Safetensors
GGUF
Turkish
llama
Llama-3
instruct
finetune
chatml
gpt4
synthetic data
distillation
function calling
json mode
axolotl
roleplaying
chat
Instructions to use tda45/TdAI with libraries, inference providers, notebooks, and local apps. Follow these links to get started.
- Libraries
- llama-cpp-python
How to use tda45/TdAI with llama-cpp-python:
# !pip install llama-cpp-python from llama_cpp import Llama llm = Llama.from_pretrained( repo_id="tda45/TdAI", filename="llama.cpp/models/ggml-vocab-aquila.gguf", )
output = llm( "Once upon a time,", max_tokens=512, echo=True ) print(output)
- Notebooks
- Google Colab
- Kaggle
- Local Apps Settings
- llama.cpp
How to use tda45/TdAI with llama.cpp:
Install (macOS, Linux)
curl -LsSf https://llama.app/install.sh | sh # Start a local OpenAI-compatible server with a web UI: llama serve -hf tda45/TdAI # Run inference directly in the terminal: llama cli -hf tda45/TdAI
Install from WinGet (Windows)
winget install llama.cpp # Start a local OpenAI-compatible server with a web UI: llama serve -hf tda45/TdAI # Run inference directly in the terminal: llama cli -hf tda45/TdAI
Use pre-built binary
# Download pre-built binary from: # https://github.com/ggerganov/llama.cpp/releases # Start a local OpenAI-compatible server with a web UI: ./llama-server -hf tda45/TdAI # Run inference directly in the terminal: ./llama-cli -hf tda45/TdAI
Build from source code
git clone https://github.com/ggerganov/llama.cpp.git cd llama.cpp cmake -B build cmake --build build -j --target llama-server llama-cli # Start a local OpenAI-compatible server with a web UI: ./build/bin/llama-server -hf tda45/TdAI # Run inference directly in the terminal: ./build/bin/llama-cli -hf tda45/TdAI
Use Docker
docker model run hf.co/tda45/TdAI
- LM Studio
- Jan
- Ollama
How to use tda45/TdAI with Ollama:
ollama run hf.co/tda45/TdAI
- Unsloth Studio
How to use tda45/TdAI with Unsloth Studio:
Install Unsloth Studio (macOS, Linux, WSL)
curl -fsSL https://unsloth.ai/install.sh | sh # Run unsloth studio unsloth studio -H 0.0.0.0 -p 8888 # Then open http://localhost:8888 in your browser # Search for tda45/TdAI to start chatting
Install Unsloth Studio (Windows)
irm https://unsloth.ai/install.ps1 | iex # Run unsloth studio unsloth studio -H 0.0.0.0 -p 8888 # Then open http://localhost:8888 in your browser # Search for tda45/TdAI to start chatting
Using HuggingFace Spaces for Unsloth
# No setup required # Open https://huggingface.co/spaces/unsloth/studio in your browser # Search for tda45/TdAI to start chatting
- Atomic Chat new
- Docker Model Runner
How to use tda45/TdAI with Docker Model Runner:
docker model run hf.co/tda45/TdAI
- Lemonade
How to use tda45/TdAI with Lemonade:
Pull the model
# Download Lemonade from https://lemonade-server.ai/ lemonade pull tda45/TdAI
Run and chat with the model
lemonade run user.TdAI-{{QUANT_TAG}}List all available models
lemonade list
| ggml_tensor * clip_graph_mimovl::build_mm(ggml_tensor * w, ggml_tensor * x) const { | |
| ggml_tensor * cur = ggml_mul_mat(ctx0, w, x); | |
