std::regex re("<lora:([^:]+):([^>]+)>");

std::smatch matches;

std::unordered_map<std::string, float> filename2multiplier;

while (std::regex_search(text, matches, re)) {

std::string filename = matches[1].str();

float multiplier = std::stof(matches[2].str());

text = std::regex_replace(text, re, "", std::regex_constants::format_first_only);

if (multiplier == 0.f) {

continue;

}

if (filename2multiplier.find(filename) == filename2multiplier.end()) {

filename2multiplier[filename] = multiplier;

} else {

filename2multiplier[filename] += multiplier;

}

}

return std::make_pair(filename2multiplier, text);

std::vector<std::pair<int, std::u32string>> byte_unicode_pairs;

std::set<int> byte_set;

for (int b = static_cast<int>('!'); b <= static_cast<int>('~'); ++b) {

byte_set.insert(b);

byte_unicode_pairs.push_back(std::pair<int, std::u32string>(b, unicode_value_to_utf32(b)));

}

for (int b = 161; b <= 172; ++b) {

byte_set.insert(b);

byte_unicode_pairs.push_back(std::pair<int, std::u32string>(b, unicode_value_to_utf32(b)));

}

for (int b = 174; b <= 255; ++b) {

byte_set.insert(b);

byte_unicode_pairs.push_back(std::pair<int, std::u32string>(b, unicode_value_to_utf32(b)));

}

int n = 0;

for (int b = 0; b < 256; ++b) {

if (byte_set.find(b) == byte_set.end()) {

byte_unicode_pairs.push_back(std::pair<int, std::u32string>(b, unicode_value_to_utf32(n + 256)));

++n;

}

}

// LOG_DEBUG("byte_unicode_pairs %d", byte_unicode_pairs.size());

return byte_unicode_pairs;

std::map<int, std::u32string> byte_encoder;

std::map<std::u32string, int> byte_decoder;

std::map<std::u32string, int> encoder;

std::map<int, std::u32string> decoder;

std::map<std::pair<std::u32string, std::u32string>, int> bpe_ranks;

std::regex pat;

int encoder_len;

int bpe_len;

const std::string UNK_TOKEN = "<|endoftext|>";

const std::string BOS_TOKEN = "<|startoftext|>";

const std::string EOS_TOKEN = "<|endoftext|>";

const std::string PAD_TOKEN = "<|endoftext|>";

const int UNK_TOKEN_ID = 49407;

const int BOS_TOKEN_ID = 49406;

const int EOS_TOKEN_ID = 49407;

const int PAD_TOKEN_ID = 49407;

static std::string strip(const std::string& str) {

std::string::size_type start = str.find_first_not_of(" \t\n\r\v\f");

std::string::size_type end = str.find_last_not_of(" \t\n\r\v\f");

if (start == std::string::npos) {

// String contains only whitespace characters

return "";

}

return str.substr(start, end - start + 1);

}

static std::string whitespace_clean(std::string text) {

text = std::regex_replace(text, std::regex(R"(\s+)"), " ");

text = strip(text);

return text;

}

static std::set<std::pair<std::u32string, std::u32string>> get_pairs(const std::vector<std::u32string>& subwords) {

std::set<std::pair<std::u32string, std::u32string>> pairs;

if (subwords.size() == 0) {

return pairs;

}

std::u32string prev_subword = subwords[0];

for (int i = 1; i < subwords.size(); i++) {

std::u32string subword = subwords[i];

std::pair<std::u32string, std::u32string> pair(prev_subword, subword);

pairs.insert(pair);

prev_subword = subword;

}

return pairs;

}

CLIPTokenizer(int pad_token_id = 49407, const std::string& merges_utf8_str = "")

: PAD_TOKEN_ID(pad_token_id) {

if (merges_utf8_str.size() > 0) {

load_from_merges(merges_utf8_str);

} else {

load_from_merges(ModelLoader::load_merges());

}

}

void load_from_merges(const std::string& merges_utf8_str) {

auto byte_unicode_pairs = bytes_to_unicode();

// printf("byte_unicode_pairs have %lu pairs \n", byte_unicode_pairs.size());

byte_encoder = std::map<int, std::u32string>(byte_unicode_pairs.begin(), byte_unicode_pairs.end());

for (auto& pair : byte_unicode_pairs) {

byte_decoder[pair.second] = pair.first;

}

// for (auto & pair: byte_unicode_pairs) {

// std::cout << pair.first << ": " << pair.second << std::endl;

