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	#include "clip.h"
	#include "clip-impl.h"
	#include "clip-model.h"
	#include "clip-graph.h"
	#include "models/models.h"

	#include "ggml.h"
	#include "ggml-cpp.h"
	#include "ggml-alloc.h"
	#include "ggml-backend.h"
	#include "gguf.h"

	#include <algorithm>
	#include <cassert>
	#include <cmath>
	#include <cstdlib>
	#include <cstring>
	#include <fstream>
	#include <map>
	#include <stdexcept>
	#include <unordered_set>
	#include <vector>
	#include <cinttypes>
	#include <limits>
	#include <array>
	#include <functional>

	struct clip_logger_state g_logger_state = {clip_log_callback_default, NULL};

	//#define CLIP_DEBUG_FUNCTIONS

	#ifdef CLIP_DEBUG_FUNCTIONS
	static void clip_image_write_image_to_ppm(const clip_image_u8& img, const std::string& filename) {
	std::ofstream file(filename, std::ios::binary);
	if (!file.is_open()) {
	LOG_ERR("Failed to open file for writing: %s\n", filename.c_str());
	return;
	}

	// PPM header: P6 format, width, height, and max color value
	file << "P6\n" << img.nx << " " << img.ny << "\n255\n";

	// Write pixel data
	for (size_t i = 0; i < img.buf.size(); i += 3) {
	// PPM expects binary data in RGB format, which matches our image buffer
	file.write(reinterpret_cast<const char*>(&img.buf[i]), 3);
	}

	file.close();
	}

	static void clip_image_save_to_bmp(const clip_image_u8& img, const std::string& filename) {
	std::ofstream file(filename, std::ios::binary);
	if (!file.is_open()) {
	LOG_ERR("Failed to open file for writing: %s\n", filename.c_str());
	return;
	}

	int fileSize = 54 + 3 * img.nx * img.ny; // File header + info header + pixel data
	int bytesPerPixel = 3;
	int widthInBytes = img.nx * bytesPerPixel;
	int paddingAmount = (4 - (widthInBytes % 4)) % 4;
	int stride = widthInBytes + paddingAmount;

	// Bitmap file header
	unsigned char fileHeader[14] = {
	'B','M', // Signature
	0,0,0,0, // Image file size in bytes
	0,0,0,0, // Reserved
	54,0,0,0 // Start of pixel array
	};

	// Total file size
	fileSize = 54 + (stride * img.ny);
	fileHeader[2] = (unsigned char)(fileSize);
	fileHeader[3] = (unsigned char)(fileSize >> 8);
	fileHeader[4] = (unsigned char)(fileSize >> 16);
	fileHeader[5] = (unsigned char)(fileSize >> 24);

	// Bitmap information header (BITMAPINFOHEADER)
	unsigned char infoHeader[40] = {
	40,0,0,0, // Size of this header (40 bytes)
	0,0,0,0, // Image width
	0,0,0,0, // Image height
	1,0, // Number of color planes
	24,0, // Bits per pixel
	0,0,0,0, // No compression
	0,0,0,0, // Image size (can be 0 for no compression)
	0,0,0,0, // X pixels per meter (not specified)
	0,0,0,0, // Y pixels per meter (not specified)
	0,0,0,0, // Total colors (color table not used)
	0,0,0,0 // Important colors (all are important)
	};

	// Width and height in the information header
	infoHeader[4] = (unsigned char)(img.nx);
	infoHeader[5] = (unsigned char)(img.nx >> 8);
	infoHeader[6] = (unsigned char)(img.nx >> 16);
	infoHeader[7] = (unsigned char)(img.nx >> 24);
	infoHeader[8] = (unsigned char)(img.ny);
	infoHeader[9] = (unsigned char)(img.ny >> 8);
	infoHeader[10] = (unsigned char)(img.ny >> 16);
	infoHeader[11] = (unsigned char)(img.ny >> 24);

	// Write file headers
	file.write(reinterpret_cast<char*>(fileHeader), sizeof(fileHeader));
	file.write(reinterpret_cast<char*>(infoHeader), sizeof(infoHeader));

	// Pixel data
	std::vector<unsigned char> padding(3, 0); // Max padding size to be added to each row
	for (int y = img.ny - 1; y >= 0; --y) { // BMP files are stored bottom-to-top
	for (int x = 0; x < img.nx; ++x) {
	// Each pixel
	size_t pixelIndex = (y * img.nx + x) * 3;
	unsigned char pixel[3] = {
	img.buf[pixelIndex + 2], // BMP stores pixels in BGR format
	img.buf[pixelIndex + 1],
	img.buf[pixelIndex]
	};
	file.write(reinterpret_cast<char*>(pixel), 3);
	}
	// Write padding for the row
	file.write(reinterpret_cast<char*>(padding.data()), paddingAmount);
	}

	file.close();
	}

	// debug function to convert f32 to u8
	static void clip_image_convert_f32_to_u8(const clip_image_f32& src, clip_image_u8& dst) {
	dst.nx = src.nx;
	dst.ny = src.ny;
	dst.buf.resize(3 * src.nx * src.ny);
	for (size_t i = 0; i < src.buf.size(); ++i) {
	dst.buf[i] = static_cast<uint8_t>(std::min(std::max(int(src.buf[i] * 255.0f), 0), 255));
	}
	}
	#endif


	struct clip_ctx {
	clip_model model;

	gguf_context_ptr ctx_gguf;
	ggml_context_ptr ctx_data;

	std::vector<uint8_t> buf_compute_meta;

	std::vector<ggml_backend_t> backend_ptrs;
	std::vector<ggml_backend_buffer_type_t> backend_buft;

	ggml_backend_t backend = nullptr;
	ggml_backend_t backend_cpu = nullptr;
	ggml_backend_buffer_ptr buf;


	int max_nodes = 8192;
	ggml_backend_sched_ptr sched;
	clip_flash_attn_type flash_attn_type = CLIP_FLASH_ATTN_TYPE_AUTO;
	bool is_allocated = false;

	clip_ctx(clip_context_params & ctx_params) {
	flash_attn_type = ctx_params.flash_attn_type;
	backend_cpu = ggml_backend_init_by_type(GGML_BACKEND_DEVICE_TYPE_CPU, nullptr);
	if (!backend_cpu) {
	throw std::runtime_error("failed to initialize CPU backend");
	}
	if (ctx_params.use_gpu) {
	auto backend_name = std::getenv("MTMD_BACKEND_DEVICE");
	if (backend_name != nullptr) {
	backend = ggml_backend_init_by_name(backend_name, nullptr);
	if (!backend) {
	LOG_WRN("%s: Warning: Failed to initialize \"%s\" backend, falling back to default GPU backend\n", __func__, backend_name);
	}
	}
	if (!backend) {
	backend = ggml_backend_init_by_type(GGML_BACKEND_DEVICE_TYPE_GPU, nullptr);
	backend = backend ? backend : ggml_backend_init_by_type(GGML_BACKEND_DEVICE_TYPE_IGPU, nullptr);
	}
	}

	if (backend) {
	LOG_INF("%s: CLIP using %s backend\n", __func__, ggml_backend_name(backend));
	backend_ptrs.push_back(backend);
	backend_buft.push_back(ggml_backend_get_default_buffer_type(backend));
	} else {
	backend = backend_cpu;
	LOG_INF("%s: CLIP using CPU backend\n", __func__);
	}

	if (ctx_params.image_min_tokens > 0) {
	model.hparams.custom_image_min_tokens = ctx_params.image_min_tokens;
	}
	if (ctx_params.image_max_tokens > 0) {
	model.hparams.custom_image_max_tokens = ctx_params.image_max_tokens;
	}

	backend_ptrs.push_back(backend_cpu);
	backend_buft.push_back(ggml_backend_get_default_buffer_type(backend_cpu));

	sched.reset(
	ggml_backend_sched_new(backend_ptrs.data(), backend_buft.data(), backend_ptrs.size(), 8192, false, true)
	);

	if (ctx_params.cb_eval != nullptr) {
	ggml_backend_sched_set_eval_callback(sched.get(), ctx_params.cb_eval, ctx_params.cb_eval_user_data);
	}
	}

	~clip_ctx() {
	ggml_backend_free(backend);
	if (backend != backend_cpu) {
	ggml_backend_free(backend_cpu);
	}
	}

	// this function is added so that we don't change too much of the existing code
	projector_type proj_type() const {
	return model.proj_type;
	}
	};

	//
	// clip_graph
	//

	clip_graph::clip_graph(clip_ctx * ctx, const clip_image_f32 & img) :
	model(ctx->model),
	hparams(model.hparams),
	proj_type(ctx->proj_type()),
	img(img),
	patch_size(hparams.patch_size),
	n_patches_x(img.nx / patch_size),
	n_patches_y(img.ny / patch_size),
	n_patches(n_patches_x * n_patches_y),
	n_embd(hparams.n_embd),
	n_head(hparams.n_head),
	d_head(n_embd / n_head),
	n_layer(hparams.n_layer),
	n_mmproj_embd(clip_n_mmproj_embd(ctx)),
	eps(hparams.eps),
	kq_scale(1.0f / sqrtf((float)d_head)),
	flash_attn_type(ctx->flash_attn_type) {
	struct ggml_init_params params = {
	/.mem_size =/ ctx->buf_compute_meta.size(),
	/.mem_buffer =/ ctx->buf_compute_meta.data(),
	/.no_alloc =/ true,
	};
	ctx0_ptr.reset(ggml_init(params));
	ctx0 = ctx0_ptr.get();
	gf = ggml_new_graph_custom(ctx0, ctx->max_nodes, false);
	}

	void clip_graph::cb(ggml_tensor * cur, const char * name, int il) const {
	if (il >= 0) {
	ggml_format_name(cur, "%s-%d", name, il);
	} else {
	ggml_set_name(cur, name);
	}
	}

	// siglip2 naflex
	ggml_tensor * clip_graph::resize_position_embeddings(uint32_t interpolation_mode) {
	ggml_tensor * pos_embd = model.position_embeddings;
	const int height = img.ny / patch_size;
	const int width = img.nx / patch_size;
	const uint32_t mode = interpolation_mode;
	const int n_per_side = (int)std::sqrt(pos_embd->ne[1]);

	GGML_ASSERT(pos_embd);

	if (height == n_per_side && width == n_per_side) {
	return pos_embd;
	}

	pos_embd = ggml_reshape_3d(ctx0, pos_embd, n_embd, n_per_side, n_per_side); // -> (n_embd, n_per_side, n_per_side)
	pos_embd = ggml_permute(ctx0, pos_embd, 2, 0, 1, 3); // -> (n_per_side, n_per_side, n_embd)
	pos_embd = ggml_interpolate(ctx0, pos_embd, width, height, n_embd, 1, mode); // -> (width, height, n_embd)
	pos_embd = ggml_permute(ctx0, pos_embd, 1, 2, 0, 3); // -> (n_embd, width, height)
	pos_embd = ggml_cont_2d(ctx0, pos_embd, n_embd, width * height); // -> (n_embd, width * height)

	return pos_embd;
	}

	// build vision transformer (ViT) cgraph
	// this function should cover most of the models
	// if your model has specific features, you should probably duplicate this function
	ggml_tensor * clip_graph::build_vit(
	ggml_tensor * inp,
	int64_t n_pos,
	norm_type norm_t,
	ffn_op_type ffn_t,
	ggml_tensor * learned_pos_embd,
	std::function<ggml_tensor (ggml_tensor , const clip_layer &)> add_pos
	) {
	if (learned_pos_embd) {
	inp = ggml_add(ctx0, inp, learned_pos_embd);
	cb(inp, "pos_embed", -1);
	}

	ggml_tensor * inpL = inp;

	// pre-layernorm
	if (model.pre_ln_w) {
	inpL = build_norm(inpL, model.pre_ln_w, model.pre_ln_b, norm_t, eps, -1);
	cb(inpL, "pre_ln", -1);
	}

	// loop over layers
	for (int il = 0; il < n_layer; il++) {
	auto & layer = model.layers[il];
	ggml_tensor * cur = inpL; // inpL = residual, cur = hidden_states

	// layernorm1
	cur = build_norm(cur, layer.ln_1_w, layer.ln_1_b, norm_t, eps, il);
	cb(cur, "layer_inp_normed", il);

	// self-attention
	{
	ggml_tensor * Qcur = nullptr;
	ggml_tensor * Kcur = nullptr;
	ggml_tensor * Vcur = nullptr;
	if (layer.qkv_w != nullptr) {
	// fused qkv
	cur = ggml_mul_mat(ctx0, layer.qkv_w, cur);
	if (layer.qkv_b != nullptr) {
	cur = ggml_add(ctx0, cur, layer.qkv_b);
	}

	Qcur = ggml_view_3d(ctx0, cur, d_head, n_head, n_pos,
	/* nb1 */ ggml_row_size(cur->type, d_head),
	/* nb2 */ cur->nb[1],
	/* offset */ 0);

	Kcur = ggml_view_3d(ctx0, cur, d_head, n_head, n_pos,
	/* nb1 */ ggml_row_size(cur->type, d_head),
	/* nb2 */ cur->nb[1],
	/* offset */ ggml_row_size(cur->type, n_embd));

	Vcur = ggml_view_3d(ctx0, cur, d_head, n_head, n_pos,
	/* nb1 */ ggml_row_size(cur->type, d_head),
	/* nb2 */ cur->nb[1],
	/* offset / ggml_row_size(cur->type, 2 n_embd));

	if (layer.q_norm) {
	GGML_ASSERT(layer.q_norm->ne[0] == Qcur->ne[0]);
	Qcur = build_norm(Qcur, layer.q_norm, NULL, norm_t, eps, il);
	cb(Qcur, "Qcur_norm", il);
	}

	if (layer.k_norm) {
	GGML_ASSERT(layer.k_norm->ne[0] == Kcur->ne[0]);
	Kcur = build_norm(Kcur, layer.k_norm, NULL, norm_t, eps, il);
	cb(Kcur, "Kcur_norm", il);
	}

	} else {
	// separate q, k, v
	Qcur = ggml_mul_mat(ctx0, layer.q_w, cur);
	if (layer.q_b) {
	Qcur = ggml_add(ctx0, Qcur, layer.q_b);
	}

	Kcur = ggml_mul_mat(ctx0, layer.k_w, cur);
	if (layer.k_b) {
	Kcur = ggml_add(ctx0, Kcur, layer.k_b);
	}

	Vcur = ggml_mul_mat(ctx0, layer.v_w, cur);
	if (layer.v_b) {
	Vcur = ggml_add(ctx0, Vcur, layer.v_b);
	}

	if (layer.q_norm) {
	Qcur = build_norm(Qcur, layer.q_norm, NULL, norm_t, eps, il);
	cb(Qcur, "Qcur_norm", il);
	}

	if (layer.k_norm) {
	Kcur = build_norm(Kcur, layer.k_norm, NULL, norm_t, eps, il);
	cb(Kcur, "Kcur_norm", il);
	}

	Qcur = ggml_reshape_3d(ctx0, Qcur, d_head, n_head, n_pos);
	Kcur = ggml_reshape_3d(ctx0, Kcur, d_head, n_head, n_pos);
	Vcur = ggml_reshape_3d(ctx0, Vcur, d_head, n_head, n_pos);
	}

	cb(Qcur, "Qcur", il);
	cb(Kcur, "Kcur", il);
	cb(Vcur, "Vcur", il);

	if (add_pos) {
	Qcur = add_pos(Qcur, layer);
	Kcur = add_pos(Kcur, layer);
	cb(Qcur, "Qcur_pos", il);
	cb(Kcur, "Kcur_pos", il);
	}

	cur = build_attn(layer.o_w, layer.o_b,
	Qcur, Kcur, Vcur, nullptr, kq_scale, il);
	cb(cur, "attn_out", il);
	}

	if (layer.ls_1_w) {
	cur = ggml_mul(ctx0, cur, layer.ls_1_w);
	cb(cur, "attn_out_scaled", il);
	}

	// re-add the layer input, e.g., residual
	cur = ggml_add(ctx0, cur, inpL);

	inpL = cur; // inpL = residual, cur = hidden_states

	cb(cur, "ffn_inp", il);

	// layernorm2
	cur = build_norm(cur, layer.ln_2_w, layer.ln_2_b, norm_t, eps, il);
	cb(cur, "ffn_inp_normed", il);

