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ollama37/model/models/llama/model.go
Jesse Gross 1f371ea92f ml: Panic rather than return error on tensor allocation failure 
FromFloatSlice and FromIntSlice return an error if the shape doesn't
match the passed data or if memory can't be allocated. Since these
are inputs, the memory being allocated is system memory rather than VRAM.

In many cases, the caller can't really handle the error and panics.

Empty and Zeros directly panic if they can't allocate memory.

This makes things consistent by panicing for the first two cases,
removing a fair amount of error handling code. This is also consistent
with how Go typically handles these situations.
2025-05-22 14:38:09 -07:00

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package llama
import (
"cmp"
"math"
"github.com/ollama/ollama/fs"
"github.com/ollama/ollama/kvcache"
"github.com/ollama/ollama/ml"
"github.com/ollama/ollama/ml/nn"
"github.com/ollama/ollama/ml/nn/fast"
"github.com/ollama/ollama/ml/nn/rope"
"github.com/ollama/ollama/model"
"github.com/ollama/ollama/model/input"
)
type Options struct {
hiddenSize, numHeads, numKVHeads int
headDim, ropeDim int
eps, ropeBase, ropeScale float32
}
type Model struct {
model.Base
model.BytePairEncoding
TokenEmbedding *nn.Embedding `gguf:"token_embd"`
Layers []Layer `gguf:"blk"`
OutputNorm *nn.RMSNorm `gguf:"output_norm"`
Output *nn.Linear `gguf:"output,alt:token_embd"`
*Options
}
func New(c fs.Config) (model.Model, error) {
m := Model{
BytePairEncoding: model.NewBytePairEncoding(
c.String("tokenizer.ggml.pretokenizer", `(?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+`),
&model.Vocabulary{
Values: c.Strings("tokenizer.ggml.tokens"),
Types: c.Ints("tokenizer.ggml.token_type"),
Merges: c.Strings("tokenizer.ggml.merges"),
AddBOS: c.Bool("tokenizer.ggml.add_bos_token", true),
BOS: []int32{int32(c.Uint("tokenizer.ggml.bos_token_id"))},
AddEOS: c.Bool("tokenizer.ggml.add_eos_token", false),
EOS: append(
[]int32{int32(c.Uint("tokenizer.ggml.eos_token_id"))},
c.Ints("tokenizer.ggml.eos_token_ids")...,
),
},
),
Layers: make([]Layer, c.Uint("block_count")),
Options: &Options{
hiddenSize: int(c.Uint("embedding_length")),
numHeads: int(c.Uint("attention.head_count")),
numKVHeads: int(c.Uint("attention.head_count_kv")),
headDim: int(c.Uint("attention.key_length")),
ropeDim: int(c.Uint("rope.dimension_count")),
eps: c.Float("attention.layer_norm_rms_epsilon"),
ropeBase: c.Float("rope.freq_base"),
ropeScale: c.Float("rope.freq_scale", 1),
},
}
m.Cache = kvcache.NewCausalCache(m.Shift)
return &m, nil
}
type SelfAttention struct {
Query *nn.Linear `gguf:"attn_q"`
Key *nn.Linear `gguf:"attn_k"`
Value *nn.Linear `gguf:"attn_v"`
Output *nn.Linear `gguf:"attn_output"`
RopeFactors ml.Tensor `gguf:"rope_freqs.weight"`
}
func (sa *SelfAttention) Forward(ctx ml.Context, hiddenState, positions ml.Tensor, cache kvcache.Cache, opts *Options) ml.Tensor {
batchSize := hiddenState.Dim(1)
headDim := cmp.Or(opts.headDim, opts.hiddenSize/opts.numHeads)
ropeDim := cmp.Or(opts.ropeDim, headDim)
query := sa.Query.Forward(ctx, hiddenState)
query = query.Reshape(ctx, headDim, opts.numHeads, batchSize)
key := sa.Key.Forward(ctx, hiddenState)
key = key.Reshape(ctx, headDim, opts.numKVHeads, batchSize)
value := sa.Value.Forward(ctx, hiddenState)
value = value.Reshape(ctx, headDim, opts.numKVHeads, batchSize)
query = fast.RoPE(ctx, query, positions, ropeDim, opts.ropeBase, opts.ropeScale, rope.WithFactors(sa.RopeFactors))
key = fast.RoPE(ctx, key, positions, ropeDim, opts.ropeBase, opts.ropeScale, rope.WithFactors(sa.RopeFactors))
attention := nn.Attention(ctx, query, key, value, 1.0/math.Sqrt(float64(headDim)), cache)
attention = attention.Reshape(ctx, headDim*opts.numHeads, batchSize)
return sa.Output.Forward(ctx, attention)
}
func (m *Model) Shift(ctx ml.Context, layer int, key, shift ml.Tensor) (ml.Tensor, error) {
ropeDim := cmp.Or(m.ropeDim, m.hiddenSize/m.numHeads)
return fast.RoPE(ctx, key, shift, ropeDim, m.ropeBase, m.ropeScale, rope.WithFactors(m.Layers[layer].SelfAttention.RopeFactors)), nil
}
type MLP struct {
Up *nn.Linear `gguf:"ffn_up"`
Down *nn.Linear `gguf:"ffn_down"`
Gate *nn.Linear `gguf:"ffn_gate"`
}
func (mlp *MLP) Forward(ctx ml.Context, hiddenState ml.Tensor, opts *Options) ml.Tensor {
hiddenState = mlp.Gate.Forward(ctx, hiddenState).SILU(ctx).Mul(ctx, mlp.Up.Forward(ctx, hiddenState))
return mlp.Down.Forward(ctx, hiddenState)
}
type Layer struct {
AttentionNorm *nn.RMSNorm `gguf:"attn_norm"`
SelfAttention *SelfAttention
MLPNorm *nn.RMSNorm `gguf:"ffn_norm"`
MLP *MLP
}
func (l *Layer) Forward(ctx ml.Context, hiddenState, positions, outputs ml.Tensor, cache kvcache.Cache, opts *Options) ml.Tensor {
residual := hiddenState
hiddenState = l.AttentionNorm.Forward(ctx, hiddenState, opts.eps)
hiddenState = l.SelfAttention.Forward(ctx, hiddenState, positions, cache, opts)
// In the final layer (outputs != nil), optimize by pruning to just the token positions
// we need logits for.
if outputs != nil {
hiddenState = hiddenState.Rows(ctx, outputs)
residual = residual.Rows(ctx, outputs)
}
hiddenState = hiddenState.Add(ctx, residual)
residual = hiddenState
hiddenState = l.MLPNorm.Forward(ctx, hiddenState, opts.eps)
hiddenState = l.MLP.Forward(ctx, hiddenState, opts)
return hiddenState.Add(ctx, residual)
}
func (m *Model) Forward(ctx ml.Context, batch input.Batch) (ml.Tensor, error) {
positions := ctx.Input().FromIntSlice(batch.Positions, len(batch.Positions))
hiddenState := m.TokenEmbedding.Forward(ctx, batch.Inputs)
for i, layer := range m.Layers {
m.Cache.SetLayer(i)
var outputs ml.Tensor
if i == len(m.Layers)-1 {
outputs = ctx.Input().FromIntSlice(batch.Outputs, len(batch.Outputs))
}
hiddenState = layer.Forward(ctx, hiddenState, positions, outputs, m.Cache, m.Options)
}
hiddenState = m.OutputNorm.Forward(ctx, hiddenState, m.eps)
return m.Output.Forward(ctx, hiddenState), nil
}
func init() {
model.Register("llama", New)
}
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