// }

std::vector<std::u32string> merges;

size_t start = 0;

size_t pos;

std::u32string merges_utf32_str = utf8_to_utf32(merges_utf8_str);

while ((pos = merges_utf32_str.find('\n', start)) != std::string::npos) {

merges.push_back(merges_utf32_str.substr(start, pos - start));

start = pos + 1;

}

// LOG_DEBUG("merges size %llu", merges.size());

GGML_ASSERT(merges.size() == 48895);

merges = std::vector<std::u32string>(merges.begin() + 1, merges.end());

std::vector<std::pair<std::u32string, std::u32string>> merge_pairs;

for (const auto& merge : merges) {

size_t space_pos = merge.find(' ');

merge_pairs.emplace_back(merge.substr(0, space_pos), merge.substr(space_pos + 1));

// LOG_DEBUG("%s", utf32_to_utf8(merge.substr(space_pos + 1)).c_str());

// printf("%s :: %s | %s \n", utf32_to_utf8(merge).c_str(), utf32_to_utf8(merge.substr(0, space_pos)).c_str(),

// utf32_to_utf8(merge.substr(space_pos + 1)).c_str());

}

std::vector<std::u32string> vocab;

for (const auto& pair : byte_unicode_pairs) {

vocab.push_back(pair.second);

}

for (const auto& pair : byte_unicode_pairs) {

vocab.push_back(pair.second + utf8_to_utf32("</w>"));

}

for (const auto& merge : merge_pairs) {

vocab.push_back(merge.first + merge.second);

}

vocab.push_back(utf8_to_utf32("<|startoftext|>"));

vocab.push_back(utf8_to_utf32("<|endoftext|>"));

LOG_DEBUG("vocab size: %llu", vocab.size());

int i = 0;

for (const auto& token : vocab) {

encoder[token] = i;

decoder[i] = token;

i++;

}

encoder_len = i;

auto it = encoder.find(utf8_to_utf32("img</w>"));

if (it != encoder.end()) {

LOG_DEBUG(" trigger word img already in vocab");

} else {

LOG_DEBUG(" trigger word img not in vocab yet");

}

int rank = 0;

for (const auto& merge : merge_pairs) {

bpe_ranks[merge] = rank++;

}

bpe_len = rank;

};

void add_token(const std::string& text) {

std::u32string token = utf8_to_utf32(text);

auto it = encoder.find(token);

if (it != encoder.end()) {

encoder[token] = encoder_len;

decoder[encoder_len] = token;

encoder_len++;

}

}

std::u32string bpe(const std::u32string& token) {

std::vector<std::u32string> word;

for (int i = 0; i < token.size() - 1; i++) {

word.emplace_back(1, token[i]);

}

word.push_back(token.substr(token.size() - 1) + utf8_to_utf32("</w>"));

std::set<std::pair<std::u32string, std::u32string>> pairs = get_pairs(word);

if (pairs.empty()) {

return token + utf8_to_utf32("</w>");

}

while (true) {

auto min_pair_iter = std::min_element(pairs.begin(),

pairs.end(),

[&](const std::pair<std::u32string, std::u32string>& a,

const std::pair<std::u32string, std::u32string>& b) {

if (bpe_ranks.find(a) == bpe_ranks.end()) {

return false;

} else if (bpe_ranks.find(b) == bpe_ranks.end()) {

return true;

}

return bpe_ranks.at(a) < bpe_ranks.at(b);

});

const std::pair<std::u32string, std::u32string>& bigram = *min_pair_iter;

if (bpe_ranks.find(bigram) == bpe_ranks.end()) {

break;

}

std::u32string first = bigram.first;

std::u32string second = bigram.second;

std::vector<std::u32string> new_word;

int32_t i = 0;

while (i < word.size()) {

auto it = std::find(word.begin() + i, word.end(), first);

if (it == word.end()) {

new_word.insert(new_word.end(), word.begin() + i, word.end());

break;

}

new_word.insert(new_word.end(), word.begin() + i, it);

i = static_cast<int32_t>(std::distance(word.begin(), it));

if (word[i] == first && i < static_cast<int32_t>(word.size()) - 1 && word[i + 1] == second) {

new_word.push_back(first + second);

i += 2;

} else {

new_word.push_back(word[i]);

i += 1;

}

}

word = new_word;

if (word.size() == 1) {

break;

}

pairs = get_pairs(word);

}

std::u32string result;

for (int i = 0; i < word.size(); i++) {

result += word[i];

if (i != word.size() - 1) {

result += utf8_to_utf32(" ");