	// ffn
	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,
	ffn_t, il);

	cb(cur, "ffn_out", il);

	if (layer.ls_2_w) {
	cur = ggml_mul(ctx0, cur, layer.ls_2_w);
	cb(cur, "ffn_out_scaled", il);
	}

	// residual 2
	cur = ggml_add(ctx0, inpL, cur);
	cb(cur, "layer_out", il);

	inpL = cur;
	}

	if (model.audio_has_avgpool()) {
	ggml_tensor * cur = inpL;
	cur = ggml_transpose(ctx0, cur);
	cur = ggml_cont(ctx0, cur);
	cur = ggml_pool_1d(ctx0, cur, GGML_OP_POOL_AVG, 2, 2, 0);
	cur = ggml_transpose(ctx0, cur);
	cur = ggml_cont(ctx0, cur);
	inpL = cur;
	}

	// post-layernorm
	if (model.post_ln_w) {
	inpL = build_norm(inpL, model.post_ln_w, model.post_ln_b, norm_t, eps, -1);
	}
	return inpL;
	}

	// build the input after conv2d (inp_raw --> patches)
	// returns tensor with shape [n_embd, n_patches]
	ggml_tensor * clip_graph::build_inp() {
	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);
	inp = ggml_reshape_2d(ctx0, inp, n_patches, n_embd);
	inp = ggml_cont(ctx0, ggml_transpose(ctx0, inp));
	if (model.patch_bias) {
	inp = ggml_add(ctx0, inp, model.patch_bias);
	cb(inp, "patch_bias", -1);
	}
	return inp;
	}

	ggml_tensor * clip_graph::build_inp_raw(int channels) {
	ggml_tensor * inp_raw = ggml_new_tensor_3d(ctx0, GGML_TYPE_F32, img.nx, img.ny, channels);
	ggml_set_name(inp_raw, "inp_raw");
	ggml_set_input(inp_raw);
	return inp_raw;
	}

	ggml_tensor * clip_graph::build_norm(
	ggml_tensor * cur,
	ggml_tensor * mw,
	ggml_tensor * mb,
	norm_type type,
	float norm_eps,
	int il) const {

	cur = type == NORM_TYPE_RMS
	? ggml_rms_norm(ctx0, cur, norm_eps)
	: ggml_norm(ctx0, cur, norm_eps);

	if (mw) {
	cur = ggml_mul(ctx0, cur, mw);
	cb(cur, "norm_w", il);
	}

	if (mb) {
	cur = ggml_add(ctx0, cur, mb);
	cb(cur, "norm_b", il);
	}

	return cur;
	}

	ggml_tensor * clip_graph::build_ffn(
	ggml_tensor * cur,
	ggml_tensor * up,
	ggml_tensor * up_b,
	ggml_tensor * gate,
	ggml_tensor * gate_b,
	ggml_tensor * down,
	ggml_tensor * down_b,
	ffn_op_type type_op,
	int il) const {

	ggml_tensor * tmp = up ? ggml_mul_mat(ctx0, up, cur) : cur;
	cb(tmp, "ffn_up", il);

	if (up_b) {
	tmp = ggml_add(ctx0, tmp, up_b);
	cb(tmp, "ffn_up_b", il);
	}

	if (gate) {
	cur = ggml_mul_mat(ctx0, gate, cur);
	cb(cur, "ffn_gate", il);

	if (gate_b) {
	cur = ggml_add(ctx0, cur, gate_b);
	cb(cur, "ffn_gate_b", il);
	}
	} else {
	cur = tmp;
	}

	// we only support parallel ffn for now
	switch (type_op) {
	case FFN_SILU:
	if (gate) {
	cur = ggml_swiglu_split(ctx0, cur, tmp);
	cb(cur, "ffn_swiglu", il);
	} else {
	cur = ggml_silu(ctx0, cur);
	cb(cur, "ffn_silu", il);
	} break;
	case FFN_GELU:
	if (gate) {
	cur = ggml_geglu_split(ctx0, cur, tmp);
	cb(cur, "ffn_geglu", il);
	} else {
	cur = ggml_gelu(ctx0, cur);
	cb(cur, "ffn_gelu", il);
	} break;
	case FFN_GELU_ERF:
	if (gate) {
	cur = ggml_geglu_erf_split(ctx0, cur, tmp);
	cb(cur, "ffn_geglu_erf", il);
	} else {
	cur = ggml_gelu_erf(ctx0, cur);
	cb(cur, "ffn_gelu_erf", il);
	} break;
	case FFN_GELU_QUICK:
	if (gate) {
	cur = ggml_geglu_quick_split(ctx0, cur, tmp);
	cb(cur, "ffn_geglu_quick", il);
	} else {
	cur = ggml_gelu_quick(ctx0, cur);
	cb(cur, "ffn_gelu_quick", il);
	} break;
	case FFN_RELU_SQR:
	{
	cur = ggml_relu(ctx0, cur);
	cur = ggml_sqr(ctx0, cur);
	cb(cur, "ffn_relu_sqr", il);
	} break;
	}

	if (down) {
	cur = ggml_mul_mat(ctx0, down, cur);
	}

	if (down_b) {
	cb(cur, "ffn_down", il);
	}

	if (down_b) {
	cur = ggml_add(ctx0, cur, down_b);
	}

	return cur;
	}

	ggml_tensor * clip_graph::build_attn(
	ggml_tensor * wo,
	ggml_tensor * wo_b,
	ggml_tensor * q_cur,
	ggml_tensor * k_cur,
	ggml_tensor * v_cur,
	ggml_tensor * kq_mask,
	float kq_scale,
	int il) const {
	// these nodes are added to the graph together so that they are not reordered
	// by doing so, the number of splits in the graph is reduced
	ggml_build_forward_expand(gf, q_cur);
	ggml_build_forward_expand(gf, k_cur);
	ggml_build_forward_expand(gf, v_cur);

	ggml_tensor * q = ggml_permute(ctx0, q_cur, 0, 2, 1, 3);
	//cb(q, "q", il);

	ggml_tensor * k = ggml_permute(ctx0, k_cur, 0, 2, 1, 3);
	//cb(k, "k", il);

	ggml_tensor * cur;

	if (flash_attn_type == CLIP_FLASH_ATTN_TYPE_ENABLED) {
	ggml_tensor * v = ggml_permute(ctx0, v_cur, 0, 2, 1, 3);

	k = ggml_cast(ctx0, k, GGML_TYPE_F16);
	v = ggml_cast(ctx0, v, GGML_TYPE_F16);

	cur = ggml_flash_attn_ext(ctx0, q, k, v, kq_mask, kq_scale, 0.0f, 0.0f);
	ggml_flash_attn_ext_set_prec(cur, GGML_PREC_F32);

	cur = ggml_reshape_2d(ctx0, cur, cur->ne[0]cur->ne[1], cur->ne[2]cur->ne[3]);

	} else {
	ggml_tensor * v = ggml_permute(ctx0, v_cur, 1, 2, 0, 3);
	v = ggml_cont(ctx0, v);

	ggml_tensor * kq = ggml_mul_mat(ctx0, k, q);
	// F32 may not needed for vision encoders?
	// ggml_mul_mat_set_prec(kq, GGML_PREC_F32);

	kq = ggml_soft_max_ext(ctx0, kq, kq_mask, kq_scale, 0.0f);

	ggml_tensor * kqv = ggml_mul_mat(ctx0, v, kq);
	cur = ggml_permute(ctx0, kqv, 0, 2, 1, 3);
	cur = ggml_cont_2d(ctx0, cur, cur->ne[0] * cur->ne[1], cur->ne[2] * cur->ne[3]);
	}

	cb(cur, "kqv_out", il);

	if (wo) {
	cur = ggml_mul_mat(ctx0, wo, cur);
	}

	if (wo_b) {
	cur = ggml_add(ctx0, cur, wo_b);
	}

	return cur;
	}

	// implementation of the 2D RoPE without adding a new op in ggml
	// this is not efficient (use double the memory), but works on all backends
	// TODO: there was a more efficient which relies on ggml_view and ggml_rope_ext_inplace, but the rope inplace does not work well with non-contiguous tensors ; we should fix that and revert back to the original implementation in https://github.com/ggml-org/llama.cpp/pull/13065
	ggml_tensor * clip_graph::build_rope_2d(
	ggml_context * ctx0,
	ggml_tensor * cur,
	ggml_tensor * pos_a, // first half
	ggml_tensor * pos_b, // second half
	const float freq_base,
	const bool interleave_freq
	) {
	const int64_t n_dim = cur->ne[0];
	const int64_t n_head = cur->ne[1];
	const int64_t n_pos = cur->ne[2];

	// for example, if we have cur tensor of shape (n_dim=8, n_head, n_pos)
	// we will have a list of 4 inv_freq: 1e-0, 1e-1, 1e-2, 1e-3
	// first half of cur will use 1e-0, 1e-2 (even)
	// second half of cur will use 1e-1, 1e-3 (odd)
	// the trick here is to rotate just half of n_dim, so inv_freq will automatically be even
	// ^ don't ask me why, it's math! -2(2i) / n_dim == -2i / (n_dim/2)
	// then for the second half, we use freq_scale to shift the inv_freq
	// ^ why? replace (2i) with (2i+1) in the above equation
	const float freq_scale_odd = interleave_freq
	? std::pow(freq_base, (float)-2/n_dim)
	: 1.0;

	// first half
	ggml_tensor * first;
	{
	first = ggml_view_3d(ctx0, cur,
	n_dim/2, n_head, n_pos,
	cur->nb[1],
	cur->nb[2],
	0);
	first = ggml_rope_ext(
	ctx0,
	first,
	pos_a, // positions
	nullptr, // freq factors
	n_dim/2, // n_dims
	0, 0, freq_base,
	1.0f, 0.0f, 1.0f, 0.0f, 0.0f
	);
	}

	// second half
	ggml_tensor * second;
	{
	second = ggml_view_3d(ctx0, cur,
	n_dim/2, n_head, n_pos,
	cur->nb[1],
	cur->nb[2],
	n_dim/2 * ggml_element_size(cur));
	second = ggml_rope_ext(
	ctx0,
	second,
	pos_b, // positions
	nullptr, // freq factors
	n_dim/2, // n_dims
	0, 0, freq_base,
	freq_scale_odd,
	0.0f, 1.0f, 0.0f, 0.0f
	);
	}

	cur = ggml_concat(ctx0, first, second, 0);
	return cur;
	}

	// Generic function to stack frames for audio processing
	// Abstracts out the StackAudioFrames logic used by ultravox
	ggml_tensor * clip_graph::build_stack(ggml_tensor * cur, int32_t stack_factor, int32_t n_embed) {
	if (stack_factor <= 1) {
	return cur;
	}

	int64_t total_elements = ggml_nelements(cur);
	int64_t stride = n_embed * stack_factor;

	// Calculate padded length
	int64_t padded_len = GGML_PAD(total_elements, stride);
	int64_t pad = padded_len - total_elements;

	if (pad > 0) {
	// Pad the tensor to make it divisible by stride
	cur = ggml_view_1d(ctx0, cur, total_elements, 0);
	cur = ggml_pad(ctx0, cur, pad, 0, 0, 0);
	}

	// Reshape to [stride, padded_len / stride]
	cur = ggml_view_2d(ctx0, cur, stride, padded_len / stride,
	ggml_row_size(cur->type, stride), 0);
	return cur;
	}

	// aka pixel_shuffle / pixel_unshuffle / patch_merger (Kimi-VL)
	// support dynamic resolution
	ggml_tensor * clip_graph::build_patch_merge_permute(ggml_tensor * cur, int scale_factor) {
	GGML_ASSERT(scale_factor > 1);

	const int n_embd = cur->ne[0];
	int width = img.nx / patch_size;
	int height = img.ny / patch_size;

	// pad width and height to factor
	const int64_t pad_width = CLIP_ALIGN(width, scale_factor) - width;
	const int64_t pad_height = CLIP_ALIGN(height, scale_factor) - height;
	cur = ggml_reshape_3d(ctx0, cur, n_embd, width, height);
	if (pad_width \|\| pad_height) {
	cur = ggml_pad(ctx0, cur, 0, pad_width, pad_height, 0);
	width += pad_width;
	height += pad_height;
	}

	// unshuffle h
	cur = ggml_reshape_3d(ctx0, cur, n_embd * scale_factor, width / scale_factor, height);
	cur = ggml_permute(ctx0, cur, 0, 2, 1, 3);

	// unshuffle w
	cur = ggml_cont_3d(ctx0, cur, n_embd * scale_factor * scale_factor, height / scale_factor, width / scale_factor);
	cur = ggml_permute(ctx0, cur, 0, 2, 1, 3);

	cur = ggml_cont_2d(ctx0, cur, cur->ne[0], cur->ne[1] * cur->ne[2]);
	cb(cur, "pixel_shuffle", -1);

	return cur;
	}

	static ggml_cgraph * clip_image_build_graph(clip_ctx * ctx, const clip_image_f32_batch & imgs) {
	GGML_ASSERT(imgs.entries.size() == 1 && "n_batch > 1 is not supported");

	const clip_image_f32 & img = *imgs.entries[0];
	std::unique_ptr<clip_graph> builder;

	switch (ctx->proj_type()) {
	case PROJECTOR_TYPE_GEMMA3:
	case PROJECTOR_TYPE_IDEFICS3:
	case PROJECTOR_TYPE_LFM2:
	case PROJECTOR_TYPE_JANUS_PRO:
	{
	builder = std::make_unique<clip_graph_siglip>(ctx, img);
	} break;
	case PROJECTOR_TYPE_GEMMA3NV:
	{
	builder = std::make_unique<clip_graph_mobilenetv5>(ctx, img);
	} break;
	case PROJECTOR_TYPE_PIXTRAL:
	case PROJECTOR_TYPE_LIGHTONOCR:
	{
	builder = std::make_unique<clip_graph_pixtral>(ctx, img);
	} break;
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	{
	builder = std::make_unique<clip_graph_qwen2vl>(ctx, img);
	} break;
	case PROJECTOR_TYPE_QWEN3VL:
	{
	builder = std::make_unique<clip_graph_qwen3vl>(ctx, img);
	} break;
	case PROJECTOR_TYPE_MINICPMV:
	{
	builder = std::make_unique<clip_graph_minicpmv>(ctx, img);
	} break;
	case PROJECTOR_TYPE_INTERNVL:
	{
	builder = std::make_unique<clip_graph_internvl>(ctx, img);
	} break;
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	{
	builder = std::make_unique<clip_graph_nemotron_v2_vl>(ctx, img);
	} break;
	case PROJECTOR_TYPE_LLAMA4:
	{
	builder = std::make_unique<clip_graph_llama4>(ctx, img);
	} break;
	case PROJECTOR_TYPE_ULTRAVOX:
	case PROJECTOR_TYPE_VOXTRAL:
	case PROJECTOR_TYPE_QWEN2A:
	case PROJECTOR_TYPE_GLMA:
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	{
	builder = std::make_unique<clip_graph_whisper_enc>(ctx, img);
	} break;
	case PROJECTOR_TYPE_KIMIVL:
	{
	builder = std::make_unique<clip_graph_kimivl>(ctx, img);
	} break;
	case PROJECTOR_TYPE_PADDLEOCR:
	{
	builder = std::make_unique<clip_graph_paddleocr>(ctx, img);
	} break;
	case PROJECTOR_TYPE_KIMIK25:
	{
	builder = std::make_unique<clip_graph_kimik25>(ctx, img);
	} break;
	case PROJECTOR_TYPE_COGVLM:
	{
	builder = std::make_unique<clip_graph_cogvlm>(ctx, img);
	} break;
	case PROJECTOR_TYPE_MLP:
	case PROJECTOR_TYPE_MLP_NORM:
	case PROJECTOR_TYPE_LDP:
	case PROJECTOR_TYPE_LDPV2:
	case PROJECTOR_TYPE_GLM_EDGE:
	{
	builder = std::make_unique<clip_graph_llava>(ctx, img);
	} break;
	case PROJECTOR_TYPE_LFM2A:
	{
	builder = std::make_unique<clip_graph_conformer>(ctx, img);
	} break;
	case PROJECTOR_TYPE_GLM4V:
	{
	builder = std::make_unique<clip_graph_glm4v>(ctx, img);
	} break;
	case PROJECTOR_TYPE_YOUTUVL:
	{
	builder = std::make_unique<clip_graph_youtuvl>(ctx, img);
	} break;
	default:
	GGML_ABORT("missing cgraph builder");
	}

	return builder->build();
	}

	//
	// clip_model_loader
	//

	struct clip_model_loader {
	ggml_context_ptr ctx_meta;
	gguf_context_ptr ctx_gguf;

	std::string fname;

	size_t model_size = 0; // in bytes

	bool has_vision = false;
	bool has_audio = false;

