ollama/convert/convert_gptoss.go

package convert

import (
	"bytes"
	"cmp"
	"encoding/binary"
	"io"
	"slices"
	"strings"

	"github.com/ollama/ollama/fs/ggml"
	"github.com/pdevine/tensor"
	"github.com/pdevine/tensor/native"
)

type gptossModel struct {
	ModelParameters
	HiddenLayers         uint32  `json:"num_hidden_layers"`
	HiddenSize           uint32  `json:"hidden_size"`
	IntermediateSize     uint32  `json:"intermediate_size"`
	AttentionHeads       uint32  `json:"num_attention_heads"`
	KeyValueHeads        uint32  `json:"num_key_value_heads"`
	HeadDim              uint32  `json:"head_dim"`
	Experts              uint32  `json:"num_experts"`
	ExpertsPerToken      uint32  `json:"experts_per_token"`
	RMSNormEpsilon       float32 `json:"rms_norm_eps"`
	InitialContextLength uint32  `json:"initial_context_length"`
	RopeTheta            float32 `json:"rope_theta"`
	RopeScalingFactor    float32 `json:"rope_scaling_factor"`
	SlidingWindow        uint32  `json:"sliding_window"`
}

var _ ModelConverter = (*gptossModel)(nil)

func (m *gptossModel) KV(t *Tokenizer) ggml.KV {
	kv := m.ModelParameters.KV(t)
	kv["general.architecture"] = "gptoss"
	kv["general.file_type"] = uint32(4)
	kv["gptoss.context_length"] = uint32(m.RopeScalingFactor * float32(m.InitialContextLength))
	kv["gptoss.block_count"] = m.HiddenLayers
	kv["gptoss.embedding_length"] = m.HiddenSize
	kv["gptoss.feed_forward_length"] = m.IntermediateSize
	kv["gptoss.expert_count"] = m.Experts
	kv["gptoss.expert_used_count"] = m.ExpertsPerToken
	kv["gptoss.attention.head_count"] = m.AttentionHeads
	kv["gptoss.attention.head_count_kv"] = m.KeyValueHeads
	kv["gptoss.attention.key_length"] = m.HeadDim
	kv["gptoss.attention.value_length"] = m.HeadDim
	kv["gptoss.attention.layer_norm_rms_epsilon"] = cmp.Or(m.RMSNormEpsilon, 1e-5)
	kv["gptoss.attention.sliding_window"] = m.SlidingWindow
	kv["gptoss.rope.freq_base"] = m.RopeTheta
	kv["gptoss.rope.scaling.factor"] = m.RopeScalingFactor
	kv["gptoss.rope.scaling.original_context_length"] = m.InitialContextLength
	kv["tokenizer.ggml.bos_token_id"] = uint32(199998) // <|startoftext|>
	kv["tokenizer.ggml.add_bos_token"] = false
	kv["tokenizer.ggml.eos_token_id"] = uint32(199999) // <|endoftext|>
	kv["tokenizer.ggml.eos_token_ids"] = []int32{
		199999, /* <|endoftext|> */
		200002, /* <|return|> */
		200012, /* <|call|> */
	}
	kv["tokenizer.ggml.add_eos_token"] = false
	return kv
}

func (m *gptossModel) Tensors(ts []Tensor) []*ggml.Tensor {
	var out []*ggml.Tensor
	mxfp4s := make(map[string]*mxfp4)
	for _, t := range ts {
		if strings.HasSuffix(t.Name(), ".blocks") || strings.HasSuffix(t.Name(), ".scales") {
			dot := strings.LastIndex(t.Name(), ".")
			name, suffix := t.Name()[:dot], t.Name()[dot+1:]
			if _, ok := mxfp4s[name]; !ok {
				mxfp4s[name] = &mxfp4{}
			}

			switch suffix {
			case "blocks":
				mxfp4s[name].blocks = t
			case "scales":
				mxfp4s[name].scales = t
			}
		} else {
			out = append(out, &ggml.Tensor{
				Name:     t.Name(),
				Kind:     t.Kind(),
				Shape:    t.Shape(),
				WriterTo: t,
			})
		}
	}