}

}

return result;

}

std::vector<int> tokenize(std::string text,

on_new_token_cb_t on_new_token_cb,

size_t max_length = 0,

bool padding = false) {

std::vector<int32_t> tokens = encode(text, on_new_token_cb);

tokens.insert(tokens.begin(), BOS_TOKEN_ID);

if (max_length > 0) {

if (tokens.size() > max_length - 1) {

tokens.resize(max_length - 1);

tokens.push_back(EOS_TOKEN_ID);

} else {

tokens.push_back(EOS_TOKEN_ID);

if (padding) {

tokens.insert(tokens.end(), max_length - tokens.size(), PAD_TOKEN_ID);

}

}

}

return tokens;

}

void pad_tokens(std::vector<int>& tokens,

std::vector<float>& weights,

size_t max_length = 0,

bool padding = false) {

if (max_length > 0 && padding) {

size_t n = std::ceil(tokens.size() * 1.0 / (max_length - 2));

if (n == 0) {

n = 1;

}

size_t length = max_length * n;

LOG_DEBUG("token length: %llu", length);

std::vector<int> new_tokens;

std::vector<float> new_weights;

new_tokens.push_back(BOS_TOKEN_ID);

new_weights.push_back(1.0);

int token_idx = 0;

for (int i = 1; i < length; i++) {

if (token_idx >= tokens.size()) {

break;

}

if (i % max_length == 0) {

new_tokens.push_back(BOS_TOKEN_ID);

new_weights.push_back(1.0);

} else if (i % max_length == max_length - 1) {

new_tokens.push_back(EOS_TOKEN_ID);

new_weights.push_back(1.0);

} else {

new_tokens.push_back(tokens[token_idx]);

new_weights.push_back(weights[token_idx]);

token_idx++;

}

}

new_tokens.push_back(EOS_TOKEN_ID);

new_weights.push_back(1.0);

tokens = new_tokens;

weights = new_weights;

if (padding) {

tokens.insert(tokens.end(), length - tokens.size(), PAD_TOKEN_ID);

weights.insert(weights.end(), length - weights.size(), 1.0);

}

}

}

std::string clean_up_tokenization(std::string& text) {

std::regex pattern(R"( ,)");

// Replace " ," with ","

std::string result = std::regex_replace(text, pattern, ",");

return result;

}

std::string decode(const std::vector<int>& tokens) {

std::string text = "";

for (int t : tokens) {

if (t == 49406 || t == 49407)

continue;

std::u32string ts = decoder[t];

// printf("%d, %s \n", t, utf32_to_utf8(ts).c_str());

std::string s = utf32_to_utf8(ts);

if (s.length() >= 4) {

if (ends_with(s, "</w>")) {

text += s.replace(s.length() - 4, s.length() - 1, "") + " ";

} else {

text += s;

}

} else {

text += " " + s;

}

}

// std::vector<unsigned char> bytes;

// for (auto c : text){

// bytes.push_back(byte_decoder[c]);

// }

// std::string s((char *)bytes.data());

// std::string s = "";

text = clean_up_tokenization(text);

return trim(text);

}

std::vector<int> encode(std::string text, on_new_token_cb_t on_new_token_cb) {

std::string original_text = text;

std::vector<int32_t> bpe_tokens;

text = whitespace_clean(text);

std::transform(text.begin(), text.end(), text.begin(), [](unsigned char c) { return std::tolower(c); });

std::regex pat(R"(<\|startoftext\|>|<\|endoftext\|>|'s|'t|'re|'ve|'m|'ll|'d|[[:alpha:]]+|[[:digit:]]|[^[:space:][:alpha:][:digit:]]+)",

std::regex::icase);

std::smatch matches;

std::string str = text;

std::vector<std::string> token_strs;

while (std::regex_search(str, matches, pat)) {

bool skip = on_new_token_cb(str, bpe_tokens);

if (skip) {

continue;

}

for (auto& token : matches) {

std::string token_str = token.str();

std::u32string utf32_token;

for (int i = 0; i < token_str.length(); i++) {

unsigned char b = token_str[i];

utf32_token += byte_encoder[b];

}

auto bpe_strs = bpe(utf32_token);

size_t start = 0;

size_t pos;

while ((pos = bpe_strs.find(' ', start)) != std::u32string::npos) {

auto bpe_str = bpe_strs.substr(start, pos - start);

bpe_tokens.push_back(encoder[bpe_str]);

token_strs.push_back(utf32_to_utf8(bpe_str));

start = pos + 1;

