ollama source for Momentry Core verification
This commit is contained in:
319
model/models/glm4moelite/model.go
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319
model/models/glm4moelite/model.go
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package glm4moelite
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import (
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"errors"
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"math"
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"github.com/ollama/ollama/fs"
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"github.com/ollama/ollama/kvcache"
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"github.com/ollama/ollama/ml"
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"github.com/ollama/ollama/ml/nn"
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"github.com/ollama/ollama/model"
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"github.com/ollama/ollama/model/input"
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"github.com/ollama/ollama/tokenizer"
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)
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var ErrOldModelFormat = errors.New("this model uses a weight format that is no longer supported; please re-download it")
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type Options struct {
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numExpertsUsed int
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numExperts int
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normTopKProb bool
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routedScalingFactor float32
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kvLoraRank,
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qkNopeHeadDim,
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qkRopeHeadDim,
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kqNopeHeadDim,
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qkHeadDim int
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qLoraRank int
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vHeadDim int
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hiddenSize,
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numHeads,
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numKVHeads int
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eps,
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ropeBase float32
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kqScale float64
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}
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func (o Options) applyRotaryPositionEmbeddings(ctx ml.Context, t, p ml.Tensor) ml.Tensor {
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return nn.RoPE(ctx, t, p, o.qkRopeHeadDim, o.ropeBase, 1.0)
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}
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type Attention struct {
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Q *nn.Linear `gguf:"attn_q"`
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QA *nn.Linear `gguf:"attn_q_a"`
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QANorm *nn.RMSNorm `gguf:"attn_q_a_norm"`
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QB *nn.Linear `gguf:"attn_q_b"`
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KVA *nn.Linear `gguf:"attn_kv_a_mqa"`
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KVANorm *nn.RMSNorm `gguf:"attn_kv_a_norm"`
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KB *nn.Linear `gguf:"attn_k_b"`
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VB *nn.Linear `gguf:"attn_v_b"`
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Output *nn.Linear `gguf:"attn_out,alt:attn_output"`
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}
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func (attn *Attention) Forward(ctx ml.Context, hiddenStates, positions ml.Tensor, cache kvcache.Cache, opts *Options) ml.Tensor {
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seqLength := hiddenStates.Dim(1)
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var query ml.Tensor
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if opts.qLoraRank == 0 {
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query = attn.Q.Forward(ctx, hiddenStates)
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} else {
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query = attn.QA.Forward(ctx, hiddenStates)
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query = attn.QANorm.Forward(ctx, query, opts.eps)
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query = attn.QB.Forward(ctx, query)
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}
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query = query.Reshape(ctx, query.Dim(0)/opts.numHeads, opts.numHeads, seqLength)
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queryChunks := query.ChunkSections(ctx, 0, opts.qkNopeHeadDim, opts.qkRopeHeadDim)
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compressedKV := attn.KVA.Forward(ctx, hiddenStates)
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kPass := compressedKV.Slice(ctx, 0, 0, opts.kvLoraRank, 1)
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kRot := compressedKV.View(ctx,
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opts.kvLoraRank*compressedKV.Stride(0), opts.qkRopeHeadDim,
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compressedKV.Stride(1), 1,
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compressedKV.Stride(1), compressedKV.Dim(1),
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)
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qRot := opts.applyRotaryPositionEmbeddings(ctx, queryChunks[1], positions)
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kRot = opts.applyRotaryPositionEmbeddings(ctx, kRot, positions)
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kPass = attn.KVANorm.Forward(ctx, kPass, opts.eps)
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// MLA absorption: absorb K projection into query
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qPass := queryChunks[0].Permute(ctx, 0, 2, 1, 3)
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qPassAbsorb := attn.KB.Forward(ctx, qPass).Permute(ctx, 0, 2, 1, 3)
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query = qRot.Concat(ctx, qPassAbsorb, 0)
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kPass = kPass.Reshape(ctx, opts.kvLoraRank, 1, seqLength)
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key := kRot.Concat(ctx, kPass, 0)
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attention := nn.AttentionWithVMLA(ctx, query, key, kPass, nil, attn.VB.Weight, opts.kqScale, cache)
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attention = attention.Reshape(ctx, attention.Dim(0)*attention.Dim(1), seqLength)
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return attn.Output.Forward(ctx, attention)
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}
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type MLP interface {
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Forward(ml.Context, ml.Tensor, *Options) ml.Tensor
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}
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type sparse struct {
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Router *nn.Linear `gguf:"ffn_gate_inp"`
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Gate *nn.Linear `gguf:"ffn_gate_exps"`
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Up *nn.Linear `gguf:"ffn_up_exps"`
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Down *nn.Linear `gguf:"ffn_down_exps"`