	// TODO @ngxson : we should not pass clip_ctx here, it should be clip_model
	clip_model_loader(const char * fname) : fname(fname) {
	struct ggml_context * meta = nullptr;

	struct gguf_init_params params = {
	/.no_alloc = / true,
	/.ctx = / &meta,
	};

	ctx_gguf = gguf_context_ptr(gguf_init_from_file(fname, params));
	if (!ctx_gguf.get()) {
	throw std::runtime_error(string_format("%s: failed to load CLIP model from %s. Does this file exist?\n", __func__, fname));
	}

	ctx_meta.reset(meta);

	const int n_tensors = gguf_get_n_tensors(ctx_gguf.get());

	// print gguf info
	{
	std::string name;
	get_string(KEY_NAME, name, false);
	std::string description;
	get_string(KEY_DESCRIPTION, description, false);
	LOG_INF("%s: model name: %s\n", __func__, name.c_str());
	LOG_INF("%s: description: %s\n", __func__, description.c_str());
	LOG_INF("%s: GGUF version: %d\n", __func__, gguf_get_version(ctx_gguf.get()));
	LOG_INF("%s: alignment: %zu\n", __func__, gguf_get_alignment(ctx_gguf.get()));
	LOG_INF("%s: n_tensors: %d\n", __func__, n_tensors);
	LOG_INF("%s: n_kv: %d\n", __func__, (int)gguf_get_n_kv(ctx_gguf.get()));
	LOG_INF("\n");
	}

	// modalities
	{
	get_bool(KEY_HAS_VISION_ENC, has_vision, false);
	get_bool(KEY_HAS_AUDIO_ENC, has_audio, false);

	if (has_vision) {
	LOG_INF("%s: has vision encoder\n", __func__);
	}
	if (has_audio) {
	LOG_INF("%s: has audio encoder\n", __func__);
	}
	}

	// tensors
	{
	for (int i = 0; i < n_tensors; ++i) {
	const char * name = gguf_get_tensor_name(ctx_gguf.get(), i);
	const size_t offset = gguf_get_tensor_offset(ctx_gguf.get(), i);
	enum ggml_type type = gguf_get_tensor_type(ctx_gguf.get(), i);
	ggml_tensor * cur = ggml_get_tensor(meta, name);
	size_t tensor_size = ggml_nbytes(cur);
	model_size += tensor_size;
	LOG_DBG("%s: tensor[%d]: n_dims = %d, name = %s, tensor_size=%zu, offset=%zu, shape:[%" PRIu64 ", %" PRIu64 ", %" PRIu64 ", %" PRIu64 "], type = %s\n",
	__func__, i, ggml_n_dims(cur), cur->name, tensor_size, offset, cur->ne[0], cur->ne[1], cur->ne[2], cur->ne[3], ggml_type_name(type));
	}
	}
	}

	void load_hparams(clip_model & model, clip_modality modality) {
	auto & hparams = model.hparams;
	std::string log_ffn_op; // for logging

	// sanity check
	if (modality == CLIP_MODALITY_VISION) {
	GGML_ASSERT(has_vision);
	} else if (modality == CLIP_MODALITY_AUDIO) {
	GGML_ASSERT(has_audio);
	}
	model.modality = modality;


	// projector type
	std::string proj_type;
	{
	// default key
	get_string(KEY_PROJ_TYPE, proj_type, false);

	// for models with mixed modalities
	if (proj_type.empty()) {
	if (modality == CLIP_MODALITY_VISION) {
	get_string(KEY_VISION_PROJ_TYPE, proj_type, false);
	} else if (modality == CLIP_MODALITY_AUDIO) {
	get_string(KEY_AUDIO_PROJ_TYPE, proj_type, false);
	} else {
	GGML_ABORT("unknown modality");
	}
	}

	model.proj_type = clip_projector_type_from_string(proj_type);

	if (model.proj_type == PROJECTOR_TYPE_UNKNOWN) {
	throw std::runtime_error(string_format("%s: unknown projector type: %s\n", __func__, proj_type.c_str()));
	}

	// correct arch for multimodal models (legacy method)
	if (model.proj_type == PROJECTOR_TYPE_QWEN25O) {
	model.proj_type = modality == CLIP_MODALITY_VISION
	? PROJECTOR_TYPE_QWEN25VL
	: PROJECTOR_TYPE_QWEN2A;
	}
	}

	const bool is_vision = model.modality == CLIP_MODALITY_VISION;
	const bool is_audio = model.modality == CLIP_MODALITY_AUDIO;

	// other hparams
	{
	const char * prefix = is_vision ? "vision" : "audio";
	get_u32(string_format(KEY_N_EMBD, prefix), hparams.n_embd);
	get_u32(string_format(KEY_N_HEAD, prefix), hparams.n_head);
	get_u32(string_format(KEY_N_FF, prefix), hparams.n_ff);
	get_u32(string_format(KEY_N_BLOCK, prefix), hparams.n_layer);
	get_u32(string_format(KEY_PROJ_DIM, prefix), hparams.projection_dim);
	get_f32(string_format(KEY_LAYER_NORM_EPS, prefix), hparams.eps);

	if (is_vision) {
	get_u32(KEY_IMAGE_SIZE, hparams.image_size);
	get_u32(KEY_PATCH_SIZE, hparams.patch_size);
	get_u32(KEY_IMAGE_CROP_RESOLUTION, hparams.image_crop_resolution, false);
	get_i32(KEY_MINICPMV_VERSION, hparams.minicpmv_version, false); // legacy
	get_u32(KEY_MINICPMV_QUERY_NUM, hparams.minicpmv_query_num, false);
	if (hparams.minicpmv_query_num == 0) {
	// Fallback to hardcoded values for legacy models
	if (hparams.minicpmv_version == 3) {
	hparams.minicpmv_query_num = 64;
	} else if (hparams.minicpmv_version == 4) {
	hparams.minicpmv_query_num = 64;
	} else if (hparams.minicpmv_version == 5) {
	hparams.minicpmv_query_num = 64;
	} else if (hparams.minicpmv_version == 6) {
	hparams.minicpmv_query_num = 64;
	} else if (hparams.minicpmv_version == 100045) {
	hparams.minicpmv_query_num = 64;
	} else {
	hparams.minicpmv_query_num = 96;
	}
	}
	} else if (is_audio) {
	get_u32(KEY_A_NUM_MEL_BINS, hparams.n_mel_bins);
	// some hparams are unused, but still need to set to avoid issues
	hparams.image_size = 0;
	hparams.patch_size = 1;

	} else {
	GGML_ASSERT(false && "unknown modality");
	}

	// for pinpoints, we need to convert it into a list of resolution candidates
	{
	std::vector<int> pinpoints;
	get_arr_int(KEY_IMAGE_GRID_PINPOINTS, pinpoints, false);
	if (!pinpoints.empty()) {
	for (size_t i = 0; i < pinpoints.size(); i += 2) {
	hparams.image_res_candidates.push_back({
	pinpoints[i],
	pinpoints[i+1],
	});
	}
	}
	}

	// default warmup value
	hparams.warmup_image_size = hparams.image_size;

	hparams.has_llava_projector = model.proj_type == PROJECTOR_TYPE_MLP
	\|\| model.proj_type == PROJECTOR_TYPE_MLP_NORM
	\|\| model.proj_type == PROJECTOR_TYPE_LDP
	\|\| model.proj_type == PROJECTOR_TYPE_LDPV2;

	{
	bool use_gelu = false;
	bool use_silu = false;
	get_bool(KEY_USE_GELU, use_gelu, false);
	get_bool(KEY_USE_SILU, use_silu, false);
	if (use_gelu && use_silu) {
	throw std::runtime_error(string_format("%s: both use_gelu and use_silu are set to true\n", __func__));
	}
	if (use_gelu) {
	hparams.ffn_op = FFN_GELU;
	log_ffn_op = "gelu";
	} else if (use_silu) {
	hparams.ffn_op = FFN_SILU;
	log_ffn_op = "silu";
	} else {
	hparams.ffn_op = FFN_GELU_QUICK;
	log_ffn_op = "gelu_quick";
	}
	}

	{
	std::string mm_patch_merge_type;
	get_string(KEY_MM_PATCH_MERGE_TYPE, mm_patch_merge_type, false);
	if (mm_patch_merge_type == "spatial_unpad") {
	hparams.mm_patch_merge_type = PATCH_MERGE_SPATIAL_UNPAD;
	}
	}

	if (is_vision) {
	int idx_mean = gguf_find_key(ctx_gguf.get(), KEY_IMAGE_MEAN);
	int idx_std = gguf_find_key(ctx_gguf.get(), KEY_IMAGE_STD);
	GGML_ASSERT(idx_mean >= 0 && "image_mean not found");
	GGML_ASSERT(idx_std >= 0 && "image_std not found");
	const float * mean_data = (const float *) gguf_get_arr_data(ctx_gguf.get(), idx_mean);
	const float * std_data = (const float *) gguf_get_arr_data(ctx_gguf.get(), idx_std);
	for (int i = 0; i < 3; ++i) {
	hparams.image_mean[i] = mean_data[i];
	hparams.image_std[i] = std_data[i];
	}
	}

	// Load the vision feature layer indices if they are explicitly provided;
	// if multiple vision feature layers are present, the values will be concatenated
	// to form the final visual features.
	// NOTE: gguf conversions should standardize the values of the vision feature layer to
	// be non-negative, since we use -1 to mark values as unset here.
	std::vector<int> vision_feature_layer;
	get_arr_int(KEY_FEATURE_LAYER, vision_feature_layer, false);
	// convert std::vector to std::unordered_set
	for (auto & layer : vision_feature_layer) {
	hparams.vision_feature_layer.insert(layer);
	}

	// model-specific params
	switch (model.proj_type) {
	case PROJECTOR_TYPE_MINICPMV:
	{
	if (hparams.minicpmv_version == 0) {
	hparams.minicpmv_version = 2; // default to 2 if not set
	}
	} break;
	case PROJECTOR_TYPE_INTERNVL:
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	{
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	} break;
	case PROJECTOR_TYPE_IDEFICS3:
	{
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	get_u32(KEY_PREPROC_IMAGE_SIZE, hparams.image_longest_edge, false);
	} break;
	case PROJECTOR_TYPE_LFM2:
	{
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	// ref: https://huggingface.co/LiquidAI/LFM2.5-VL-1.6B/blob/main/processor_config.json
	hparams.set_limit_image_tokens(64, 256);
	} break;
	case PROJECTOR_TYPE_PIXTRAL:
	case PROJECTOR_TYPE_LIGHTONOCR:
	{
	// ref: https://huggingface.co/mistral-community/pixtral-12b/blob/main/preprocessor_config.json
	// TODO: verify the image_min_tokens
	hparams.n_merge = 1; // the original pixtral does not use patch merging
	hparams.rope_theta = 10000.0f;
	get_u32(KEY_SPATIAL_MERGE_SIZE, hparams.n_merge, false);
	hparams.set_limit_image_tokens(8, 1024);
	hparams.set_warmup_n_tokens(256); // avoid OOM on warmup
	} break;
	case PROJECTOR_TYPE_KIMIVL:
	{
	hparams.rope_theta = 10000.0f;
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	// TODO: check kimivl preprocessor for exact values
	hparams.set_limit_image_tokens(8, 1024);
	hparams.set_warmup_n_tokens(256); // avoid OOM on warmup
	} break;
	case PROJECTOR_TYPE_KIMIK25:
	{
	hparams.rope_theta = 10000.0f;
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);

	int min_pixels = 0, max_pixels = 0;
	get_u32(KEY_IMAGE_MIN_PIXELS, min_pixels, false);
	get_u32(KEY_IMAGE_MAX_PIXELS, max_pixels, false);
	if (min_pixels > 0 && max_pixels > 0) {
	hparams.image_min_pixels = min_pixels;
	hparams.image_max_pixels = max_pixels;
	hparams.warmup_image_size = static_cast<int>(std::sqrt(max_pixels));
	} else {
	hparams.set_limit_image_tokens(2, 4096);
	}
	} break;
	case PROJECTOR_TYPE_GEMMA3:
	{
	// default value (used by all model sizes in gemma 3 family)
	// number of patches for each side is reduced by a factor of 4
	hparams.n_merge = 4;
	// test model (tinygemma3) has a different value, we optionally read it
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	} break;

	case PROJECTOR_TYPE_GEMMA3NV:
	{
	// Gemma3n uses MobileNetV5 which produces 256 tokens (16x16)
	// Similar configuration to Gemma3
	hparams.n_merge = 1; // MobileNetV5 handles resizing internally
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	} break;
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_QWEN3VL:
	{
	hparams.n_merge = 2; // default value for Qwen 2 and 2.5
	get_u32(KEY_SPATIAL_MERGE_SIZE, hparams.n_merge, false);
	get_u32(KEY_WIN_ATTN_PATTERN, hparams.n_wa_pattern, model.proj_type == PROJECTOR_TYPE_QWEN25VL); // only 2.5 requires it
	// ref: https://huggingface.co/Qwen/Qwen2.5-VL-7B-Instruct/blob/main/preprocessor_config.json
	hparams.set_limit_image_tokens(8, 4096);
	hparams.set_warmup_n_tokens(46*46); // avoid OOM on warmup
	const int warn_min_pixels = 1024 * hparams.n_merge * hparams.n_merge * hparams.patch_size * hparams.patch_size;
	if (hparams.image_min_pixels < warn_min_pixels) {
	LOG_WRN("%s: Qwen-VL models require at minimum 1024 image tokens to function correctly on grounding tasks\n", __func__);
	LOG_WRN("%s: if you encounter problems with accuracy, try adding --image-min-tokens 1024\n", __func__);
	LOG_WRN("%s: more info: https://github.com/ggml-org/llama.cpp/issues/16842\n\n", __func__);
	}
	} break;
	case PROJECTOR_TYPE_YOUTUVL:
	{
	hparams.n_merge = 2;
	get_u32(KEY_SPATIAL_MERGE_SIZE, hparams.n_merge, false);
	get_u32(KEY_ATTN_WINDOW_SIZE, hparams.attn_window_size, true);
	std::vector<int> wa_layer_indexes_vec;
	get_arr_int(KEY_WIN_ATTN_LAYER_INDEXES, wa_layer_indexes_vec, true);
	for (auto & layer : wa_layer_indexes_vec) {
	hparams.wa_layer_indexes.insert(layer);
	}
	// support max_height * max_width = 8000 * 8000. 8000/16/2 = 250 image tokens
	hparams.set_limit_image_tokens(1, 62500);
	hparams.set_warmup_n_tokens(16*16); // avoid OOM on warmup
	} break;
	case PROJECTOR_TYPE_GLM4V:
	{
	hparams.rope_theta = 10000.0f;
	hparams.n_merge = 2; // default value for GLM4-V
	get_u32(KEY_SPATIAL_MERGE_SIZE, hparams.n_merge, false);
	hparams.set_limit_image_tokens(8, 4096);
	hparams.set_warmup_n_tokens(46*46); // avoid OOM on warmup
	} break;
	case PROJECTOR_TYPE_LLAMA4:
	{
	hparams.rope_theta = 10000.0f;
	get_u32(KEY_PROJ_SCALE_FACTOR, hparams.n_merge, false);
	set_llava_uhd_res_candidates(model, 3);
	} break;
	case PROJECTOR_TYPE_ULTRAVOX:
	case PROJECTOR_TYPE_QWEN2A:
	case PROJECTOR_TYPE_GLMA:
	case PROJECTOR_TYPE_VOXTRAL:
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	{
	bool require_stack = model.proj_type == PROJECTOR_TYPE_ULTRAVOX \|\|
	model.proj_type == PROJECTOR_TYPE_VOXTRAL \|\|
	model.proj_type == PROJECTOR_TYPE_GLMA;
	get_u32(KEY_A_PROJ_STACK_FACTOR, hparams.proj_stack_factor, require_stack);
	hparams.ffn_op = FFN_GELU_ERF;
	log_ffn_op = "gelu_erf"; // temporary solution for logging