}

auto bpe_str = bpe_strs.substr(start, bpe_strs.size() - start);

bpe_tokens.push_back(encoder[bpe_str]);

token_strs.push_back(utf32_to_utf8(bpe_str));

}

str = matches.suffix();

}

std::stringstream ss;

ss << "[";

for (auto token : token_strs) {

ss << "\"" << token << "\", ";

}

ss << "]";

// LOG_DEBUG("split prompt \"%s\" to tokens %s", original_text.c_str(), ss.str().c_str());

// printf("split prompt \"%s\" to tokens %s \n", original_text.c_str(), ss.str().c_str());

return bpe_tokens;

}

bool use_gelu;

CLIPMLP(int64_t d_model, int64_t intermediate_size) {

blocks["fc1"] = std::shared_ptr<GGMLBlock>(new Linear(d_model, intermediate_size));

blocks["fc2"] = std::shared_ptr<GGMLBlock>(new Linear(intermediate_size, d_model));

if (d_model == 1024 || d_model == 1280) { // SD 2.x

use_gelu = true;

} else { // SD 1.x

use_gelu = false;

}

}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* x) {

// x: [N, n_token, d_model]

auto fc1 = std::dynamic_pointer_cast<Linear>(blocks["fc1"]);

auto fc2 = std::dynamic_pointer_cast<Linear>(blocks["fc2"]);

x = fc1->forward(ctx, x);

if (use_gelu) {

x = ggml_gelu_inplace(ctx, x);

} else {

x = ggml_gelu_quick_inplace(ctx, x);

}

x = fc2->forward(ctx, x);

return x;

}

int64_t d_model; // hidden_size/embed_dim

int64_t n_head;

int64_t intermediate_size;

CLIPLayer(int64_t d_model,

int64_t n_head,

int64_t intermediate_size)

: d_model(d_model),

n_head(n_head),

intermediate_size(intermediate_size) {

blocks["self_attn"] = std::shared_ptr<GGMLBlock>(new MultiheadAttention(d_model, n_head, true, true));

blocks["layer_norm1"] = std::shared_ptr<GGMLBlock>(new LayerNorm(d_model));

blocks["layer_norm2"] = std::shared_ptr<GGMLBlock>(new LayerNorm(d_model));

blocks["mlp"] = std::shared_ptr<GGMLBlock>(new CLIPMLP(d_model, intermediate_size));

}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* x, bool mask = true) {

// x: [N, n_token, d_model]

auto self_attn = std::dynamic_pointer_cast<MultiheadAttention>(blocks["self_attn"]);

auto layer_norm1 = std::dynamic_pointer_cast<LayerNorm>(blocks["layer_norm1"]);

auto layer_norm2 = std::dynamic_pointer_cast<LayerNorm>(blocks["layer_norm2"]);

auto mlp = std::dynamic_pointer_cast<CLIPMLP>(blocks["mlp"]);

x = ggml_add(ctx, x, self_attn->forward(ctx, layer_norm1->forward(ctx, x), mask));

x = ggml_add(ctx, x, mlp->forward(ctx, layer_norm2->forward(ctx, x)));

return x;

}

int64_t n_layer;

CLIPEncoder(int64_t n_layer,

int64_t d_model,

int64_t n_head,

int64_t intermediate_size)

: n_layer(n_layer) {

for (int i = 0; i < n_layer; i++) {

std::string name = "layers." + std::to_string(i);

blocks[name] = std::shared_ptr<GGMLBlock>(new CLIPLayer(d_model, n_head, intermediate_size));

}

}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* x, int clip_skip = -1, bool mask = true) {

// x: [N, n_token, d_model]

int layer_idx = n_layer - 1;

// LOG_DEBUG("clip_skip %d", clip_skip);

if (clip_skip > 0) {

layer_idx = n_layer - clip_skip;

}

for (int i = 0; i < n_layer; i++) {

// LOG_DEBUG("layer %d", i);

if (i == layer_idx + 1) {

break;

}

std::string name = "layers." + std::to_string(i);

auto layer = std::dynamic_pointer_cast<CLIPLayer>(blocks[name]);

x = layer->forward(ctx, x, mask); // [N, n_token, d_model]

// LOG_DEBUG("layer %d", i);

}

return x;

