm.readString(r)
if err != nil {
return nil, err
}
arr = append(arr, s)
default:
return nil, fmt.Errorf("invalid array type: %d", atype)
}
}
return
}