| ggml_mul_mat_set_prec(cur, GGML_PREC_F32); | |
| return cur; | |
| } | |
| // MiMoVL vision tower for MiMo-V2.5 (non-Pro). Qwen2.5-VL-shaped ViT, except: | |
| // 1. GQA in attention (32 Q / 8 KV heads, head_dim 64). | |
| // 2. Per-head attention sinks on every windowed layer. The sinks adjust | |
| // the softmax denominator (equivalently, a virtual extra K column with V=0), | |
| // so they decay attention weight without contributing to the output. | |
| // 3. Per-layer window-attention mode in hparams.wa_pattern_mode: | |
| // -1 -> full, 0 -> row-window+sinks, 1 -> col-window+sinks. | |
| // Col mode transposes the merge-unit grid on entry and restores | |
| // it on exit. Both patch and rotary orderings are pre-computed | |
| // host-side. | |
| // 4. 1D banded sliding window (|q-k| > window_size -> -inf) as a | |
| // single 2D mask broadcast across heads. | |
| // 5. Per-block MLP biases. | |
| ggml_cgraph * clip_graph_mimovl::build() { | |
| GGML_ASSERT(model.patch_embeddings_0 != nullptr); | |
| GGML_ASSERT(model.patch_embeddings_1 != nullptr); | |
| GGML_ASSERT(model.class_embedding == nullptr); | |
| GGML_ASSERT(hparams.n_head_kv > 0); | |
| GGML_ASSERT(n_head % hparams.n_head_kv == 0); | |
| GGML_ASSERT((int) hparams.wa_pattern_mode.size() == n_layer); | |
| const int batch_size = 1; | |
| const int n_pos = n_patches; | |
| const int n_head_kv = hparams.n_head_kv; | |
| const int merge = hparams.n_merge > 0 ? hparams.n_merge : 2; | |
| const int merge_unit = merge * merge; | |
| const int n_units = n_pos / merge_unit; | |
| GGML_ASSERT(n_units * merge_unit == n_pos); | |
| // MiMoVL has head_dim=64 with n_embd=1280, so n_embd is NOT n_head*head_dim | |
| // (the base class's d_head = n_embd/n_head = 40 is wrong here). Derive | |
| // head_dim from the fused QKV projection: rows = (n_head + 2*n_head_kv)*head_dim. | |
| GGML_ASSERT(model.layers[0].qkv_w != nullptr); | |
| const int qkv_rows = model.layers[0].qkv_w->ne[1]; | |
| const int head_dim = qkv_rows / (n_head + 2 * n_head_kv); | |
| GGML_ASSERT(head_dim * (n_head + 2 * n_head_kv) == qkv_rows); | |
| const float attn_scale = 1.0f / std::sqrt((float) head_dim); | |
| const int rope_n_dims = head_dim / 2; | |
| int mrope_sections[4] = {rope_n_dims/2, rope_n_dims/2, 0, 0}; | |
| // Patch embed: Conv3D(kt=2) split into two Conv2D, then interleave-merge | |
| // along the height axis to match the merge-tile token order. | |
| ggml_tensor * inp_raw = build_inp_raw(); | |
| ggml_tensor * inp = ggml_conv_2d(ctx0, model.patch_embeddings_0, inp_raw, | |
| patch_size, patch_size, 0, 0, 1, 1); | |
| { | |
| ggml_tensor * inp_1 = ggml_conv_2d(ctx0, model.patch_embeddings_1, inp_raw, | |
| patch_size, patch_size, 0, 0, 1, 1); | |
| inp = ggml_add(ctx0, inp, inp_1); | |
| GGML_ASSERT(img.nx() % (patch_size * 2) == 0); | |
| GGML_ASSERT(img.ny() % (patch_size * 2) == 0); | |
| inp = ggml_permute(ctx0, inp, 1, 2, 0, 3); // [w,h,c,b] -> [c,w,h,b] | |
| inp = ggml_cont_4d(ctx0, inp, n_embd * 2, n_patches_x / 2, n_patches_y, batch_size); | |