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SharedExpert *dense `gguf:",suf:_shexp"`
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ExpProbsBias ml.Tensor `gguf:"exp_probs_b.bias,alt:exp_probs_b"`
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}
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func (moe *sparse) Moe(ctx ml.Context, hiddenStates, topKIndices, topKWeights ml.Tensor, opts *Options) ml.Tensor {
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hiddenStates = hiddenStates.Reshape(ctx, hiddenStates.Dim(0), 1, hiddenStates.Dim(1))
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upStates := moe.Up.Weight.MulmatID(ctx, hiddenStates, topKIndices)
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hiddenStates = moe.Gate.Weight.MulmatID(ctx, hiddenStates, topKIndices)
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hiddenStates = hiddenStates.SILU(ctx, upStates)
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experts := moe.Down.Weight.MulmatID(ctx, hiddenStates, topKIndices)
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experts = experts.Mul(ctx, topKWeights)
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nextStates := experts.View(ctx, 0, experts.Dim(0), experts.Stride(2), experts.Dim(2))
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for i := 1; i < opts.numExpertsUsed; i++ {
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nextStates = nextStates.Add(ctx, experts.View(ctx, i*experts.Stride(1), experts.Dim(0), experts.Stride(2), experts.Dim(2)))
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}
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return nextStates
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}
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func (moe *sparse) topKIndices(ctx ml.Context, scores ml.Tensor, opts *Options) ml.Tensor {
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if moe.ExpProbsBias != nil {
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scores = scores.Add(ctx, moe.ExpProbsBias)
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}
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topKIndices := scores.TopK(ctx, opts.numExpertsUsed)
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return topKIndices
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}
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func (moe *sparse) Forward(ctx ml.Context, hiddenStates ml.Tensor, opts *Options) ml.Tensor {
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residuals := hiddenStates
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routerLogits := moe.Router.Forward(ctx, hiddenStates)
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scores := routerLogits.Sigmoid(ctx)
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topKIndices := moe.topKIndices(ctx, scores, opts)
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topKWeights := scores.Reshape(ctx, 1, opts.numExperts, hiddenStates.Dim(1)).Rows(ctx, topKIndices)
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if opts.normTopKProb {
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topKWeights = topKWeights.Reshape(ctx, opts.numExpertsUsed, hiddenStates.Dim(1))
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topKWeights = topKWeights.Div(ctx, topKWeights.SumRows(ctx))
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topKWeights = topKWeights.Reshape(ctx, 1, opts.numExpertsUsed, hiddenStates.Dim(1))
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}
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topKWeights = topKWeights.Scale(ctx, float64(opts.routedScalingFactor))
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hiddenStates = moe.Moe(ctx, hiddenStates, topKIndices, topKWeights, opts)
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sharedExpertResult := moe.SharedExpert.Forward(ctx, residuals, opts)
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hiddenStates = hiddenStates.Add(ctx, sharedExpertResult)
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return hiddenStates
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}
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type dense struct {
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Gate *nn.Linear `gguf:"ffn_gate"`
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Up *nn.Linear `gguf:"ffn_up"`
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Down *nn.Linear `gguf:"ffn_down"`
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}
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func (mlp *dense) Forward(ctx ml.Context, hiddenStates ml.Tensor, opts *Options) ml.Tensor {
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hiddenStates = mlp.Gate.Forward(ctx, hiddenStates).SILU(ctx, mlp.Up.Forward(ctx, hiddenStates))
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return mlp.Down.Forward(ctx, hiddenStates)
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}
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type Layer struct {
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AttentionNorm *nn.RMSNorm `gguf:"attn_norm"`
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Attention *Attention
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MLPNorm *nn.RMSNorm `gguf:"ffn_norm"`
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MLP MLP
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}
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func (t *Layer) Forward(ctx ml.Context, hiddenStates, positions, outputs ml.Tensor, cache kvcache.Cache, opts *Options) ml.Tensor {
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residual := hiddenStates
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hiddenStates = t.AttentionNorm.Forward(ctx, hiddenStates, opts.eps)
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hiddenStates = t.Attention.Forward(ctx, hiddenStates, positions, cache, opts)
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if outputs != nil {
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hiddenStates = hiddenStates.Rows(ctx, outputs)
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residual = residual.Rows(ctx, outputs)
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}
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hiddenStates = hiddenStates.Add(ctx, residual)
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residual = hiddenStates
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hiddenStates = t.MLPNorm.Forward(ctx, hiddenStates, opts.eps)
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hiddenStates = t.MLP.Forward(ctx, hiddenStates, opts)
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hiddenStates = hiddenStates.Add(ctx, residual)
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return hiddenStates
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}
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type Model struct {
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model.Base
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tokenizer.Tokenizer
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TokenEmbedding *nn.Embedding `gguf:"token_embd"`
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Layers []Layer `gguf:"blk"`
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OutputNorm *nn.RMSNorm `gguf:"output_norm"`
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Output *nn.Linear `gguf:"output,alt:token_embd"`
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*Options
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}
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func New(c fs.Config) (model.Model, error) {