}

int64_t embed_dim;

int64_t vocab_size;

int64_t num_positions;

void init_params(struct ggml_context* ctx, std::map<std::string, enum ggml_type>& tensor_types, const std::string prefix = "") {

enum ggml_type token_wtype = (tensor_types.find(prefix + "token_embedding.weight") != tensor_types.end()) ? tensor_types[prefix + "token_embedding.weight"] : GGML_TYPE_F32;

enum ggml_type position_wtype = GGML_TYPE_F32; //(tensor_types.find(prefix + "position_embedding.weight") != tensor_types.end()) ? tensor_types[prefix + "position_embedding.weight"] : GGML_TYPE_F32;

params["token_embedding.weight"] = ggml_new_tensor_2d(ctx, token_wtype, embed_dim, vocab_size);

params["position_embedding.weight"] = ggml_new_tensor_2d(ctx, position_wtype, embed_dim, num_positions);

}

CLIPEmbeddings(int64_t embed_dim,

int64_t vocab_size = 49408,

int64_t num_positions = 77)

: embed_dim(embed_dim),

vocab_size(vocab_size),

num_positions(num_positions) {

}

struct ggml_tensor* get_token_embed_weight() {

return params["token_embedding.weight"];

}

struct ggml_tensor* forward(struct ggml_context* ctx,

struct ggml_tensor* input_ids,

struct ggml_tensor* custom_embed_weight) {

// input_ids: [N, n_token]

auto token_embed_weight = params["token_embedding.weight"];

auto position_embed_weight = params["position_embedding.weight"];

GGML_ASSERT(input_ids->ne[0] == position_embed_weight->ne[1]);

input_ids = ggml_reshape_3d(ctx, input_ids, input_ids->ne[0], 1, input_ids->ne[1]);

auto token_embedding = ggml_get_rows(ctx, custom_embed_weight != NULL ? custom_embed_weight : token_embed_weight, input_ids);

token_embedding = ggml_reshape_3d(ctx, token_embedding, token_embedding->ne[0], token_embedding->ne[1], token_embedding->ne[3]);

// token_embedding + position_embedding

auto x = ggml_add(ctx,

token_embedding,

position_embed_weight); // [N, n_token, embed_dim]

return x;

}

int64_t embed_dim;

int64_t num_channels;

int64_t patch_size;

int64_t image_size;

int64_t num_patches;

int64_t num_positions;

void init_params(struct ggml_context* ctx, std::map<std::string, enum ggml_type>& tensor_types, const std::string prefix = "") {

enum ggml_type patch_wtype = GGML_TYPE_F16; // tensor_types.find(prefix + "patch_embedding.weight") != tensor_types.end() ? tensor_types[prefix + "patch_embedding.weight"] : GGML_TYPE_F16;

enum ggml_type class_wtype = GGML_TYPE_F32; // tensor_types.find(prefix + "class_embedding") != tensor_types.end() ? tensor_types[prefix + "class_embedding"] : GGML_TYPE_F32;

enum ggml_type position_wtype = GGML_TYPE_F32; // tensor_types.find(prefix + "position_embedding.weight") != tensor_types.end() ? tensor_types[prefix + "position_embedding.weight"] : GGML_TYPE_F32;

params["patch_embedding.weight"] = ggml_new_tensor_4d(ctx, patch_wtype, patch_size, patch_size, num_channels, embed_dim);

params["class_embedding"] = ggml_new_tensor_1d(ctx, class_wtype, embed_dim);

params["position_embedding.weight"] = ggml_new_tensor_2d(ctx, position_wtype, embed_dim, num_positions);

}

CLIPVisionEmbeddings(int64_t embed_dim,

int64_t num_channels = 3,

int64_t patch_size = 14,

int64_t image_size = 224)

: embed_dim(embed_dim),

num_channels(num_channels),

patch_size(patch_size),

image_size(image_size) {

num_patches = (image_size / patch_size) * (image_size / patch_size);

num_positions = num_patches + 1;

}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* pixel_values) {

// pixel_values: [N, num_channels, image_size, image_size]

// return: [N, num_positions, embed_dim]

GGML_ASSERT(pixel_values->ne[0] == image_size && pixel_values->ne[1] == image_size && pixel_values->ne[2] == num_channels);

auto patch_embed_weight = params["patch_embedding.weight"];

auto class_embed_weight = params["class_embedding"];

auto position_embed_weight = params["position_embedding.weight"];