| inp = ggml_reshape_4d(ctx0, inp, n_embd * 2, n_patches_x / 2, 2, batch_size * (n_patches_y / 2)); | |
| inp = ggml_permute(ctx0, inp, 0, 2, 1, 3); | |
| inp = ggml_cont_3d(ctx0, inp, n_embd, n_patches_x * n_patches_y, batch_size); | |
| } | |
| cb(inp, "patch_embed", -1); | |
| ggml_tensor * positions_row = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, n_pos * 4); | |
| ggml_set_name(positions_row, "mimovl_positions_row"); | |
| ggml_set_input(positions_row); | |
| ggml_tensor * positions_col = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, n_pos * 4); | |
| ggml_set_name(positions_col, "mimovl_positions_col"); | |
| ggml_set_input(positions_col); | |
| // idx_col is the col-major merge-unit permutation. Take it as F32 so we can | |
| // derive the inverse permutation in-graph via ggml_argsort; | |
| // ggml_get_rows requires its index tensor to be I32, so cast back as well. | |
| ggml_tensor * idx_col_f = ggml_new_tensor_1d(ctx0, GGML_TYPE_F32, n_units); | |
| ggml_set_name(idx_col_f, "mimovl_idx_col"); | |
| ggml_set_input(idx_col_f); | |
| ggml_tensor * idx_col = ggml_cast(ctx0, idx_col_f, GGML_TYPE_I32); | |
| ggml_tensor * idx_col_inv = ggml_argsort(ctx0, idx_col_f, GGML_SORT_ORDER_ASC); | |
| ggml_tensor * window_mask = ggml_new_tensor_2d(ctx0, GGML_TYPE_F32, n_pos, n_pos); | |
| ggml_set_name(window_mask, "mimovl_window_mask"); | |
| ggml_set_input(window_mask); | |
| ggml_tensor * window_mask_attn = (flash_attn_type == CLIP_FLASH_ATTN_TYPE_ENABLED) | |
| ? ggml_cast(ctx0, window_mask, GGML_TYPE_F16) | |
| : window_mask; | |
| // Reorder helper: permute patches at merge-unit granularity. The patch | |
| // sequence is laid out as n_units groups of merge_unit (=4) consecutive | |
| // patches; the row<->col transpose only permutes whole groups. We keep | |
| // the per-group (h,w) ordering intact by reshaping to | |
| // [n_embd*merge_unit, n_units] before ggml_get_rows. | |
| auto reorder = [&](ggml_tensor * x, ggml_tensor * idx) { | |
| ggml_tensor * y = ggml_reshape_2d(ctx0, x, n_embd * merge_unit, n_units); | |
| y = ggml_get_rows(ctx0, y, idx); | |
| return ggml_reshape_3d(ctx0, y, n_embd, n_pos, batch_size); | |
| }; | |
| ggml_tensor * inpL = inp; | |
| int prev_mode = -1; | |
| for (int il = 0; il < n_layer; il++) { | |
| const auto & layer = model.layers[il]; | |
| const int mode = hparams.wa_pattern_mode[il]; | |
| const bool is_full = (mode == -1); | |
| const bool is_col = (mode == 1); | |
| // Reorder transitions on entry/exit of a col-mode run. | |
| if (is_col && prev_mode != 1) { | |
| inpL = reorder(inpL, idx_col); | |
| cb(inpL, "reorder_to_col", il); | |
| } else if (!is_col && prev_mode == 1) { | |
| inpL = reorder(inpL, idx_col_inv); | |
| cb(inpL, "reorder_to_row", il); | |
| } | |
| ggml_tensor * cur = inpL; | |
| // Pre-attention RMSNorm. | |
| cur = build_norm(cur, layer.ln_1_w, layer.ln_1_b, NORM_TYPE_RMS, eps, il); | |
| cb(cur, "ln1", il); | |
| // Fused QKV with GQA. | |
| ggml_tensor * qkv = build_mm(layer.qkv_w, cur); | |