	// audio preprocessing params
	hparams.audio_chunk_len = 30; // in seconds
	hparams.audio_sample_rate = 16000;
	hparams.audio_n_fft = 400;
	hparams.audio_window_len = 400;
	hparams.audio_hop_len = 160;
	} break;
	case PROJECTOR_TYPE_PADDLEOCR:
	{
	hparams.n_merge = 2;
	get_u32(KEY_IMAGE_MIN_PIXELS, hparams.image_min_pixels);
	get_u32(KEY_IMAGE_MAX_PIXELS, hparams.image_max_pixels);

	hparams.set_warmup_n_tokens(28*28); // avoid OOM on warmup
	} break;
	case PROJECTOR_TYPE_LFM2A:
	{
	// audio preprocessing params
	hparams.audio_chunk_len = 1; // in seconds
	hparams.audio_sample_rate = 16000;
	hparams.audio_n_fft = 512;
	hparams.audio_window_len = 400;
	hparams.audio_hop_len = 160;
	} break;
	default:
	break;
	}

	// sanity check
	{
	if (hparams.image_max_pixels < hparams.image_min_pixels) {
	throw std::runtime_error(string_format("%s: image_max_pixels (%d) is less than image_min_pixels (%d)\n", __func__, hparams.image_max_pixels, hparams.image_min_pixels));
	}
	}

	LOG_INF("%s: projector: %s\n", __func__, proj_type.c_str());
	LOG_INF("%s: n_embd: %d\n", __func__, hparams.n_embd);
	LOG_INF("%s: n_head: %d\n", __func__, hparams.n_head);
	LOG_INF("%s: n_ff: %d\n", __func__, hparams.n_ff);
	LOG_INF("%s: n_layer: %d\n", __func__, hparams.n_layer);
	LOG_INF("%s: ffn_op: %s\n", __func__, log_ffn_op.c_str());
	LOG_INF("%s: projection_dim: %d\n", __func__, hparams.projection_dim);
	if (is_vision) {
	LOG_INF("\n--- vision hparams ---\n");
	LOG_INF("%s: image_size: %d\n", __func__, hparams.image_size);
	LOG_INF("%s: patch_size: %d\n", __func__, hparams.patch_size);
	LOG_INF("%s: has_llava_proj: %d\n", __func__, hparams.has_llava_projector);
	LOG_INF("%s: minicpmv_version: %d\n", __func__, hparams.minicpmv_version);
	LOG_INF("%s: n_merge: %d\n", __func__, hparams.n_merge);
	LOG_INF("%s: n_wa_pattern: %d\n", __func__, hparams.n_wa_pattern);
	if (!hparams.wa_layer_indexes.empty()) {
	LOG_INF("%s: wa_layer_indexes: ", __func__);
	for (auto & layer : hparams.wa_layer_indexes) {
	LOG_INF("%d ", layer);
	}
	LOG_INF("\n");
	}
	if (hparams.image_min_pixels > 0) {
	LOG_INF("%s: image_min_pixels: %d%s\n", __func__, hparams.image_min_pixels, hparams.custom_image_min_tokens > 0 ? " (custom value)" : "");
	}
	if (hparams.image_max_pixels > 0) {
	LOG_INF("%s: image_max_pixels: %d%s\n", __func__, hparams.image_max_pixels, hparams.custom_image_max_tokens > 0 ? " (custom value)" : "");
	}
	} else if (is_audio) {
	LOG_INF("\n--- audio hparams ---\n");
	LOG_INF("%s: n_mel_bins: %d\n", __func__, hparams.n_mel_bins);
	LOG_INF("%s: proj_stack_factor: %d\n", __func__, hparams.proj_stack_factor);
	LOG_INF("%s: audio_chunk_len: %d\n", __func__, hparams.audio_chunk_len);
	LOG_INF("%s: audio_sample_rate: %d\n", __func__, hparams.audio_sample_rate);
	LOG_INF("%s: audio_n_fft: %d\n", __func__, hparams.audio_n_fft);
	LOG_INF("%s: audio_window_len: %d\n", __func__, hparams.audio_window_len);
	LOG_INF("%s: audio_hop_len: %d\n", __func__, hparams.audio_hop_len);
	}
	LOG_INF("\n");
	LOG_INF("%s: model size: %.2f MiB\n", __func__, model_size / 1024.0 / 1024.0);
	LOG_INF("%s: metadata size: %.2f MiB\n", __func__, ggml_get_mem_size(ctx_meta.get()) / 1024.0 / 1024.0);
	}
	}

	void load_tensors(clip_ctx & ctx_clip) {
	auto & model = ctx_clip.model;
	auto & hparams = model.hparams;
	std::map<std::string, size_t> tensor_offset;
	std::vector<ggml_tensor *> tensors_to_load;

	// TODO @ngxson : support both audio and video in the future
	const char * prefix = model.modality == CLIP_MODALITY_AUDIO ? "a" : "v";

	// get offsets
	for (int64_t i = 0; i < gguf_get_n_tensors(ctx_gguf.get()); ++i) {
	const char * name = gguf_get_tensor_name(ctx_gguf.get(), i);
	tensor_offset[name] = gguf_get_data_offset(ctx_gguf.get()) + gguf_get_tensor_offset(ctx_gguf.get(), i);
	}

	// create data context
	struct ggml_init_params params = {
	/.mem_size =/ static_cast<size_t>(gguf_get_n_tensors(ctx_gguf.get()) + 1) * ggml_tensor_overhead(),
	/.mem_buffer =/ NULL,
	/.no_alloc =/ true,
	};
	ctx_clip.ctx_data.reset(ggml_init(params));
	if (!ctx_clip.ctx_data) {
	throw std::runtime_error(string_format("%s: failed to init ggml context\n", __func__));
	}

	// helper function
	auto get_tensor = [&](const std::string & name, bool required = true) {
	ggml_tensor * cur = ggml_get_tensor(ctx_meta.get(), name.c_str());
	if (!cur && required) {
	throw std::runtime_error(string_format("%s: unable to find tensor %s\n", __func__, name.c_str()));
	}
	if (cur) {
	tensors_to_load.push_back(cur);
	// add tensors to context
	ggml_tensor * data_tensor = ggml_dup_tensor(ctx_clip.ctx_data.get(), cur);
	ggml_set_name(data_tensor, cur->name);
	cur = data_tensor;
	}
	return cur;
	};

	model.class_embedding = get_tensor(TN_CLASS_EMBD, false);

	model.pre_ln_w = get_tensor(string_format(TN_LN_PRE, prefix, "weight"), false);
	model.pre_ln_b = get_tensor(string_format(TN_LN_PRE, prefix, "bias"), false);

	model.post_ln_w = get_tensor(string_format(TN_LN_POST, prefix, "weight"), false);
	model.post_ln_b = get_tensor(string_format(TN_LN_POST, prefix, "bias"), false);

	model.patch_bias = get_tensor(TN_PATCH_BIAS, false);
	model.patch_embeddings_0 = get_tensor(TN_PATCH_EMBD, false);
	model.patch_embeddings_1 = get_tensor(TN_PATCH_EMBD_1, false);

	model.norm_embd_w = get_tensor(string_format(TN_NORM_EMBD, "weight"), false);
	model.norm_embd_b = get_tensor(string_format(TN_NORM_EMBD, "bias"), false);

	model.position_embeddings = get_tensor(string_format(TN_POS_EMBD, prefix), false);

	if (model.proj_type == PROJECTOR_TYPE_GEMMA3NV) {
	hparams.n_layer = 0; // gemma3n does not use normal layer structure
	}

	// layers
	model.layers.resize(hparams.n_layer);
	for (int il = 0; il < hparams.n_layer; ++il) {
	auto & layer = model.layers[il];
	layer.k_w = get_tensor(string_format(TN_ATTN_K, prefix, il, "weight"), false);
	layer.q_w = get_tensor(string_format(TN_ATTN_Q, prefix, il, "weight"), false);
	layer.v_w = get_tensor(string_format(TN_ATTN_V, prefix, il, "weight"), false);
	layer.o_w = get_tensor(string_format(TN_ATTN_OUTPUT, prefix, il, "weight"));
	layer.qkv_w = get_tensor(string_format(TN_ATTN_QKV, prefix, il, "weight"), false);
	layer.k_norm = get_tensor(string_format(TN_ATTN_K_NORM, prefix, il, "weight"), false);
	layer.q_norm = get_tensor(string_format(TN_ATTN_Q_NORM, prefix, il, "weight"), false);
	layer.ln_1_w = get_tensor(string_format(TN_LN_1, prefix, il, "weight"), false);
	layer.ln_2_w = get_tensor(string_format(TN_LN_2, prefix, il, "weight"), false);
	layer.ls_1_w = get_tensor(string_format(TN_LS_1, prefix, il, "weight"), false); // no bias
	layer.ls_2_w = get_tensor(string_format(TN_LS_2, prefix, il, "weight"), false); // no bias

	layer.k_b = get_tensor(string_format(TN_ATTN_K, prefix, il, "bias"), false);
	layer.q_b = get_tensor(string_format(TN_ATTN_Q, prefix, il, "bias"), false);
	layer.v_b = get_tensor(string_format(TN_ATTN_V, prefix, il, "bias"), false);
	layer.o_b = get_tensor(string_format(TN_ATTN_OUTPUT, prefix, il, "bias"), false);
	layer.qkv_b = get_tensor(string_format(TN_ATTN_QKV, prefix, il, "bias"), false);
	layer.ln_1_b = get_tensor(string_format(TN_LN_1, prefix, il, "bias"), false);
	layer.ln_2_b = get_tensor(string_format(TN_LN_2, prefix, il, "bias"), false);

	// ffn
	layer.ff_up_w = get_tensor(string_format(TN_FFN_UP, prefix, il, "weight"));
	layer.ff_up_b = get_tensor(string_format(TN_FFN_UP, prefix, il, "bias"), false);
	layer.ff_gate_w = get_tensor(string_format(TN_FFN_GATE, prefix, il, "weight"), false);
	layer.ff_gate_b = get_tensor(string_format(TN_FFN_GATE, prefix, il, "bias"), false);
	layer.ff_down_w = get_tensor(string_format(TN_FFN_DOWN, prefix, il, "weight"));
	layer.ff_down_b = get_tensor(string_format(TN_FFN_DOWN, prefix, il, "bias"), false);


	// qwen3vl deepstack layer
	layer.deepstack_norm_w = get_tensor(string_format(TN_DEEPSTACK_NORM, il, "weight"), false);
	layer.deepstack_norm_b = get_tensor(string_format(TN_DEEPSTACK_NORM, il, "bias"), false);
	layer.deepstack_fc1_w = get_tensor(string_format(TN_DEEPSTACK_FC1, il, "weight"), false);
	layer.deepstack_fc1_b = get_tensor(string_format(TN_DEEPSTACK_FC1, il, "bias"), false);
	layer.deepstack_fc2_w = get_tensor(string_format(TN_DEEPSTACK_FC2, il, "weight"), false);
	layer.deepstack_fc2_b = get_tensor(string_format(TN_DEEPSTACK_FC2, il, "bias"), false);
	if (layer.has_deepstack()) {
	model.n_deepstack_layers++;
	}

	// some models already exported with legacy (incorrect) naming which is quite messy, let's fix it here
	// note: Qwen model converted from the old surgery script has n_ff = 0, so we cannot use n_ff to check!
	bool is_ffn_swapped = (
	// only old models need this fix
	model.proj_type == PROJECTOR_TYPE_MLP
	\|\| model.proj_type == PROJECTOR_TYPE_MLP_NORM
	\|\| model.proj_type == PROJECTOR_TYPE_LDP
	\|\| model.proj_type == PROJECTOR_TYPE_LDPV2
	\|\| model.proj_type == PROJECTOR_TYPE_QWEN2VL
	\|\| model.proj_type == PROJECTOR_TYPE_QWEN25VL
	\|\| model.proj_type == PROJECTOR_TYPE_GLM_EDGE
	\|\| model.proj_type == PROJECTOR_TYPE_GEMMA3
	\|\| model.proj_type == PROJECTOR_TYPE_IDEFICS3
	\|\| model.proj_type == PROJECTOR_TYPE_MINICPMV
	) && layer.ff_up_w && layer.ff_down_w && layer.ff_down_w->ne[0] == hparams.n_embd;
	if (is_ffn_swapped) {
	// swap up and down weights
	ggml_tensor * tmp = layer.ff_up_w;
	layer.ff_up_w = layer.ff_down_w;
	layer.ff_down_w = tmp;
	// swap up and down biases
	tmp = layer.ff_up_b;
	layer.ff_up_b = layer.ff_down_b;
	layer.ff_down_b = tmp;
	if (il == 0) {
	LOG_WRN("%s: ffn up/down are swapped\n", __func__);
	}
	}
	}