	for name, mxfp4 := range mxfp4s {
		dims := mxfp4.blocks.Shape()
		out = append(out, &ggml.Tensor{
			Name:     name,
			Kind:     uint32(ggml.TensorTypeMXFP4),
			Shape:    []uint64{dims[0], dims[1], dims[2] * dims[3] * 2},
			WriterTo: mxfp4,
		})
	}

	return out
}

func (m *gptossModel) Replacements() []string {
	return []string{
		// noop replacements so other replacements will not be applied
		".blocks", ".blocks",
		".scales", ".scales",
		// real replacements
		"block", "blk",
		"attn.norm", "attn_norm",
		"attn.qkv", "attn_qkv",
		"attn.sinks", "attn_sinks",
		"attn.out", "attn_out",
		"mlp.norm", "ffn_norm",
		"mlp.gate", "ffn_gate_inp",
		"mlp.mlp1_", "ffn_gate_up_exps.",
		"mlp.mlp2_", "ffn_down_exps.",
		"embedding", "token_embd",
		"norm", "output_norm",
		"unembedding", "output",
		"scale", "weight",
	}
}

type mxfp4 struct {
	blocks, scales Tensor
}

func (m *mxfp4) WriteTo(w io.Writer) (int64, error) {
	var b bytes.Buffer
	if _, err := m.blocks.WriteTo(&b); err != nil {
		return 0, err
	}

	blocksDims := make([]int, len(m.blocks.Shape()))
	for i, d := range m.blocks.Shape() {
		blocksDims[i] = int(d)
	}

	var blocks tensor.Tensor = tensor.New(tensor.WithShape(blocksDims...), tensor.WithBacking(b.Bytes()))

	var s bytes.Buffer
	if _, err := m.scales.WriteTo(&s); err != nil {
		return 0, err
	}

	scalesDims := slices.Repeat([]int{1}, len(m.blocks.Shape()))
	for i, d := range m.scales.Shape() {
		scalesDims[i] = int(d)
	}

	var scales tensor.Tensor = tensor.New(tensor.WithShape(scalesDims...), tensor.WithBacking(s.Bytes()))

	out, err := tensor.Concat(3, scales, blocks)
	if err != nil {
		return 0, err
	}

	out = tensor.Materialize(out)

	if err := out.Reshape(out.Shape().TotalSize()); err != nil {
		return 0, err
	}

	u8s, err := native.VectorU8(out.(*tensor.Dense))
	if err != nil {
		return 0, err
	}

	if err := binary.Write(w, binary.LittleEndian, u8s); err != nil {
		return 0, err
	}

	return 0, nil
}
gpt-oss (#11672) * bf16 * tests * gpt-oss * enable gptoss for engine * rough estimate * convert to mxfp4 * handle safetensors U8 * clamp glu/linear * update tokenizer * MXFP4 support This implements the Open Compute Microscaling (MX) FP4 format as a tensor type with backend implementations focusing on mulmat and mulmatid on CPU, CUDA, and Metal. * Unit tests for MXFP4 support This exercises various operations and shapes on both CPU and GPU (if detected on the system) * cuda graph * unit test adjustments * cuda: optimize memory access Read 4 bytes at a time (8 elements) when performing mul_mat_vec_mxfp4 * mac: fix crash on old macos versions cblas_sgemm is only supported on v13.3 and up, however bf16 is only supported on v14+ so we were falling back to ggml-blas and crashing on bf16 tensors. Checking for the function being null seems to be the simplest way to condittionally avoid registering the backend. * server: Minimum context length for gptoss This model requires a minimum context length of 8192 to function effectively. Users can set higher values through all normal mechanisms but lower values will be silently reset. * ggml: Multiply by numParallel for gptoss sliding window When computing the graph size estimate, the context size is already multiplied by numParallel so estimates reflect that. However, since sliding window models use a smaller, fixed context size, they need to manually take numParallel into account. * gpt-oss integration includes harmony parser and thinking levels, etc. * fix sync * fix tests * fix lint --------- Co-authored-by: Daniel Hiltgen <daniel@ollama.com> Co-authored-by: Jesse Gross <jesse@ollama.com> Co-authored-by: Devon Rifkin <drifkin@drifkin.net> 2025-08-06 03:21:16 +08:00			`package convert`