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layers := make([]Layer, c.Uint("block_count"))
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firstDenseLayerIndex := int(c.Uint("leading_dense_block_count"))
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for i := range layers {
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if i < firstDenseLayerIndex {
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layers[i].MLP = &dense{}
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} else {
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layers[i].MLP = &sparse{}
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}
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}
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keyLength := int(c.Uint("attention.key_length"))
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valueLength := int(c.Uint("attention.value_length"))
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kqScale := 1.0 / math.Sqrt(float64(keyLength))
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var pre []string
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switch c.String("tokenizer.ggml.pre") {
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case "glm4":
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pre = []string{
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`(?i:'s|'t|'re|'ve|'m|'ll|'d)|[^\r\n\p{L}\p{N}]?\p{L}+|\p{N}{1,3}| ?[^\s\p{L}\p{N}]+[\r\n]*|\s*[\r\n]+|\s+(?!\S)|\s+`,
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}
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default:
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return nil, model.ErrUnsupportedTokenizer
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}
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m := Model{
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Tokenizer: tokenizer.NewBytePairEncoding(
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&tokenizer.Vocabulary{
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Values: c.Strings("tokenizer.ggml.tokens"),
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Types: c.Ints("tokenizer.ggml.token_type"),
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Merges: c.Strings("tokenizer.ggml.merges"),
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AddBOS: c.Bool("tokenizer.ggml.add_bos_token", false),
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BOS: []int32{int32(c.Uint("tokenizer.ggml.bos_token_id"))},
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AddEOS: c.Bool("tokenizer.ggml.add_eos_token", false),
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EOS: append(
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[]int32{int32(c.Uint("tokenizer.ggml.eos_token_id"))},
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c.Ints("tokenizer.ggml.eos_token_ids")...,
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),
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},
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pre...,
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),
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Layers: layers,
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Options: &Options{
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hiddenSize: int(c.Uint("embedding_length")),
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numHeads: int(c.Uint("attention.head_count")),
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numKVHeads: int(c.Uint("attention.head_count_kv")),
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eps: c.Float("attention.layer_norm_rms_epsilon"),
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ropeBase: c.Float("rope.freq_base"),
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numExperts: int(c.Uint("expert_count")),
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numExpertsUsed: int(c.Uint("expert_used_count")),
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normTopKProb: c.Bool("expert_weights_norm", true),
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qLoraRank: int(c.Uint("attention.q_lora_rank")),
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kvLoraRank: int(c.Uint("attention.kv_lora_rank")),
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qkHeadDim: keyLength,
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vHeadDim: valueLength,
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qkRopeHeadDim: int(c.Uint("rope.dimension_count")),
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qkNopeHeadDim: keyLength - int(c.Uint("rope.dimension_count")),
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kqNopeHeadDim: keyLength - int(c.Uint("rope.dimension_count")),
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routedScalingFactor: c.Float("expert_weights_scale"),
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kqScale: kqScale,
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},
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}
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m.Cache = kvcache.NewCausalCache(m.Shift)
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return &m, nil
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}
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func (m Model) Shift(ctx ml.Context, layer int, key, shift ml.Tensor) (ml.Tensor, error) {
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return m.applyRotaryPositionEmbeddings(ctx, key, shift), nil
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}
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func (m *Model) Validate() error {
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for _, layer := range m.Layers {
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if layer.Attention != nil && (layer.Attention.KB == nil || layer.Attention.VB == nil) {
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return ErrOldModelFormat
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}
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}
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return nil
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}
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func (m *Model) Forward(ctx ml.Context, batch input.Batch) (ml.Tensor, error) {
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positions := ctx.Input().FromInts(batch.Positions, len(batch.Positions))
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hiddenStates := m.TokenEmbedding.Forward(ctx, batch.Inputs)
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for i, layer := range m.Layers {
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m.Cache.SetLayer(i)
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var outputs ml.Tensor
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if i == len(m.Layers)-1 {
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outputs = batch.Outputs
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}
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hiddenStates = layer.Forward(ctx, hiddenStates, positions, outputs, m.Cache, m.Options)
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}
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hiddenStates = m.OutputNorm.Forward(ctx, hiddenStates, m.eps)
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return m.Output.Forward(ctx, hiddenStates), nil
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}
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func init() {
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model.Register("glm4moelite", New)
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}
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