	switch (model.proj_type) {
	case PROJECTOR_TYPE_MLP:
	case PROJECTOR_TYPE_MLP_NORM:
	{
	// LLaVA projection
	model.mm_0_w = get_tensor(string_format(TN_LLAVA_PROJ, 0, "weight"), false);
	model.mm_0_b = get_tensor(string_format(TN_LLAVA_PROJ, 0, "bias"), false);
	// Yi-type llava
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 1, "weight"), false);
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 1, "bias"), false);
	// missing in Yi-type llava
	model.mm_2_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"), false);
	model.mm_2_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"), false);
	// Yi-type llava
	model.mm_3_w = get_tensor(string_format(TN_LLAVA_PROJ, 3, "weight"), false);
	model.mm_3_b = get_tensor(string_format(TN_LLAVA_PROJ, 3, "bias"), false);
	model.mm_4_w = get_tensor(string_format(TN_LLAVA_PROJ, 4, "weight"), false);
	model.mm_4_b = get_tensor(string_format(TN_LLAVA_PROJ, 4, "bias"), false);
	if (model.mm_3_w) {
	// TODO: this is a hack to support Yi-type llava
	model.proj_type = PROJECTOR_TYPE_MLP_NORM;
	}
	model.image_newline = get_tensor(TN_IMAGE_NEWLINE, false);
	} break;
	case PROJECTOR_TYPE_LDP:
	{
	// MobileVLM projection
	model.mm_model_mlp_1_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 1, "weight"));
	model.mm_model_mlp_1_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 1, "bias"));
	model.mm_model_mlp_3_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 3, "weight"));
	model.mm_model_mlp_3_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 3, "bias"));
	model.mm_model_block_1_block_0_0_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 0, "0.weight"));
	model.mm_model_block_1_block_0_1_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 0, "1.weight"));
	model.mm_model_block_1_block_0_1_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 0, "1.bias"));
	model.mm_model_block_1_block_1_fc1_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 1, "fc1.weight"));
	model.mm_model_block_1_block_1_fc1_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 1, "fc1.bias"));
	model.mm_model_block_1_block_1_fc2_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 1, "fc2.weight"));
	model.mm_model_block_1_block_1_fc2_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 1, "fc2.bias"));
	model.mm_model_block_1_block_2_0_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 2, "0.weight"));
	model.mm_model_block_1_block_2_1_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 2, "1.weight"));
	model.mm_model_block_1_block_2_1_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 1, 2, "1.bias"));
	model.mm_model_block_2_block_0_0_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 0, "0.weight"));
	model.mm_model_block_2_block_0_1_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 0, "1.weight"));
	model.mm_model_block_2_block_0_1_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 0, "1.bias"));
	model.mm_model_block_2_block_1_fc1_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 1, "fc1.weight"));
	model.mm_model_block_2_block_1_fc1_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 1, "fc1.bias"));
	model.mm_model_block_2_block_1_fc2_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 1, "fc2.weight"));
	model.mm_model_block_2_block_1_fc2_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 1, "fc2.bias"));
	model.mm_model_block_2_block_2_0_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 2, "0.weight"));
	model.mm_model_block_2_block_2_1_w = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 2, "1.weight"));
	model.mm_model_block_2_block_2_1_b = get_tensor(string_format(TN_MVLM_PROJ_BLOCK, 2, 2, "1.bias"));
	} break;
	case PROJECTOR_TYPE_LDPV2:
	{
	// MobilVLM_V2 projection
	model.mm_model_mlp_0_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 0, "weight"));
	model.mm_model_mlp_0_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 0, "bias"));
	model.mm_model_mlp_2_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 2, "weight"));
	model.mm_model_mlp_2_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 2, "bias"));
	model.mm_model_peg_0_w = get_tensor(string_format(TN_MVLM_PROJ_PEG, 0, "weight"));
	model.mm_model_peg_0_b = get_tensor(string_format(TN_MVLM_PROJ_PEG, 0, "bias"));
	} break;
	case PROJECTOR_TYPE_MINICPMV:
	{
	// model.mm_model_pos_embed = get_tensor(new_clip->ctx_data, TN_MINICPMV_POS_EMBD);
	model.mm_model_pos_embed_k = get_tensor(TN_MINICPMV_POS_EMBD_K);
	model.mm_model_query = get_tensor(TN_MINICPMV_QUERY);
	model.mm_model_proj = get_tensor(TN_MINICPMV_PROJ);
	model.mm_model_kv_proj = get_tensor(TN_MINICPMV_KV_PROJ);
	model.mm_model_attn_q_w = get_tensor(string_format(TN_MINICPMV_ATTN, "q", "weight"));
	model.mm_model_attn_k_w = get_tensor(string_format(TN_MINICPMV_ATTN, "k", "weight"));
	model.mm_model_attn_v_w = get_tensor(string_format(TN_MINICPMV_ATTN, "v", "weight"));
	model.mm_model_attn_q_b = get_tensor(string_format(TN_MINICPMV_ATTN, "q", "bias"));
	model.mm_model_attn_k_b = get_tensor(string_format(TN_MINICPMV_ATTN, "k", "bias"));
	model.mm_model_attn_v_b = get_tensor(string_format(TN_MINICPMV_ATTN, "v", "bias"));
	model.mm_model_attn_o_w = get_tensor(string_format(TN_MINICPMV_ATTN, "out", "weight"));
	model.mm_model_attn_o_b = get_tensor(string_format(TN_MINICPMV_ATTN, "out", "bias"));
	model.mm_model_ln_q_w = get_tensor(string_format(TN_MINICPMV_LN, "q", "weight"));
	model.mm_model_ln_q_b = get_tensor(string_format(TN_MINICPMV_LN, "q", "bias"));
	model.mm_model_ln_kv_w = get_tensor(string_format(TN_MINICPMV_LN, "kv", "weight"));
	model.mm_model_ln_kv_b = get_tensor(string_format(TN_MINICPMV_LN, "kv", "bias"));
	model.mm_model_ln_post_w = get_tensor(string_format(TN_MINICPMV_LN, "post", "weight"));
	model.mm_model_ln_post_b = get_tensor(string_format(TN_MINICPMV_LN, "post", "bias"));
	} break;
	case PROJECTOR_TYPE_GLM_EDGE:
	{
	model.mm_model_adapter_conv_w = get_tensor(string_format(TN_GLM_ADAPER_CONV, "weight"));
	model.mm_model_adapter_conv_b = get_tensor(string_format(TN_GLM_ADAPER_CONV, "bias"));
	model.mm_model_mlp_0_w = get_tensor(string_format(TN_GLM_ADAPTER_LINEAR, "weight"));
	model.mm_model_ln_q_w = get_tensor(string_format(TN_GLM_ADAPTER_NORM_1, "weight"));
	model.mm_model_ln_q_b = get_tensor(string_format(TN_GLM_ADAPTER_NORM_1, "bias"));
	model.mm_model_mlp_1_w = get_tensor(string_format(TN_GLM_ADAPTER_D_H_2_4H, "weight"));
	model.mm_model_mlp_2_w = get_tensor(string_format(TN_GLM_ADAPTER_GATE, "weight"));
	model.mm_model_mlp_3_w = get_tensor(string_format(TN_GLM_ADAPTER_D_4H_2_H, "weight"));
	model.mm_boi = get_tensor(string_format(TN_TOK_GLM_BOI));
	model.mm_eoi = get_tensor(string_format(TN_TOK_GLM_EOI));
	} break;
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	{
	model.mm_0_w = get_tensor(string_format(TN_LLAVA_PROJ, 0, "weight"));
	model.mm_0_b = get_tensor(string_format(TN_LLAVA_PROJ, 0, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"));
	} break;
	case PROJECTOR_TYPE_QWEN3VL:
	{
	model.mm_0_w = get_tensor(string_format(TN_LLAVA_PROJ, 0, "weight"));
	model.mm_0_b = get_tensor(string_format(TN_LLAVA_PROJ, 0, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"));
	} break;
	case PROJECTOR_TYPE_YOUTUVL:
	{
	model.mm_input_norm_w = get_tensor(TN_MM_INP_NORM); // merger.ln_q (RMS norm)
	model.mm_0_w = get_tensor(string_format(TN_LLAVA_PROJ, 0, "weight")); // merger.mlp.0
	model.mm_0_b = get_tensor(string_format(TN_LLAVA_PROJ, 0, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight")); // merger.mlp.2
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"));
	} break;
	case PROJECTOR_TYPE_GLM4V:
	{
	model.projection = get_tensor(TN_MM_PROJECTOR);
	model.mm_ffn_up_w = get_tensor(string_format(TN_MM_UP, "weight"));
	model.mm_ffn_up_b = get_tensor(string_format(TN_MM_UP, "bias"), false);
	model.mm_ffn_gate_w = get_tensor(string_format(TN_MM_GATE, "weight"));
	model.mm_ffn_gate_b = get_tensor(string_format(TN_MM_GATE, "bias"), false);
	model.mm_ffn_down_w = get_tensor(string_format(TN_MM_DOWN, "weight"));
	model.mm_ffn_down_b = get_tensor(string_format(TN_MM_DOWN, "bias"), false);
	model.mm_post_norm_w = get_tensor(string_format(TN_MM_POST_NORM, "weight"));
	model.mm_post_norm_b = get_tensor(string_format(TN_MM_POST_NORM, "bias"), false);
	model.mm_patch_merger_w = get_tensor(string_format(TN_MM_PATCH_MERGER, "weight"));
	model.mm_patch_merger_b = get_tensor(string_format(TN_MM_PATCH_MERGER, "bias"));
	} break;
	case PROJECTOR_TYPE_GEMMA3:
	{
	model.mm_input_proj_w = get_tensor(TN_MM_INP_PROJ);
	model.mm_soft_emb_norm_w = get_tensor(TN_MM_SOFT_EMB_N);
	} break;
	case PROJECTOR_TYPE_GEMMA3NV:
	{
	model.mobilenet_stem_conv_w = get_tensor(TN_MNV5_STEM_CONV, false);
	model.mobilenet_stem_conv_b = get_tensor(TN_MNV5_STEM_BIAS, false);
	model.mobilenet_stem_norm_w = get_tensor(TN_MNV5_STEM_BN, false);

	model.msfa_ffn_expand_w = get_tensor(TN_MNV5_MSFA_FFN_EXP_W, false);
	model.msfa_ffn_expand_bn = get_tensor(TN_MNV5_MSFA_FFN_EXP_BN, false); // Consume BN if present but likely folded
	model.msfa_ffn_project_w = get_tensor(TN_MNV5_MSFA_FFN_PROJ_W, false);
	model.msfa_ffn_project_bn = get_tensor(TN_MNV5_MSFA_FFN_PROJ_BN, false);

	model.msfa_concat_norm_w = get_tensor(TN_MNV5_MSFA_NORM, false);

	// Dynamically load blocks stage by stage
	for (int stage = 0; stage < 4; ++stage) {
	int blocks_found_in_stage = 0;

	for (int blk_idx = 0; ; ++blk_idx) {
	bool found_block = false;
	mobilenetv5_block block;

	// 1. Check for Edge Residual (S0)
	block.s0_conv_exp_w = get_tensor(string_format(TN_MNV5_BLK_S0_EXP_W, stage, blk_idx), false);
	if (block.s0_conv_exp_w) {
	found_block = true;
	block.s0_bn1_w = get_tensor(string_format(TN_MNV5_BLK_S0_BN1_W, stage, blk_idx), false);
	block.s0_conv_pwl_w = get_tensor(string_format(TN_MNV5_BLK_S0_PWL_W, stage, blk_idx), false);
	block.s0_bn2_w = get_tensor(string_format(TN_MNV5_BLK_S0_BN2_W, stage, blk_idx), false);
	}
	// 2. Check for UIR (Universal Inverted Residual)
	else {
	// Check for dw_start OR pw_exp (some UIR blocks skip dw_start)
	block.dw_start_w = get_tensor(string_format(TN_MNV5_BLK_DW_START_W, stage, blk_idx), false);
	block.pw_exp_w = get_tensor(string_format(TN_MNV5_BLK_PW_EXP_W, stage, blk_idx), false);

	if (block.dw_start_w \|\| block.pw_exp_w) {
	found_block = true;
	if (block.dw_start_w) {
	block.dw_start_bn_w = get_tensor(string_format(TN_MNV5_BLK_DW_START_BN, stage, blk_idx), false);
	}
	if (block.pw_exp_w) {
	block.pw_exp_bn_w = get_tensor(string_format(TN_MNV5_BLK_PW_EXP_BN, stage, blk_idx), false);
	}
	block.dw_mid_w = get_tensor(string_format(TN_MNV5_BLK_DW_MID_W, stage, blk_idx), false);
	if (block.dw_mid_w) {
	block.dw_mid_bn_w = get_tensor(string_format(TN_MNV5_BLK_DW_MID_BN, stage, blk_idx), false);
	}
	block.pw_proj_w = get_tensor(string_format(TN_MNV5_BLK_PW_PROJ_W, stage, blk_idx), false);
	if (block.pw_proj_w) {
	block.pw_proj_bn_w = get_tensor(string_format(TN_MNV5_BLK_PW_PROJ_BN, stage, blk_idx), false);
	}
	block.layer_scale_w = get_tensor(string_format(TN_MNV5_BLK_LAYER_SCALE, stage, blk_idx), false);
	}
	}

	// 3. Check for Attention (MQA)
	// Even if UIR/Edge check failed, this might be a pure attention block
	ggml_tensor* attn_q_check = get_tensor(string_format(TN_MNV5_ATTN_Q_W, stage, blk_idx), false);
	if (attn_q_check) {
	found_block = true;
	block.attn_q_w = attn_q_check;
	block.attn_k_w = get_tensor(string_format(TN_MNV5_ATTN_K_W, stage, blk_idx), false);
	block.attn_v_w = get_tensor(string_format(TN_MNV5_ATTN_V_W, stage, blk_idx), false);
	block.attn_o_w = get_tensor(string_format(TN_MNV5_ATTN_O_W, stage, blk_idx), false);
	block.attn_k_dw_w = get_tensor(string_format(TN_MNV5_ATTN_K_DW, stage, blk_idx), false);
	block.attn_k_norm_w = get_tensor(string_format(TN_MNV5_ATTN_K_NORM, stage, blk_idx), false);
	block.attn_v_dw_w = get_tensor(string_format(TN_MNV5_ATTN_V_DW, stage, blk_idx), false);
	block.attn_v_norm_w = get_tensor(string_format(TN_MNV5_ATTN_V_NORM, stage, blk_idx), false);
	block.attn_norm_w = get_tensor(string_format(TN_MNV5_ATTN_NORM, stage, blk_idx), false);
	// Note: Attention blocks also have layer_scale, load it if not already loaded by UIR check
	if (!block.layer_scale_w) {
	block.layer_scale_w = get_tensor(string_format(TN_MNV5_BLK_LAYER_SCALE, stage, blk_idx), false);
	}
	}

	if (found_block) {
	model.mobilenet_blocks.push_back(block);
	blocks_found_in_stage++;
	} else {
	// End of blocks for this stage
	break;
	}
	}

	// Track where this stage ends in the flat vector
	if (blocks_found_in_stage > 0) {
	model.mobilenet_stage_ends.push_back(model.mobilenet_blocks.size() - 1);
	LOG_INF("%s: Stage %d ended at global block index %zu\n", __func__, stage, model.mobilenet_blocks.size() - 1);
	}
	}
	model.mm_input_proj_w = get_tensor(TN_MM_INP_PROJ);
	model.mm_soft_emb_norm_w = get_tensor(TN_MM_SOFT_EMB_N);
	} break;
	case PROJECTOR_TYPE_IDEFICS3:
	{
	model.projection = get_tensor(TN_MM_PROJECTOR);
	} break;
	case PROJECTOR_TYPE_LFM2:
	{
	model.mm_input_norm_w = get_tensor(TN_MM_INP_NORM, false);
	model.mm_input_norm_b = get_tensor(TN_MM_INP_NORM_B, false);
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 1, "bias"));
	model.mm_2_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"));
	model.mm_2_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"));
	} break;
	case PROJECTOR_TYPE_KIMIVL:
	case PROJECTOR_TYPE_PADDLEOCR:
	case PROJECTOR_TYPE_KIMIK25:
	{
	model.mm_input_norm_w = get_tensor(TN_MM_INP_NORM);
	model.mm_input_norm_b = get_tensor(TN_MM_INP_NORM_B);
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 1, "bias"));
	model.mm_2_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"));
	model.mm_2_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"));
	} break;
	case PROJECTOR_TYPE_PIXTRAL:
	{
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 1, "bias"), false);
	model.mm_2_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"));
	model.mm_2_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"), false);
	// [IMG_BREAK] token embedding
	model.token_embd_img_break = get_tensor(TN_TOK_IMG_BREAK);
	// for mistral small 3.1
	model.mm_input_norm_w = get_tensor(TN_MM_INP_NORM, false);
	model.mm_patch_merger_w = get_tensor(string_format(TN_MM_PATCH_MERGER, "weight"), false);
	} break;
	case PROJECTOR_TYPE_LIGHTONOCR:
	{
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 1, "bias"), false);
	model.mm_2_w = get_tensor(string_format(TN_LLAVA_PROJ, 2, "weight"));
	model.mm_2_b = get_tensor(string_format(TN_LLAVA_PROJ, 2, "bias"), false);
	model.mm_input_norm_w = get_tensor(TN_MM_INP_NORM, false);
	model.mm_patch_merger_w = get_tensor(string_format(TN_MM_PATCH_MERGER, "weight"), false);
	} break;
	case PROJECTOR_TYPE_ULTRAVOX:
	{
	model.conv1d_1_w = get_tensor(string_format(TN_CONV1D, 1, "weight"));
	model.conv1d_1_b = get_tensor(string_format(TN_CONV1D, 1, "bias"));
	model.conv1d_2_w = get_tensor(string_format(TN_CONV1D, 2, "weight"));
	model.conv1d_2_b = get_tensor(string_format(TN_CONV1D, 2, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "weight"));
	model.mm_2_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 2, "weight"));
	model.mm_norm_pre_w = get_tensor(string_format(TN_MM_NORM_PRE, "weight"));
	model.mm_norm_mid_w = get_tensor(string_format(TN_MM_NORM_MID, "weight"));
	} break;
	case PROJECTOR_TYPE_QWEN2A:
	{
	model.conv1d_1_w = get_tensor(string_format(TN_CONV1D, 1, "weight"));
	model.conv1d_1_b = get_tensor(string_format(TN_CONV1D, 1, "bias"));
	model.conv1d_2_w = get_tensor(string_format(TN_CONV1D, 2, "weight"));
	model.conv1d_2_b = get_tensor(string_format(TN_CONV1D, 2, "bias"));
	model.mm_fc_w = get_tensor(string_format(TN_MM_AUDIO_FC, "weight"));
	model.mm_fc_b = get_tensor(string_format(TN_MM_AUDIO_FC, "bias"));
	} break;
	case PROJECTOR_TYPE_VOXTRAL:
	{
	model.conv1d_1_w = get_tensor(string_format(TN_CONV1D, 1, "weight"));
	model.conv1d_1_b = get_tensor(string_format(TN_CONV1D, 1, "bias"));
	model.conv1d_2_w = get_tensor(string_format(TN_CONV1D, 2, "weight"));
	model.conv1d_2_b = get_tensor(string_format(TN_CONV1D, 2, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "weight"));
	model.mm_2_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 2, "weight"));
	} break;
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	{
	model.conv1d_1_w = get_tensor(string_format(TN_CONV1D, 1, "weight"));
	model.conv1d_1_b = get_tensor(string_format(TN_CONV1D, 1, "bias"));
	model.conv1d_2_w = get_tensor(string_format(TN_CONV1D, 2, "weight"));
	model.conv1d_2_b = get_tensor(string_format(TN_CONV1D, 2, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "bias"));
	model.mm_2_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 2, "weight"));
	model.mm_2_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 2, "bias"));
	} break;
	case PROJECTOR_TYPE_INTERNVL:
	{
	model.mm_0_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 0, "weight"));
	model.mm_0_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 0, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 1, "bias"));
	model.mm_3_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 3, "weight"));
	model.mm_3_b = get_tensor(string_format(TN_MVLM_PROJ_MLP, 3, "bias"));
	} break;
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	{
	model.mm_0_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 0, "weight"));
	model.mm_1_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 1, "weight"));
	model.mm_3_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 3, "weight"));
	} break;
	case PROJECTOR_TYPE_GLMA:
	{
	model.conv1d_1_w = get_tensor(string_format(TN_CONV1D, 1, "weight"));
	model.conv1d_1_b = get_tensor(string_format(TN_CONV1D, 1, "bias"));
	model.conv1d_2_w = get_tensor(string_format(TN_CONV1D, 2, "weight"));
	model.conv1d_2_b = get_tensor(string_format(TN_CONV1D, 2, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "bias"));
	model.mm_2_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 2, "weight"));
	model.mm_2_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 2, "bias"));
	model.mm_norm_pre_w = get_tensor(string_format(TN_MM_NORM_PRE, "weight"));
	model.mm_norm_pre_b = get_tensor(string_format(TN_MM_NORM_PRE, "bias"));
	model.mm_boi = get_tensor(string_format(TN_TOK_BOI));
	model.mm_eoi = get_tensor(string_format(TN_TOK_EOI));
	} break;
	case PROJECTOR_TYPE_LLAMA4:
	{
	model.mm_model_proj = get_tensor(TN_MM_PROJECTOR);
	model.mm_model_mlp_1_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 1, "weight"));
	model.mm_model_mlp_2_w = get_tensor(string_format(TN_MVLM_PROJ_MLP, 2, "weight"));
	} break;
	case PROJECTOR_TYPE_COGVLM:
	{
	model.mm_model_proj = get_tensor(TN_MM_PROJECTOR);
	model.mm_post_fc_norm_w = get_tensor(string_format(TN_MM_POST_FC_NORM, "weight"));
	model.mm_post_fc_norm_b = get_tensor(string_format(TN_MM_POST_FC_NORM, "bias"));
	model.mm_h_to_4h_w = get_tensor(string_format(TN_MM_H_TO_4H, "weight"));
	model.mm_gate_w = get_tensor(string_format(TN_MM_GATE, "weight"));
	model.mm_4h_to_h_w = get_tensor(string_format(TN_MM_4H_TO_H, "weight"));
	model.mm_boi = get_tensor(TN_TOK_BOI);
	model.mm_eoi = get_tensor(TN_TOK_EOI);
	} break;
	case PROJECTOR_TYPE_JANUS_PRO:
	{
	model.mm_0_w = get_tensor(string_format(TN_LLAVA_PROJ, 0, "weight"));
	model.mm_0_b = get_tensor(string_format(TN_LLAVA_PROJ, 0, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_LLAVA_PROJ, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_LLAVA_PROJ, 1, "bias"));
	} break;
	case PROJECTOR_TYPE_LFM2A:
	{
	for (int i : {0, 2, 3, 5, 6}) {
	model.pre_encode_conv_X_w[i] = get_tensor(string_format(TN_CONV1D, i, "weight"));
	model.pre_encode_conv_X_b[i] = get_tensor(string_format(TN_CONV1D, i, "bias"));
	}
	model.pre_encode_out_w = get_tensor(string_format(TN_PRE_ENCODE_OUT, "weight"));
	model.pre_encode_out_b = get_tensor(string_format(TN_PRE_ENCODE_OUT, "bias"));