			`import (`
			`"bytes"`
			`"cmp"`
			`"encoding/binary"`
			`"io"`
			`"slices"`
			`"strings"`

			`"github.com/ollama/ollama/fs/ggml"`
			`"github.com/pdevine/tensor"`
			`"github.com/pdevine/tensor/native"`
			`)`

			`type gptossModel struct {`
			`ModelParameters`
			HiddenLayers uint32 `json:"num_hidden_layers"`
			HiddenSize uint32 `json:"hidden_size"`
			IntermediateSize uint32 `json:"intermediate_size"`
			AttentionHeads uint32 `json:"num_attention_heads"`
			KeyValueHeads uint32 `json:"num_key_value_heads"`
			HeadDim uint32 `json:"head_dim"`
			Experts uint32 `json:"num_experts"`
			ExpertsPerToken uint32 `json:"experts_per_token"`
			RMSNormEpsilon float32 `json:"rms_norm_eps"`
			InitialContextLength uint32 `json:"initial_context_length"`
			RopeTheta float32 `json:"rope_theta"`
			RopeScalingFactor float32 `json:"rope_scaling_factor"`
			SlidingWindow uint32 `json:"sliding_window"`
			`}`

			`var _ ModelConverter = (*gptossModel)(nil)`

			`func (m gptossModel) KV(t Tokenizer) ggml.KV {`
			`kv := m.ModelParameters.KV(t)`
			`kv["general.architecture"] = "gptoss"`
			`kv["general.file_type"] = uint32(4)`
			`kv["gptoss.context_length"] = uint32(m.RopeScalingFactor * float32(m.InitialContextLength))`
			`kv["gptoss.block_count"] = m.HiddenLayers`
			`kv["gptoss.embedding_length"] = m.HiddenSize`
			`kv["gptoss.feed_forward_length"] = m.IntermediateSize`
			`kv["gptoss.expert_count"] = m.Experts`
			`kv["gptoss.expert_used_count"] = m.ExpertsPerToken`
			`kv["gptoss.attention.head_count"] = m.AttentionHeads`
			`kv["gptoss.attention.head_count_kv"] = m.KeyValueHeads`
			`kv["gptoss.attention.key_length"] = m.HeadDim`
			`kv["gptoss.attention.value_length"] = m.HeadDim`
			`kv["gptoss.attention.layer_norm_rms_epsilon"] = cmp.Or(m.RMSNormEpsilon, 1e-5)`
			`kv["gptoss.attention.sliding_window"] = m.SlidingWindow`
			`kv["gptoss.rope.freq_base"] = m.RopeTheta`
			`kv["gptoss.rope.scaling.factor"] = m.RopeScalingFactor`
			`kv["gptoss.rope.scaling.original_context_length"] = m.InitialContextLength`
			`kv["tokenizer.ggml.bos_token_id"] = uint32(199998) // <\|startoftext\|>`
			`kv["tokenizer.ggml.add_bos_token"] = false`
			`kv["tokenizer.ggml.eos_token_id"] = uint32(199999) // <\|endoftext\|>`
			`kv["tokenizer.ggml.eos_token_ids"] = []int32{`
			`199999, /* <\|endoftext\|> */`
			`200002, /* <\|return\|> */`
			`200012, /* <\|call\|> */`
			`}`
			`kv["tokenizer.ggml.add_eos_token"] = false`
			`return kv`
			`}`