// concat(patch_embedding, class_embedding) + position_embedding

struct ggml_tensor* patch_embedding;

int64_t N = pixel_values->ne[3];

patch_embedding = ggml_nn_conv_2d(ctx, pixel_values, patch_embed_weight, NULL, patch_size, patch_size); // [N, embed_dim, image_size // pacht_size, image_size // pacht_size]

patch_embedding = ggml_reshape_3d(ctx, patch_embedding, num_patches, embed_dim, N); // [N, embed_dim, num_patches]

patch_embedding = ggml_cont(ctx, ggml_permute(ctx, patch_embedding, 1, 0, 2, 3)); // [N, num_patches, embed_dim]

patch_embedding = ggml_reshape_4d(ctx, patch_embedding, 1, embed_dim, num_patches, N); // [N, num_patches, embed_dim, 1]

struct ggml_tensor* class_embedding = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, embed_dim, N);

class_embedding = ggml_repeat(ctx, class_embed_weight, class_embedding); // [N, embed_dim]

class_embedding = ggml_reshape_4d(ctx, class_embedding, 1, embed_dim, 1, N); // [N, 1, embed_dim, 1]

struct ggml_tensor* x = ggml_concat(ctx, class_embedding, patch_embedding, 2); // [N, num_positions, embed_dim, 1]

x = ggml_reshape_3d(ctx, x, embed_dim, num_positions, N); // [N, num_positions, embed_dim]

x = ggml_add(ctx, x, position_embed_weight);

return x; // [N, num_positions, embed_dim]

}

OPENAI_CLIP_VIT_L_14, // SD 1.x and SDXL

OPEN_CLIP_VIT_H_14, // SD 2.x

OPEN_CLIP_VIT_BIGG_14, // SDXL

void init_params(struct ggml_context* ctx, std::map<std::string, enum ggml_type>& tensor_types, const std::string prefix = "") {

if (version == OPEN_CLIP_VIT_BIGG_14) {

enum ggml_type wtype = GGML_TYPE_F32; // tensor_types.find(prefix + "text_projection") != tensor_types.end() ? tensor_types[prefix + "text_projection"] : GGML_TYPE_F32;

params["text_projection"] = ggml_new_tensor_2d(ctx, wtype, projection_dim, hidden_size);

}

}

CLIPVersion version = OPENAI_CLIP_VIT_L_14;

// network hparams

int32_t vocab_size = 49408;

int32_t n_token = 77; // max_position_embeddings

int32_t hidden_size = 768;

int32_t intermediate_size = 3072;

int32_t n_head = 12;

int32_t n_layer = 12; // num_hidden_layers

int32_t projection_dim = 1280; // only for OPEN_CLIP_VIT_BIGG_14

int32_t clip_skip = -1;

bool with_final_ln = true;

CLIPTextModel(CLIPVersion version = OPENAI_CLIP_VIT_L_14,

int clip_skip_value = -1,

bool with_final_ln = true)

: version(version), with_final_ln(with_final_ln) {

if (version == OPEN_CLIP_VIT_H_14) {

hidden_size = 1024;

intermediate_size = 4096;

n_head = 16;

n_layer = 24;

} else if (version == OPEN_CLIP_VIT_BIGG_14) { // CLIPTextModelWithProjection

hidden_size = 1280;

intermediate_size = 5120;

n_head = 20;

n_layer = 32;

}

set_clip_skip(clip_skip_value);

blocks["embeddings"] = std::shared_ptr<GGMLBlock>(new CLIPEmbeddings(hidden_size, vocab_size, n_token));

blocks["encoder"] = std::shared_ptr<GGMLBlock>(new CLIPEncoder(n_layer, hidden_size, n_head, intermediate_size));

blocks["final_layer_norm"] = std::shared_ptr<GGMLBlock>(new LayerNorm(hidden_size));

}

void set_clip_skip(int skip) {

if (skip <= 0) {

return;

}

clip_skip = skip;

}

struct ggml_tensor* get_token_embed_weight() {

auto embeddings = std::dynamic_pointer_cast<CLIPEmbeddings>(blocks["embeddings"]);

return embeddings->get_token_embed_weight();

}

struct ggml_tensor* forward(struct ggml_context* ctx,

struct ggml_tensor* input_ids,

struct ggml_tensor* tkn_embeddings,

size_t max_token_idx = 0,

bool return_pooled = false) {

// input_ids: [N, n_token]

auto embeddings = std::dynamic_pointer_cast<CLIPEmbeddings>(blocks["embeddings"]);

auto encoder = std::dynamic_pointer_cast<CLIPEncoder>(blocks["encoder"]);

auto final_layer_norm = std::dynamic_pointer_cast<LayerNorm>(blocks["final_layer_norm"]);

auto x = embeddings->forward(ctx, input_ids, tkn_embeddings); // [N, n_token, hidden_size]

x = encoder->forward(ctx, x, return_pooled ? -1 : clip_skip, true);

if (return_pooled || with_final_ln) {

x = final_layer_norm->forward(ctx, x);