	model.mm_0_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 0, "weight"));
	model.mm_0_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 0, "bias"));
	model.mm_1_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "weight"));
	model.mm_1_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 1, "bias"));
	model.mm_3_w = get_tensor(string_format(TN_MM_AUDIO_MLP, 3, "weight"));
	model.mm_3_b = get_tensor(string_format(TN_MM_AUDIO_MLP, 3, "bias"));

	for (int il = 0; il < hparams.n_layer; ++il) {
	auto & layer = model.layers[il];

	layer.ff_norm_w = get_tensor(string_format(TN_FFN_NORM, prefix, il, "weight"));
	layer.ff_norm_b = get_tensor(string_format(TN_FFN_NORM, prefix, il, "bias"));
	layer.ff_norm_1_w = get_tensor(string_format(TN_FFN_NORM_1, prefix, il, "weight"));
	layer.ff_norm_1_b = get_tensor(string_format(TN_FFN_NORM_1, prefix, il, "bias"));
	layer.ff_up_1_w = get_tensor(string_format(TN_FFN_UP_1, prefix, il, "weight"));
	layer.ff_up_1_b = get_tensor(string_format(TN_FFN_UP_1, prefix, il, "bias"));
	layer.ff_down_1_w = get_tensor(string_format(TN_FFN_DOWN_1, prefix, il, "weight"));
	layer.ff_down_1_b = get_tensor(string_format(TN_FFN_DOWN_1, prefix, il, "bias"));

	layer.pos_bias_u = get_tensor(string_format(TN_POS_BIAS_U, prefix, il));
	layer.pos_bias_v = get_tensor(string_format(TN_POS_BIAS_V, prefix, il));

	layer.norm_conv_w = get_tensor(string_format(TN_NORM_CONV, prefix, il, "weight"));
	layer.norm_conv_b = get_tensor(string_format(TN_NORM_CONV, prefix, il, "bias"));

	layer.linear_pos_w = get_tensor(string_format(TN_LINEAR_POS, prefix, il, "weight"));

	layer.conv_norm_w = get_tensor(string_format(TN_CONV_NORM, prefix, il, "weight"));
	layer.conv_norm_b = get_tensor(string_format(TN_CONV_NORM, prefix, il, "bias"));
	layer.conv_dw_w = get_tensor(string_format(TN_CONV_DW, prefix, il, "weight"));
	layer.conv_dw_b = get_tensor(string_format(TN_CONV_DW, prefix, il, "bias"));
	layer.conv_pw1_w = get_tensor(string_format(TN_CONV_PW1, prefix, il, "weight"));
	layer.conv_pw1_b = get_tensor(string_format(TN_CONV_PW1, prefix, il, "bias"));
	layer.conv_pw2_w = get_tensor(string_format(TN_CONV_PW2, prefix, il, "weight"));
	layer.conv_pw2_b = get_tensor(string_format(TN_CONV_PW2, prefix, il, "bias"));
	}
	} break;
	default:
	GGML_ASSERT(false && "unknown projector type");
	}

	// load data
	{
	std::vector<uint8_t> read_buf;

	auto fin = std::ifstream(fname, std::ios::binary);
	if (!fin) {
	throw std::runtime_error(string_format("%s: failed to open %s\n", __func__, fname.c_str()));
	}

	// alloc memory and offload data
	ggml_backend_buffer_type_t buft = ggml_backend_get_default_buffer_type(ctx_clip.backend);
	ctx_clip.buf.reset(ggml_backend_alloc_ctx_tensors_from_buft(ctx_clip.ctx_data.get(), buft));
	ggml_backend_buffer_set_usage(ctx_clip.buf.get(), GGML_BACKEND_BUFFER_USAGE_WEIGHTS);
	for (auto & t : tensors_to_load) {
	ggml_tensor * cur = ggml_get_tensor(ctx_clip.ctx_data.get(), t->name);
	const size_t offset = tensor_offset[t->name];
	fin.seekg(offset, std::ios::beg);
	if (!fin) {
	throw std::runtime_error(string_format("%s: failed to seek for tensor %s\n", __func__, t->name));
	}
	size_t num_bytes = ggml_nbytes(cur);
	if (ggml_backend_buft_is_host(buft)) {
	// for the CPU and Metal backend, we can read directly into the tensor
	fin.read(reinterpret_cast<char *>(cur->data), num_bytes);
	} else {
	// read into a temporary buffer first, then copy to device memory
	read_buf.resize(num_bytes);
	fin.read(reinterpret_cast<char *>(read_buf.data()), num_bytes);
	ggml_backend_tensor_set(cur, read_buf.data(), 0, num_bytes);
	}
	}
	fin.close();

	LOG_DBG("%s: loaded %zu tensors from %s\n", __func__, tensors_to_load.size(), fname.c_str());
	}
	}

	struct support_info_op {
	ggml_tensor * op;

	// true if the op runs on the accelerated ctx_clip.backend
	bool is_accel = true;
	};

	struct support_info_graph {
	// whether the clip_ctx.backend supports flash attention
	bool fattn = true;
	ggml_tensor * fattn_op = nullptr; // for debugging

	std::vector<support_info_op> ops;
	};

	static void warmup(clip_ctx & ctx_clip) {
	// create a fake batch
	const auto & hparams = ctx_clip.model.hparams;
	clip_image_f32_batch batch;
	clip_image_f32_ptr img(clip_image_f32_init());
	if (ctx_clip.model.modality == CLIP_MODALITY_VISION) {
	img->nx = hparams.warmup_image_size;
	img->ny = hparams.warmup_image_size;
	LOG_INF("%s: warmup with image size = %d x %d\n", __func__, img->nx, img->ny);
	} else {
	img->nx = hparams.warmup_audio_size;
	img->ny = hparams.n_mel_bins;
	LOG_INF("%s: warmup with audio size = %d\n", __func__, img->nx);
	}
	batch.entries.push_back(std::move(img));
	warmup(ctx_clip, batch);
	}

	static void warmup(clip_ctx & ctx_clip, const clip_image_f32_batch & batch) {
	support_info_graph info;

	if (ctx_clip.flash_attn_type == CLIP_FLASH_ATTN_TYPE_AUTO) {
	// try to enable flash attention to see if it's supported
	ctx_clip.flash_attn_type = CLIP_FLASH_ATTN_TYPE_ENABLED;
	info = alloc_compute_meta(ctx_clip, batch);
	if (!info.fattn && info.fattn_op) {
	auto op = info.fattn_op;
	LOG_WRN("%s: *****************************************************************\n", __func__);
	LOG_WRN("%s: WARNING: flash attention not supported by %s, memory usage will increase\n", __func__, ggml_backend_name(ctx_clip.backend));
	LOG_WRN("%s: op params: \n", __func__);
	static auto print_shape = [](const char * fn, const char * name, ggml_tensor * t) {
	LOG_WRN("%s: %s: type = %s, ne = [%d %d %d %d], nb = [%d %d %d %d]\n", fn,
	name, ggml_type_name(t->type),
	t->ne[0], t->ne[1], t->ne[2], t->ne[3],
	t->nb[0], t->nb[1], t->nb[2], t->nb[3]);
	};
	print_shape(__func__, " dst", op);
	print_shape(__func__, "src0", op->src[0]);
	print_shape(__func__, "src1", op->src[1]);
	print_shape(__func__, "src2", op->src[2]);
	LOG_WRN("%s: please report this on github as an issue\n", __func__);
	LOG_WRN("%s: *****************************************************************\n", __func__);
	ctx_clip.flash_attn_type = CLIP_FLASH_ATTN_TYPE_DISABLED;
	alloc_compute_meta(ctx_clip, batch);
	}
	} else {
	info = alloc_compute_meta(ctx_clip, batch);
	if (!info.fattn && ctx_clip.flash_attn_type == CLIP_FLASH_ATTN_TYPE_ENABLED) {
	LOG_WRN("%s: flash attention is not supported by the current backend; falling back to CPU (performance will be degraded)\n", __func__);
	}
	}

	ctx_clip.is_allocated = true; // mark buffers as allocated

	LOG_INF("%s: flash attention is %s\n", __func__,
	(ctx_clip.flash_attn_type == CLIP_FLASH_ATTN_TYPE_ENABLED) ? "enabled" : "disabled");

	// print ops that are not supported by the GPU backend (if there is one)
	if (ctx_clip.backend && ctx_clip.backend != ctx_clip.backend_cpu) {
	std::vector<support_info_op> unsupported_ops;
	for (const auto & op : info.ops) {
	if (!op.is_accel) {
	unsupported_ops.push_back(op);
	}
	}
	if (!unsupported_ops.empty()) {
	LOG_WRN("%s: *****************************************************************\n", __func__);
	LOG_WRN("%s: WARNING: the CLIP graph uses unsupported operators by the backend\n", __func__);
	LOG_WRN("%s: the performance will be suboptimal \n", __func__);
	LOG_WRN("%s: list of unsupported ops (backend=%s):\n", __func__, ggml_backend_name(ctx_clip.backend));
	for (const auto & op : unsupported_ops) {
	LOG_WRN("%s: %16s: type = %s, ne = [%d %d %d %d]\n", __func__,
	ggml_op_name(op.op->op),
	ggml_type_name(op.op->type),
	op.op->ne[0], op.op->ne[1], op.op->ne[2], op.op->ne[3]);
	}
	LOG_WRN("%s: flash attention is %s\n", __func__,
	(ctx_clip.flash_attn_type == CLIP_FLASH_ATTN_TYPE_ENABLED) ? "enabled" : "disabled");
	LOG_WRN("%s: please report this on github as an issue\n", __func__);
	LOG_WRN("%s: ref: https://github.com/ggml-org/llama.cpp/pull/16837#issuecomment-3461676118\n", __func__);
	LOG_WRN("%s: *****************************************************************\n", __func__);
	}
	}
	}

	static support_info_graph alloc_compute_meta(clip_ctx & ctx_clip, const clip_image_f32_batch & batch) {
	ctx_clip.buf_compute_meta.resize(ctx_clip.max_nodes * ggml_tensor_overhead() + ggml_graph_overhead());

	ggml_cgraph * gf = clip_image_build_graph(&ctx_clip, batch);
	ggml_backend_sched_reserve(ctx_clip.sched.get(), gf);

	for (size_t i = 0; i < ctx_clip.backend_ptrs.size(); ++i) {
	ggml_backend_t backend = ctx_clip.backend_ptrs[i];
	ggml_backend_buffer_type_t buft = ctx_clip.backend_buft[i];
	size_t size = ggml_backend_sched_get_buffer_size(ctx_clip.sched.get(), backend);
	if (size > 1) {
	LOG_INF("%s: %10s compute buffer size = %8.2f MiB\n", __func__,
	ggml_backend_buft_name(buft),
	size / 1024.0 / 1024.0);
	}
	}

	const int n_splits = ggml_backend_sched_get_n_splits(ctx_clip.sched.get());
	const int n_nodes = ggml_graph_n_nodes(gf);

	LOG_INF("%s: graph splits = %d, nodes = %d\n", __func__, n_splits, n_nodes);

	support_info_graph res {
	/.fattn = / true,
	/.fattn_op = / nullptr,
	/.ops = / {},
	};