| qkv = ggml_add(ctx0, qkv, layer.qkv_b); | |
| const size_t row = ggml_row_size(qkv->type, head_dim); | |
| const size_t off_k = ggml_row_size(qkv->type, n_head * head_dim); | |
| const size_t off_v = ggml_row_size(qkv->type, (n_head + n_head_kv) * head_dim); | |
| ggml_tensor * Qcur = ggml_view_3d(ctx0, qkv, head_dim, n_head, n_pos, row, qkv->nb[1], 0); | |
| ggml_tensor * Kcur = ggml_view_3d(ctx0, qkv, head_dim, n_head_kv, n_pos, row, qkv->nb[1], off_k); | |
| ggml_tensor * Vcur = ggml_view_3d(ctx0, qkv, head_dim, n_head_kv, n_pos, row, qkv->nb[1], off_v); | |
| cb(Qcur, "Qcur", il); | |
| cb(Kcur, "Kcur", il); | |
| cb(Vcur, "Vcur", il); | |
| // 2D RoPE | |
| ggml_tensor * pos = is_col ? positions_col : positions_row; | |
| Qcur = ggml_rope_multi(ctx0, Qcur, pos, nullptr, rope_n_dims, mrope_sections, GGML_ROPE_TYPE_VISION, 32768, 10000.0f, 1.0f, 0.0f, 1.0f, 32.0f, 1.0f); | |
| Kcur = ggml_rope_multi(ctx0, Kcur, pos, nullptr, rope_n_dims, mrope_sections, GGML_ROPE_TYPE_VISION, 32768, 10000.0f, 1.0f, 0.0f, 1.0f, 32.0f, 1.0f); | |
| cb(Qcur, "Qcur_rope", il); | |
| cb(Kcur, "Kcur_rope", il); | |
| // Full layers: plain attention. Windowed layers: banded mask and per-head sinks. | |
| ggml_tensor * mask = is_full ? nullptr : window_mask_attn; | |
| ggml_tensor * sinks = is_full ? nullptr : layer.attn_sinks; | |
| if (!is_full) { | |
| GGML_ASSERT(layer.attn_sinks != nullptr); | |
| } | |
| ggml_tensor * attn_out = build_attn(layer.o_w, layer.o_b, Qcur, Kcur, Vcur, mask, attn_scale, il, sinks); | |
| cb(attn_out, "attn_out", il); | |
| // Residual 1. | |
| cur = ggml_add(ctx0, attn_out, inpL); | |
| inpL = cur; | |
| cb(cur, "ffn_inp", il); | |
| // Pre-FFN RMSNorm. | |
| cur = build_norm(cur, layer.ln_2_w, layer.ln_2_b, NORM_TYPE_RMS, eps, il); | |
| cb(cur, "ffn_inp_normed", il); | |
| // SwiGLU MLP with biases | |
| cur = build_ffn(cur, | |
| layer.ff_up_w, layer.ff_up_b, | |
| layer.ff_gate_w, layer.ff_gate_b, | |
| layer.ff_down_w, layer.ff_down_b, | |
| hparams.ffn_op, il); | |
| cb(cur, "ffn_out", il); | |
| // Residual 2. | |
| cur = ggml_add(ctx0, inpL, cur); | |
| cb(cur, "layer_out", il); | |
| inpL = cur; | |
| prev_mode = mode; | |
| } | |
| // If the last block was col-mode, undo the transpose so the merger sees patches in row order. | |
| if (prev_mode == 1) { | |
| inpL = reorder(inpL, idx_col_inv); | |
| cb(inpL, "reorder_to_row_final", -1); | |
| } | |
| // Merger: post-LayerNorm | |
| inpL = build_norm(inpL, model.post_ln_w, model.post_ln_b, NORM_TYPE_NORMAL, 1e-6f, n_layer); | |
| cb(inpL, "post_ln", -1); | |
| // Spatial merge: pack each merge_unit (=4) of patches into a single | |
| // (n_embd*merge_unit)-wide row, then run the 2-layer MLP. | |
| ggml_tensor * embeddings = ggml_reshape_3d(ctx0, inpL, n_embd * merge_unit, n_units, batch_size); | |
| embeddings = build_ffn(embeddings, | |
| model.mm_0_w, nullptr, | |
| nullptr, nullptr, | |
| model.mm_1_w, nullptr, | |
| FFN_GELU, -1); | |
| cb(embeddings, "vit_out", -1); | |
| ggml_build_forward_expand(gf, embeddings); | |
| return gf; | |
| } | |