}

if (return_pooled) {

auto text_projection = params["text_projection"];

ggml_tensor* pooled = ggml_view_1d(ctx, x, hidden_size, x->nb[1] * max_token_idx);

if (text_projection != NULL) {

pooled = ggml_nn_linear(ctx, pooled, text_projection, NULL);

} else {

LOG_DEBUG("Missing text_projection matrix, assuming identity...");

}

return pooled; // [hidden_size, 1, 1]

}

return x; // [N, n_token, hidden_size]

}

// network hparams

int32_t num_channels = 3;

int32_t patch_size = 14;

int32_t image_size = 224;

int32_t num_positions = 257; // (image_size / patch_size)^2 + 1

int32_t hidden_size = 1024;

int32_t intermediate_size = 4096;

int32_t n_head = 16;

int32_t n_layer = 24;

CLIPVisionModel(CLIPVersion version = OPENAI_CLIP_VIT_L_14) {

if (version == OPEN_CLIP_VIT_H_14) {

hidden_size = 1280;

intermediate_size = 5120;

n_head = 16;

n_layer = 32;

} else if (version == OPEN_CLIP_VIT_BIGG_14) {

hidden_size = 1664;

intermediate_size = 8192;

n_head = 16;

n_layer = 48;

}

blocks["embeddings"] = std::shared_ptr<GGMLBlock>(new CLIPVisionEmbeddings(hidden_size, num_channels, patch_size, image_size));

blocks["pre_layernorm"] = std::shared_ptr<GGMLBlock>(new LayerNorm(hidden_size));

blocks["encoder"] = std::shared_ptr<GGMLBlock>(new CLIPEncoder(n_layer, hidden_size, n_head, intermediate_size));

blocks["post_layernorm"] = std::shared_ptr<GGMLBlock>(new LayerNorm(hidden_size));

}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* pixel_values, bool return_pooled = true) {

// pixel_values: [N, num_channels, image_size, image_size]

auto embeddings = std::dynamic_pointer_cast<CLIPVisionEmbeddings>(blocks["embeddings"]);

auto pre_layernorm = std::dynamic_pointer_cast<LayerNorm>(blocks["pre_layernorm"]);

auto encoder = std::dynamic_pointer_cast<CLIPEncoder>(blocks["encoder"]);

auto post_layernorm = std::dynamic_pointer_cast<LayerNorm>(blocks["post_layernorm"]);

auto x = embeddings->forward(ctx, pixel_values); // [N, num_positions, embed_dim]

x = pre_layernorm->forward(ctx, x);

x = encoder->forward(ctx, x, -1, false);

// print_ggml_tensor(x, true, "ClipVisionModel x: ");

auto last_hidden_state = x;

x = post_layernorm->forward(ctx, x); // [N, n_token, hidden_size]

GGML_ASSERT(x->ne[3] == 1);

if (return_pooled) {

ggml_tensor* pooled = ggml_cont(ctx, ggml_view_2d(ctx, x, x->ne[0], x->ne[2], x->nb[2], 0));

return pooled; // [N, hidden_size]

} else {

// return x; // [N, n_token, hidden_size]

return last_hidden_state; // [N, n_token, hidden_size]

}

}

int64_t in_features;

int64_t out_features;

bool transpose_weight;

void init_params(struct ggml_context* ctx, std::map<std::string, enum ggml_type>& tensor_types, const std::string prefix = "") {

enum ggml_type wtype = tensor_types.find(prefix + "weight") != tensor_types.end() ? tensor_types[prefix + "weight"] : GGML_TYPE_F32;

if (transpose_weight) {

params["weight"] = ggml_new_tensor_2d(ctx, wtype, out_features, in_features);

} else {

params["weight"] = ggml_new_tensor_2d(ctx, wtype, in_features, out_features);

}

}

CLIPProjection(int64_t in_features,

int64_t out_features,

bool transpose_weight = false)

: in_features(in_features),

out_features(out_features),

transpose_weight(transpose_weight) {}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* x) {

struct ggml_tensor* w = params["weight"];

if (transpose_weight) {

w = ggml_cont(ctx, ggml_transpose(ctx, w));