	// check op support
	for (int i = 0; i < ggml_graph_n_nodes(gf); i++) {
	ggml_tensor * node = ggml_graph_node(gf, i);
	res.ops.push_back({node, true});
	if (!ggml_backend_supports_op(ctx_clip.backend, node)) {
	res.ops.back().is_accel = false;
	if (node->op == GGML_OP_FLASH_ATTN_EXT) {
	res.fattn = false;
	res.fattn_op = node;
	}
	}
	}

	return res;
	}

	void get_bool(const std::string & key, bool & output, bool required = true) const {
	const int i = gguf_find_key(ctx_gguf.get(), key.c_str());
	if (i < 0) {
	if (required) {
	throw std::runtime_error("Key not found: " + key);
	}
	return;
	}
	output = gguf_get_val_bool(ctx_gguf.get(), i);
	}

	void get_i32(const std::string & key, int & output, bool required = true) const {
	const int i = gguf_find_key(ctx_gguf.get(), key.c_str());
	if (i < 0) {
	if (required) {
	throw std::runtime_error("Key not found: " + key);
	}
	return;
	}
	output = gguf_get_val_i32(ctx_gguf.get(), i);
	}

	void get_u32(const std::string & key, int & output, bool required = true) const {
	const int i = gguf_find_key(ctx_gguf.get(), key.c_str());
	if (i < 0) {
	if (required) {
	throw std::runtime_error("Key not found: " + key);
	}
	return;
	}
	output = gguf_get_val_u32(ctx_gguf.get(), i);
	}

	void get_f32(const std::string & key, float & output, bool required = true) const {
	const int i = gguf_find_key(ctx_gguf.get(), key.c_str());
	if (i < 0) {
	if (required) {
	throw std::runtime_error("Key not found: " + key);
	}
	return;
	}
	output = gguf_get_val_f32(ctx_gguf.get(), i);
	}

	void get_string(const std::string & key, std::string & output, bool required = true) const {
	const int i = gguf_find_key(ctx_gguf.get(), key.c_str());
	if (i < 0) {
	if (required) {
	throw std::runtime_error("Key not found: " + key);
	}
	return;
	}
	output = std::string(gguf_get_val_str(ctx_gguf.get(), i));
	}

	void get_arr_int(const std::string & key, std::vector<int> & output, bool required = true) const {
	const int i = gguf_find_key(ctx_gguf.get(), key.c_str());
	if (i < 0) {
	if (required) {
	throw std::runtime_error("Key not found: " + key);
	}
	return;
	}
	int n = gguf_get_arr_n(ctx_gguf.get(), i);
	output.resize(n);
	const int32_t * values = (const int32_t *)gguf_get_arr_data(ctx_gguf.get(), i);
	for (int i = 0; i < n; ++i) {
	output[i] = values[i];
	}
	}

	static void set_llava_uhd_res_candidates(clip_model & model, const int max_patches_per_side) {
	auto & hparams = model.hparams;
	for (int x = 1; x <= max_patches_per_side; x++) {
	for (int y = 1; y <= max_patches_per_side; y++) {
	if (x == 1 && y == 1) {
	continue; // skip the first point
	}
	hparams.image_res_candidates.push_back(clip_image_size{
	x*hparams.image_size,
	y*hparams.image_size,
	});
	}
	}
	}
	};

	struct clip_init_result clip_init(const char * fname, struct clip_context_params ctx_params) {
	clip_ctx * ctx_vision = nullptr;
	clip_ctx * ctx_audio = nullptr;

	try {
	clip_model_loader loader(fname);
	bool skip_audio = false;

	if (loader.has_vision) {
	ctx_vision = new clip_ctx(ctx_params);
	loader.load_hparams(ctx_vision->model, CLIP_MODALITY_VISION);
	loader.load_tensors(*ctx_vision);
	if (ctx_params.warmup) {
	loader.warmup(*ctx_vision);
	}

	// TODO: we don't support audio for Gemma 3N, but GGUF contains audio tensors
	// we can remove this check when we implement audio support for Gemma 3N
	skip_audio = ctx_vision->model.proj_type == PROJECTOR_TYPE_GEMMA3NV;

	// clip_debug_encode(ctx_vision, 2414, 2414, 0.5f);
	}

	if (loader.has_audio && !skip_audio) {
	ctx_audio = new clip_ctx(ctx_params);
	loader.load_hparams(ctx_audio->model, CLIP_MODALITY_AUDIO);
	loader.load_tensors(*ctx_audio);
	if (ctx_params.warmup) {
	loader.warmup(*ctx_audio);
	}
	}

	} catch (const std::exception & e) {
	LOG_ERR("%s: failed to load model '%s': %s\n", __func__, fname, e.what());

	delete ctx_vision;
	delete ctx_audio;

	return {nullptr, nullptr};
	}

	return {ctx_vision, ctx_audio};
	}

	struct clip_image_size * clip_image_size_init() {
	struct clip_image_size * load_image_size = new struct clip_image_size();
	load_image_size->width = 448;
	load_image_size->height = 448;
	return load_image_size;
	}

	struct clip_image_u8 * clip_image_u8_init() {
	return new clip_image_u8();
	}

	struct clip_image_f32 * clip_image_f32_init() {
	return new clip_image_f32();
	}

	struct clip_image_f32_batch * clip_image_f32_batch_init() {
	return new clip_image_f32_batch();
	}

	unsigned char * clip_image_u8_get_data(struct clip_image_u8 * img, uint32_t * nx, uint32_t * ny) {
	if (nx) *nx = img->nx;
	if (ny) *ny = img->ny;
	return img->buf.data();
	}

	void clip_image_size_free(struct clip_image_size * load_image_size) {
	if (load_image_size == nullptr) {
	return;
	}
	delete load_image_size;
	}
	void clip_image_u8_free(struct clip_image_u8 * img) { delete img; }
	void clip_image_f32_free(struct clip_image_f32 * img) { delete img; }
	void clip_image_u8_batch_free(struct clip_image_u8_batch * batch) { delete batch; }
	void clip_image_f32_batch_free(struct clip_image_f32_batch * batch) { delete batch; }

	size_t clip_image_f32_batch_n_images(const struct clip_image_f32_batch * batch) {
	return batch->entries.size();
	}

	size_t clip_image_f32_batch_nx(const struct clip_image_f32_batch * batch, int idx) {
	if (idx < 0 \|\| idx >= (int)batch->entries.size()) {
	LOG_ERR("%s: invalid index %d\n", __func__, idx);
	return 0;
	}
	return batch->entries[idx]->nx;
	}

	size_t clip_image_f32_batch_ny(const struct clip_image_f32_batch * batch, int idx) {
	if (idx < 0 \|\| idx >= (int)batch->entries.size()) {
	LOG_ERR("%s: invalid index %d\n", __func__, idx);
	return 0;
	}
	return batch->entries[idx]->ny;
	}

	clip_image_f32 * clip_image_f32_get_img(const struct clip_image_f32_batch * batch, int idx) {
	if (idx < 0 \|\| idx >= (int)batch->entries.size()) {
	LOG_ERR("%s: invalid index %d\n", __func__, idx);
	return nullptr;
	}
	return batch->entries[idx].get();
	}

	void clip_build_img_from_pixels(const unsigned char * rgb_pixels, int nx, int ny, clip_image_u8 * img) {
	img->nx = nx;
	img->ny = ny;
	img->buf.resize(3 * nx * ny);
	memcpy(img->buf.data(), rgb_pixels, img->buf.size());
	}

	// Normalize image to float32 - careful with pytorch .to(model.device, dtype=torch.float16) - this sometimes reduces precision (32>16>32), sometimes not
	static void normalize_image_u8_to_f32(const clip_image_u8 & src, clip_image_f32 & dst, const float mean[3], const float std[3]) {
	dst.nx = src.nx;
	dst.ny = src.ny;
	dst.buf.resize(src.buf.size());

	// TODO @ngxson : seems like this could be done more efficiently on cgraph
	for (size_t i = 0; i < src.buf.size(); ++i) {
	int c = i % 3; // rgb
	dst.buf[i] = (static_cast<float>(src.buf[i]) / 255.0f - mean[c]) / std[c];
	}
	}

	// set of tools to manupulate images
	// in the future, we can have HW acceleration by allowing this struct to access 3rd party lib like imagick or opencv
	struct img_tool {
	enum resize_algo {
	RESIZE_ALGO_BILINEAR,
	RESIZE_ALGO_BICUBIC,
	// RESIZE_ALGO_LANCZOS, // TODO
	};

	static void resize(
	const clip_image_u8 & src,
	clip_image_u8 & dst,
	const clip_image_size & target_resolution,
	resize_algo algo,
	bool add_padding = true, // TODO: define the behavior for add_padding = false
	std::array<uint8_t, 3> pad_color = {0, 0, 0}) {
	dst.nx = target_resolution.width;
	dst.ny = target_resolution.height;
	dst.buf.resize(3 * dst.nx * dst.ny);

	if (dst.nx == src.nx && dst.ny == src.ny) {
	// no resize needed, simple copy
	dst.buf = src.buf;
	return;
	}

	if (!add_padding) {
	// direct resize
	switch (algo) {
	case RESIZE_ALGO_BILINEAR:
	resize_bilinear(src, dst, target_resolution.width, target_resolution.height);
	break;
	case RESIZE_ALGO_BICUBIC:
	resize_bicubic(src, dst, target_resolution.width, target_resolution.height);
	break;
	default:
	throw std::runtime_error("Unsupported resize algorithm");
	}
	} else {
	// resize with padding
	clip_image_u8 resized_image;
	float scale_w = static_cast<float>(target_resolution.width) / src.nx;
	float scale_h = static_cast<float>(target_resolution.height) / src.ny;
	float scale = std::min(scale_w, scale_h);
	int new_width = std::min(static_cast<int>(std::ceil(src.nx * scale)), target_resolution.width);
	int new_height = std::min(static_cast<int>(std::ceil(src.ny * scale)), target_resolution.height);

	switch (algo) {
	case RESIZE_ALGO_BILINEAR:
	resize_bilinear(src, resized_image, new_width, new_height);
	break;
	case RESIZE_ALGO_BICUBIC:
	resize_bicubic(src, resized_image, new_width, new_height);
	break;
	default:
	throw std::runtime_error("Unsupported resize algorithm");
	}

	// fill dst with pad_color
	fill(dst, pad_color);

	int offset_x = (target_resolution.width - new_width) / 2;
	int offset_y = (target_resolution.height - new_height) / 2;

	composite(dst, resized_image, offset_x, offset_y);
	}
	}

	static void crop(const clip_image_u8 & image, clip_image_u8 & dst, int x, int y, int w, int h) {
	dst.nx = w;
	dst.ny = h;
	dst.buf.resize(3 * w * h);

	for (int i = 0; i < h; ++i) {
	for (int j = 0; j < w; ++j) {
	int src_idx = 3 * ((y + i)*image.nx + (x + j));
	int dst_idx = 3 * (i*w + j);
	dst.buf[dst_idx] = image.buf[src_idx];
	dst.buf[dst_idx + 1] = image.buf[src_idx + 1];
	dst.buf[dst_idx + 2] = image.buf[src_idx + 2];
	}
	}
	}

	// calculate the size of the resized image, while preserving the aspect ratio
	// the calculated size will be aligned to the nearest multiple of align_size
	// if H or W size is larger than longest_edge, it will be resized to longest_edge
	static clip_image_size calc_size_preserved_ratio(const clip_image_size & inp_size, const int align_size, const int longest_edge) {
	GGML_ASSERT(align_size > 0);
	if (inp_size.width <= 0 \|\| inp_size.height <= 0 \|\| longest_edge <= 0) {
	return {0, 0};
	}

	float scale = std::min(static_cast<float>(longest_edge) / inp_size.width,
	static_cast<float>(longest_edge) / inp_size.height);

	float target_width_f = static_cast<float>(inp_size.width) * scale;
	float target_height_f = static_cast<float>(inp_size.height) * scale;

	auto ceil_by_factor = [f = align_size](float x) { return static_cast<int>(std::ceil(x / static_cast<float>(f))) * f; };
	int aligned_width = ceil_by_factor(target_width_f);
	int aligned_height = ceil_by_factor(target_height_f);

	return {aligned_width, aligned_height};
	}

	// calculate the size of the resized image, while preserving the aspect ratio
	// the calculated size will have min_pixels <= W*H <= max_pixels
	// this is referred as "smart_resize" in transformers code
	static clip_image_size calc_size_preserved_ratio(const clip_image_size & inp_size, const int align_size, const int min_pixels, const int max_pixels) {
	GGML_ASSERT(align_size > 0);
	const int width = inp_size.width;
	const int height = inp_size.height;

	auto round_by_factor = [f = align_size](float x) { return static_cast<int>(std::round(x / static_cast<float>(f))) * f; };
	auto ceil_by_factor = [f = align_size](float x) { return static_cast<int>(std::ceil(x / static_cast<float>(f))) * f; };
	auto floor_by_factor = [f = align_size](float x) { return static_cast<int>(std::floor(x / static_cast<float>(f))) * f; };

	// always align up first
	int h_bar = std::max(align_size, round_by_factor(height));
	int w_bar = std::max(align_size, round_by_factor(width));

	if (h_bar * w_bar > max_pixels) {
	const auto beta = std::sqrt(static_cast<float>(height * width) / max_pixels);
	h_bar = std::max(align_size, floor_by_factor(height / beta));
	w_bar = std::max(align_size, floor_by_factor(width / beta));
	} else if (h_bar * w_bar < min_pixels) {
	const auto beta = std::sqrt(static_cast<float>(min_pixels) / (height * width));
	h_bar = ceil_by_factor(height * beta);
	w_bar = ceil_by_factor(width * beta);
	}

	return {w_bar, h_bar};
	}

	// draw src image into dst image at offset (offset_x, offset_y)
	static void composite(clip_image_u8 & dst, const clip_image_u8 & src, int offset_x, int offset_y) {
	for (int y = 0; y < src.ny; ++y) {
	for (int x = 0; x < src.nx; ++x) {
	int dx = x + offset_x;
	int dy = y + offset_y;
	// skip pixels that would be out of bounds in the destination
	if (dx < 0 \|\| dy < 0 \|\| dx >= dst.nx \|\| dy >= dst.ny) {
	continue;
	}
	size_t dst_idx = 3 * (static_cast<size_t>(dy) * dst.nx + static_cast<size_t>(dx));
	size_t src_idx = 3 * (static_cast<size_t>(y) * src.nx + static_cast<size_t>(x));
	dst.buf[dst_idx + 0] = src.buf[src_idx + 0];
	dst.buf[dst_idx + 1] = src.buf[src_idx + 1];
	dst.buf[dst_idx + 2] = src.buf[src_idx + 2];
	}
	}
	}

	// fill the image with a solid color
	static void fill(clip_image_u8 & img, const std::array<uint8_t, 3> & color) {
	for (size_t i = 0; i < img.buf.size(); i += 3) {
	img.buf[i] = color[0];
	img.buf[i + 1] = color[1];
	img.buf[i + 2] = color[2];
	}
	}

	private:
	// Bilinear resize function
	static void resize_bilinear(const clip_image_u8 & src, clip_image_u8 & dst, int target_width, int target_height) {
	dst.nx = target_width;
	dst.ny = target_height;
	dst.buf.resize(3 * target_width * target_height);

	float x_ratio = static_cast<float>(src.nx - 1) / target_width;
	float y_ratio = static_cast<float>(src.ny - 1) / target_height;

	for (int y = 0; y < target_height; y++) {
	for (int x = 0; x < target_width; x++) {
	float px = x_ratio * x;
	float py = y_ratio * y;
	int x_floor = static_cast<int>(px);
	int y_floor = static_cast<int>(py);
	float x_lerp = px - x_floor;
	float y_lerp = py - y_floor;

	for (int c = 0; c < 3; c++) {
	float top = lerp(
	static_cast<float>(src.buf[3 * (y_floor * src.nx + x_floor) + c]),
	static_cast<float>(src.buf[3 * (y_floor * src.nx + (x_floor + 1)) + c]),
	x_lerp
	);
	float bottom = lerp(
	static_cast<float>(src.buf[3 * ((y_floor + 1) * src.nx + x_floor) + c]),
	static_cast<float>(src.buf[3 * ((y_floor + 1) * src.nx + (x_floor + 1)) + c]),
	x_lerp
	);
	dst.buf[3 * (y * target_width + x) + c] = static_cast<uint8_t>(lerp(top, bottom, y_lerp));
	}
	}
	}
	}

	// Bicubic resize function
	// part of image will be cropped if the aspect ratio is different
	static bool resize_bicubic(const clip_image_u8 & img, clip_image_u8 & dst, int target_width, int target_height) {
	const int nx = img.nx;
	const int ny = img.ny;

	dst.nx = target_width;
	dst.ny = target_height;
	dst.buf.resize(3 * target_width * target_height);

	float Cc;
	float C[5] = {};
	float d0, d2, d3, a0, a1, a2, a3;
	int i, j, k, jj;
	int x, y;
	float dx, dy;
	float tx, ty;

	tx = (float)nx / (float)target_width;
	ty = (float)ny / (float)target_height;