			`func (m gptossModel) Tensors(ts []Tensor) []ggml.Tensor {`
			`var out []*ggml.Tensor`
			`mxfp4s := make(map[string]*mxfp4)`
			`for _, t := range ts {`
			`if strings.HasSuffix(t.Name(), ".blocks") \|\| strings.HasSuffix(t.Name(), ".scales") {`
			`dot := strings.LastIndex(t.Name(), ".")`
			`name, suffix := t.Name()[:dot], t.Name()[dot+1:]`
			`if _, ok := mxfp4s[name]; !ok {`
			`mxfp4s[name] = &mxfp4{}`
			`}`

			`switch suffix {`
			`case "blocks":`
			`mxfp4s[name].blocks = t`
			`case "scales":`
			`mxfp4s[name].scales = t`
			`}`
			`} else {`
			`out = append(out, &ggml.Tensor{`
			`Name: t.Name(),`
			`Kind: t.Kind(),`
			`Shape: t.Shape(),`
			`WriterTo: t,`
			`})`
			`}`
			`}`

			`for name, mxfp4 := range mxfp4s {`
			`dims := mxfp4.blocks.Shape()`
			`out = append(out, &ggml.Tensor{`
			`Name: name,`
			`Kind: uint32(ggml.TensorTypeMXFP4),`
			`Shape: []uint64{dims[0], dims[1], dims[2] * dims[3] * 2},`
			`WriterTo: mxfp4,`
			`})`
			`}`

			`return out`
			`}`

			`func (m *gptossModel) Replacements() []string {`
			`return []string{`
			`// noop replacements so other replacements will not be applied`
			`".blocks", ".blocks",`
			`".scales", ".scales",`
			`// real replacements`
			`"block", "blk",`
			`"attn.norm", "attn_norm",`
			`"attn.qkv", "attn_qkv",`
			`"attn.sinks", "attn_sinks",`
			`"attn.out", "attn_out",`
			`"mlp.norm", "ffn_norm",`
			`"mlp.gate", "ffn_gate_inp",`
			`"mlp.mlp1_", "ffn_gate_up_exps.",`
			`"mlp.mlp2_", "ffn_down_exps.",`
			`"embedding", "token_embd",`
			`"norm", "output_norm",`
			`"unembedding", "output",`
			`"scale", "weight",`
			`}`
			`}`

			`type mxfp4 struct {`
			`blocks, scales Tensor`
			`}`

			`func (m *mxfp4) WriteTo(w io.Writer) (int64, error) {`
			`var b bytes.Buffer`
			`if _, err := m.blocks.WriteTo(&b); err != nil {`
			`return 0, err`
			`}`

			`blocksDims := make([]int, len(m.blocks.Shape()))`
			`for i, d := range m.blocks.Shape() {`
			`blocksDims[i] = int(d)`
			`}`

			`var blocks tensor.Tensor = tensor.New(tensor.WithShape(blocksDims...), tensor.WithBacking(b.Bytes()))`

			`var s bytes.Buffer`
			`if _, err := m.scales.WriteTo(&s); err != nil {`
			`return 0, err`
			`}`

			`scalesDims := slices.Repeat([]int{1}, len(m.blocks.Shape()))`
			`for i, d := range m.scales.Shape() {`
			`scalesDims[i] = int(d)`
			`}`

			`var scales tensor.Tensor = tensor.New(tensor.WithShape(scalesDims...), tensor.WithBacking(s.Bytes()))`

			`out, err := tensor.Concat(3, scales, blocks)`
			`if err != nil {`
			`return 0, err`
			`}`

			`out = tensor.Materialize(out)`

			`if err := out.Reshape(out.Shape().TotalSize()); err != nil {`
			`return 0, err`
			`}`

			`u8s, err := native.VectorU8(out.(*tensor.Dense))`
			`if err != nil {`
			`return 0, err`
			`}`

			`if err := binary.Write(w, binary.LittleEndian, u8s); err != nil {`
			`return 0, err`
			`}`

			`return 0, nil`
			`}`