}

return ggml_nn_linear(ctx, x, w, NULL);

}

int32_t hidden_size = 1024;

int32_t projection_dim = 768;

int32_t image_size = 224;

CLIPVisionModelProjection(CLIPVersion version = OPENAI_CLIP_VIT_L_14,

bool transpose_proj_w = false) {

if (version == OPEN_CLIP_VIT_H_14) {

hidden_size = 1280;

projection_dim = 1024;

} else if (version == OPEN_CLIP_VIT_BIGG_14) {

hidden_size = 1664;

}

blocks["vision_model"] = std::shared_ptr<GGMLBlock>(new CLIPVisionModel(version));

blocks["visual_projection"] = std::shared_ptr<GGMLBlock>(new CLIPProjection(hidden_size, projection_dim, transpose_proj_w));

}

struct ggml_tensor* forward(struct ggml_context* ctx, struct ggml_tensor* pixel_values) {

// pixel_values: [N, num_channels, image_size, image_size]

// return: [N, projection_dim]

auto vision_model = std::dynamic_pointer_cast<CLIPVisionModel>(blocks["vision_model"]);

auto visual_projection = std::dynamic_pointer_cast<CLIPProjection>(blocks["visual_projection"]);

auto x = vision_model->forward(ctx, pixel_values); // [N, hidden_size]

x = visual_projection->forward(ctx, x); // [N, projection_dim]

return x; // [N, projection_dim]

}

CLIPTextModel model;

CLIPTextModelRunner(ggml_backend_t backend,

std::map<std::string, enum ggml_type>& tensor_types,

const std::string prefix,

CLIPVersion version = OPENAI_CLIP_VIT_L_14,

int clip_skip_value = 1,

bool with_final_ln = true)

: GGMLRunner(backend), model(version, clip_skip_value, with_final_ln) {

model.init(params_ctx, tensor_types, prefix);

}

std::string get_desc() {

return "clip";

}

void set_clip_skip(int clip_skip) {

model.set_clip_skip(clip_skip);

}

void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors, const std::string prefix) {

model.get_param_tensors(tensors, prefix);

}

struct ggml_tensor* forward(struct ggml_context* ctx,

struct ggml_tensor* input_ids,

struct ggml_tensor* embeddings,

size_t max_token_idx = 0,

bool return_pooled = false) {

size_t N = input_ids->ne[1];

size_t n_token = input_ids->ne[0];

if (input_ids->ne[0] > model.n_token) {

GGML_ASSERT(input_ids->ne[0] % model.n_token == 0);

input_ids = ggml_reshape_2d(ctx, input_ids, model.n_token, input_ids->ne[0] / model.n_token);

}

return model.forward(ctx, input_ids, embeddings, max_token_idx, return_pooled);

}

struct ggml_cgraph* build_graph(struct ggml_tensor* input_ids,

int num_custom_embeddings = 0,

void* custom_embeddings_data = NULL,

size_t max_token_idx = 0,

bool return_pooled = false) {

struct ggml_cgraph* gf = ggml_new_graph(compute_ctx);

input_ids = to_backend(input_ids);

struct ggml_tensor* embeddings = NULL;

if (num_custom_embeddings > 0 && custom_embeddings_data != NULL) {

auto token_embed_weight = model.get_token_embed_weight();

auto custom_embeddings = ggml_new_tensor_2d(compute_ctx,

token_embed_weight->type,

model.hidden_size,

num_custom_embeddings);

set_backend_tensor_data(custom_embeddings, custom_embeddings_data);

// concatenate custom embeddings

embeddings = ggml_concat(compute_ctx, token_embed_weight, custom_embeddings, 1);

}

struct ggml_tensor* hidden_states = forward(compute_ctx, input_ids, embeddings, max_token_idx, return_pooled);

ggml_build_forward_expand(gf, hidden_states);

return gf;

}

void compute(const int n_threads,

struct ggml_tensor* input_ids,

int num_custom_embeddings,

void* custom_embeddings_data,

size_t max_token_idx,

bool return_pooled,

ggml_tensor** output,

ggml_context* output_ctx = NULL) {

auto get_graph = [&]() -> struct ggml_cgraph* {

return build_graph(input_ids, num_custom_embeddings, custom_embeddings_data, max_token_idx, return_pooled);

};

GGMLRunner::compute(get_graph, n_threads, true, output, output_ctx);

}