	// Bicubic interpolation; adapted from ViT.cpp, inspired from :
	// -> https://github.com/yglukhov/bicubic-interpolation-image-processing/blob/master/libimage.c#L36
	// -> https://en.wikipedia.org/wiki/Bicubic_interpolation

	for (i = 0; i < target_height; i++) {
	for (j = 0; j < target_width; j++) {
	x = (int)(tx * j);
	y = (int)(ty * i);

	dx = tx * j - x;
	dy = ty * i - y;

	for (k = 0; k < 3; k++) {
	for (jj = 0; jj <= 3; jj++) {
	d0 = img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x - 1, 0, nx - 1)) * 3 + k] - img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x, 0, nx - 1)) * 3 + k];
	d2 = img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x + 1, 0, nx - 1)) * 3 + k] - img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x, 0, nx - 1)) * 3 + k];
	d3 = img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x + 2, 0, nx - 1)) * 3 + k] - img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x, 0, nx - 1)) * 3 + k];
	a0 = img.buf[(clip(y - 1 + jj, 0, ny - 1) * nx + clip(x, 0, nx - 1)) * 3 + k];

	a1 = -1.0 / 3 * d0 + d2 - 1.0 / 6 * d3;
	a2 = 1.0 / 2 * d0 + 1.0 / 2 * d2;
	a3 = -1.0 / 6 * d0 - 1.0 / 2 * d2 + 1.0 / 6 * d3;

	C[jj] = a0 + a1 * dx + a2 * dx * dx + a3 * dx * dx * dx;

	d0 = C[0] - C[1];
	d2 = C[2] - C[1];
	d3 = C[3] - C[1];
	a0 = C[1];
	a1 = -1.0 / 3 * d0 + d2 - 1.0 / 6 * d3;
	a2 = 1.0 / 2 * d0 + 1.0 / 2 * d2;
	a3 = -1.0 / 6 * d0 - 1.0 / 2 * d2 + 1.0 / 6 * d3;
	Cc = a0 + a1 * dy + a2 * dy * dy + a3 * dy * dy * dy;

	const uint8_t Cc2 = std::min(std::max(std::round(Cc), 0.0f), 255.0f);
	dst.buf[(i * target_width + j) * 3 + k] = float(Cc2);
	}
	}
	}
	}

	return true;
	}

	static inline int clip(int x, int lower, int upper) {
	return std::max(lower, std::min(x, upper));
	}

	// Linear interpolation between two points
	static inline float lerp(float s, float e, float t) {
	return s + (e - s) * t;
	}
	};

	/**
	* implementation of LLaVA-UHD:
	* - https://arxiv.org/pdf/2403.11703
	* - https://github.com/thunlp/LLaVA-UHD
	* - https://github.com/thunlp/LLaVA-UHD/blob/302301bc2175f7e717fb8548516188e89f649753/llava_uhd/train/llava-uhd/slice_logic.py#L118
	*
	* overview:
	* - an image always have a single overview (downscaled image)
	* - an image can have 0 or multiple slices, depending on the image size
	* - each slice can then be considered as a separate image
	*
	* for example:
	*
	* [overview] --> [slice 1] --> [slice 2]
	* \| \|
	* +--> [slice 3] --> [slice 4]
	*/
	struct llava_uhd {
	struct slice_coordinates {
	int x;
	int y;
	clip_image_size size;
	};

	struct slice_instructions {
	clip_image_size overview_size; // size of downscaled image
	clip_image_size refined_size; // size of image right before slicing (must be multiple of slice size)
	clip_image_size grid_size; // grid_size.width * grid_size.height = number of slices
	std::vector<slice_coordinates> slices;

	img_tool::resize_algo interpolation_overview = img_tool::RESIZE_ALGO_BILINEAR;
	bool padding_overview = false; // if true, refine image will be padded to the grid size (e.g. llava-1.6)
	std::array<uint8_t, 3> pad_color_overview = {0, 0, 0};

	img_tool::resize_algo interpolation_refined = img_tool::RESIZE_ALGO_BICUBIC;
	bool padding_refined = false; // if true, refine image will be padded to the grid size (e.g. llava-1.6)
	std::array<uint8_t, 3> pad_color_refined = {0, 0, 0};
	};

	static slice_instructions get_slice_instructions(struct clip_ctx * ctx, const clip_image_size & original_size) {
	slice_instructions res;
	const int patch_size = clip_get_patch_size(ctx);
	const int slice_size = clip_get_image_size(ctx);
	const int original_width = original_size.width;
	const int original_height = original_size.height;

	const bool has_slices = original_size.width > slice_size \|\| original_size.height > slice_size;
	const bool has_pinpoints = !ctx->model.hparams.image_res_candidates.empty();

	if (!has_slices) {
	// skip slicing logic
	res.overview_size = clip_image_size{slice_size, slice_size};
	res.refined_size = clip_image_size{0, 0};
	res.grid_size = clip_image_size{0, 0};

	return res;
	}

	if (has_pinpoints) {
	// has pinpoints, use them to calculate the grid size (e.g. llava-1.6)
	auto refine_size = llava_uhd::select_best_resolution(
	original_size,
	ctx->model.hparams.image_res_candidates);
	res.overview_size = clip_image_size{slice_size, slice_size};
	res.refined_size = refine_size;
	res.grid_size = clip_image_size{0, 0};
	res.padding_refined = true;
	res.interpolation_refined = img_tool::RESIZE_ALGO_BILINEAR; // preserve old behavior when padding

	LOG_DBG("%s: using pinpoints for slicing\n", __func__);
	LOG_DBG("%s: original size: %d x %d, overview size: %d x %d, refined size: %d x %d\n",
	__func__, original_width, original_height,
	res.overview_size.width, res.overview_size.height,
	res.refined_size.width, res.refined_size.height);

	for (int y = 0; y < refine_size.height; y += slice_size) {
	for (int x = 0; x < refine_size.width; x += slice_size) {
	slice_coordinates slice;
	slice.x = x;
	slice.y = y;
	slice.size.width = std::min(slice_size, refine_size.width - x);
	slice.size.height = std::min(slice_size, refine_size.height - y);
	res.slices.push_back(slice);
	LOG_DBG("%s: slice %d: x=%d, y=%d, size=%dx%d\n",
	__func__, (int)res.slices.size() - 1,
	slice.x, slice.y, slice.size.width, slice.size.height);
	}
	}

	res.grid_size.height = refine_size.height / slice_size;
	res.grid_size.width = refine_size.width / slice_size;
	LOG_DBG("%s: grid size: %d x %d\n", __func__, res.grid_size.width, res.grid_size.height);

	return res;
	}

	// no pinpoints, dynamically calculate the grid size (e.g. minicpmv)

	auto best_size = get_best_resize(original_size, slice_size, patch_size, !has_slices);
	res.overview_size = best_size;

	{
	const int max_slice_nums = 9; // TODO: this is only used by minicpmv, maybe remove it
	const float log_ratio = log((float)original_width / original_height);
	const float ratio = (float)original_width * original_height / (slice_size * slice_size);
	const int multiple = fmin(ceil(ratio), max_slice_nums);

	auto best_grid = get_best_grid(max_slice_nums, multiple, log_ratio);
	auto refine_size = get_refine_size(original_size, best_grid, slice_size, patch_size, true);
	res.grid_size = best_grid;
	res.refined_size = refine_size;

	LOG_DBG("%s: original size: %d x %d, overview size: %d x %d, refined size: %d x %d, grid size: %d x %d\n",
	__func__, original_width, original_height,
	res.overview_size.width, res.overview_size.height,
	res.refined_size.width, res.refined_size.height,
	res.grid_size.width, res.grid_size.height);

	int width = refine_size.width;
	int height = refine_size.height;
	int grid_x = int(width / best_grid.width);
	int grid_y = int(height / best_grid.height);
	for (int patches_y = 0, ic = 0;
	patches_y < refine_size.height && ic < best_grid.height;
	patches_y += grid_y, ic += 1) {
	for (int patches_x = 0, jc = 0;
	patches_x < refine_size.width && jc < best_grid.width;
	patches_x += grid_x, jc += 1) {
	slice_coordinates slice;
	slice.x = patches_x;
	slice.y = patches_y;
	slice.size.width = grid_x;
	slice.size.height = grid_y;
	res.slices.push_back(slice);
	LOG_DBG("%s: slice %d: x=%d, y=%d, size=%dx%d\n",
	__func__, (int)res.slices.size() - 1,
	slice.x, slice.y, slice.size.width, slice.size.height);
	}
	}
	}

	return res;
	}

	static std::vector<clip_image_u8_ptr> slice_image(const clip_image_u8 * img, const slice_instructions & inst) {
	std::vector<clip_image_u8_ptr> output;

	// resize to overview size
	clip_image_u8_ptr resized_img(clip_image_u8_init());
	img_tool::resize(img, resized_img, inst.overview_size, inst.interpolation_overview,
	inst.padding_overview, inst.pad_color_overview);
	output.push_back(std::move(resized_img));

	if (inst.slices.empty()) {
	// no slices, just return the resized image
	return output;
	}

	// resize to refined size
	clip_image_u8_ptr refined_img(clip_image_u8_init());
	img_tool::resize(img, refined_img, inst.refined_size, inst.interpolation_refined,
	inst.padding_refined, inst.pad_color_refined);

	// create slices
	for (const auto & slice : inst.slices) {
	int x = slice.x;
	int y = slice.y;
	int w = slice.size.width;
	int h = slice.size.height;

	clip_image_u8_ptr img_slice(clip_image_u8_init());
	img_tool::crop(refined_img, img_slice, x, y, w, h);
	output.push_back(std::move(img_slice));
	}

	return output;
	}

	private:
	static clip_image_size get_best_resize(const clip_image_size & original_size, int scale_resolution, int patch_size, bool allow_upscale = false) {
	int width = original_size.width;
	int height = original_size.height;
	if ((width * height > scale_resolution * scale_resolution) \|\| allow_upscale) {
	float r = static_cast<float>(width) / height;
	height = static_cast<int>(scale_resolution / std::sqrt(r));
	width = static_cast<int>(height * r);
	}
	clip_image_size res;
	res.width = ensure_divide(width, patch_size);
	res.height = ensure_divide(height, patch_size);
	return res;
	}

	static clip_image_size resize_maintain_aspect_ratio(const clip_image_size & orig, const clip_image_size & target_max) {
	float scale_width = static_cast<float>(target_max.width) / orig.width;
	float scale_height = static_cast<float>(target_max.height) / orig.height;
	float scale = std::min(scale_width, scale_height);
	return clip_image_size{
	static_cast<int>(orig.width * scale),
	static_cast<int>(orig.height * scale),
	};
	}

	/**
	* Selects the best resolution from a list of possible resolutions based on the original size.
	*
	* For example, when given a list of resolutions:
	* - 100x100
	* - 200x100
	* - 100x200
	* - 200x200
	*
	* And an input image of size 111x200, then 100x200 is the best fit (least wasted resolution).
	*
	* @param original_size The original size of the image
	* @param possible_resolutions A list of possible resolutions
	* @return The best fit resolution
	*/
	static clip_image_size select_best_resolution(const clip_image_size & original_size, const std::vector<clip_image_size> & possible_resolutions) {
	clip_image_size best_fit;
	int min_wasted_area = std::numeric_limits<int>::max();
	int max_effective_resolution = 0;

	for (const clip_image_size & candidate : possible_resolutions) {
	auto target_size = resize_maintain_aspect_ratio(original_size, candidate);
	int effective_resolution = std::min(
	target_size.width * target_size.height,
	original_size.width * original_size.height);
	int wasted_area = (candidate.width * candidate.height) - effective_resolution;

	if (effective_resolution > max_effective_resolution \|\| (effective_resolution == max_effective_resolution && wasted_area < min_wasted_area)) {
	max_effective_resolution = effective_resolution;
	min_wasted_area = wasted_area;
	best_fit = candidate;
	}

	LOG_DBG("%s: candidate: %d x %d, target: %d x %d, wasted: %d, effective: %d\n", __func__, candidate.width, candidate.height, target_size.width, target_size.height, wasted_area, effective_resolution);
	}

	return best_fit;
	}

	static int ensure_divide(int length, int patch_size) {
	return std::max(static_cast<int>(std::round(static_cast<float>(length) / patch_size) * patch_size), patch_size);
	}

	static clip_image_size get_refine_size(const clip_image_size & original_size, const clip_image_size & grid, int scale_resolution, int patch_size, bool allow_upscale = false) {
	int width = original_size.width;
	int height = original_size.height;
	int grid_x = grid.width;
	int grid_y = grid.height;

	int refine_width = ensure_divide(width, grid_x);
	int refine_height = ensure_divide(height, grid_y);

	clip_image_size grid_size;
	grid_size.width = refine_width / grid_x;
	grid_size.height = refine_height / grid_y;

	auto best_grid_size = get_best_resize(grid_size, scale_resolution, patch_size, allow_upscale);
	int best_grid_width = best_grid_size.width;
	int best_grid_height = best_grid_size.height;

	clip_image_size refine_size;
	refine_size.width = best_grid_width * grid_x;
	refine_size.height = best_grid_height * grid_y;
	return refine_size;
	}

	static clip_image_size get_best_grid(const int max_slice_nums, const int multiple, const float log_ratio) {
	std::vector<int> candidate_split_grids_nums;
	for (int i : {multiple - 1, multiple, multiple + 1}) {
	if (i == 1 \|\| i > max_slice_nums) {
	continue;
	}
	candidate_split_grids_nums.push_back(i);
	}

	std::vector<clip_image_size> candidate_grids;
	for (int split_grids_nums : candidate_split_grids_nums) {
	int m = 1;
	while (m <= split_grids_nums) {
	if (split_grids_nums % m == 0) {
	candidate_grids.push_back(clip_image_size{m, split_grids_nums / m});
	}
	++m;
	}
	}

	clip_image_size best_grid{1, 1};
	float min_error = std::numeric_limits<float>::infinity();
	for (const auto& grid : candidate_grids) {
	float error = std::abs(log_ratio - std::log(1.0 * grid.width / grid.height));
	if (error < min_error) {
	best_grid = grid;
	min_error = error;
	}
	}
	return best_grid;
	}
	};

	// ref: https://github.com/huggingface/transformers/blob/v5.1.0/src/transformers/models/lfm2_vl/image_processing_lfm2_vl_fast.py
	// some of the logic is similar to llava_uhd, but with different hyperparameters and some logic is unique (e.g. grid layout)
	struct lfm2_vl_image_processor {
	// ref: https://huggingface.co/LiquidAI/LFM2.5-VL-1.6B/blob/main/processor_config.json
	static constexpr int min_tiles = 2;
	static constexpr int max_tiles = 10;
	static constexpr float max_pixels_tolerance = 2.0f;
	static constexpr int tile_size = 512;

	static llava_uhd::slice_instructions get_slice_instructions(struct clip_ctx * ctx, const clip_image_size & original_size) {
	llava_uhd::slice_instructions inst;
	const auto & params = ctx->model.hparams;
	const int align_size = params.patch_size * params.n_merge;

	inst.interpolation_overview = img_tool::RESIZE_ALGO_BILINEAR;
	inst.interpolation_refined = img_tool::RESIZE_ALGO_BILINEAR;
	inst.overview_size = img_tool::calc_size_preserved_ratio(original_size, align_size, params.image_min_pixels, params.image_max_pixels);

	// tile if either dimension exceeds tile_size with tolerance
	const bool needs_tiling = original_size.width > tile_size * max_pixels_tolerance \|\| original_size.height > tile_size * max_pixels_tolerance;

	if (!needs_tiling) {
	inst.refined_size = clip_image_size{0, 0};
	inst.grid_size = clip_image_size{0, 0};
	return inst;
	}

	const clip_image_size grid = get_grid_layout(original_size.height, original_size.width);

	inst.grid_size = grid;
	inst.refined_size = clip_image_size{tile_size * grid.width, tile_size * grid.height};

	LOG_DBG("%s: original size: %d x %d, overview size: %d x %d, refined size: %d x %d, grid size: %d x %d\n",
	__func__,
	original_size.width, original_size.height,
	inst.overview_size.width, inst.overview_size.height,
	inst.refined_size.width, inst.refined_size.height,
	grid.width, grid.height);

	for (int row = 0; row < grid.height; row++) {
	for (int col = 0; col < grid.width; col++) {
	llava_uhd::slice_coordinates slice;
	slice.x = col * tile_size;
	slice.y = row * tile_size;
	slice.size = clip_image_size{tile_size, tile_size};
	inst.slices.push_back(slice);
	LOG_DBG("%s: slice %d: x=%d, y=%d, size=%d x %d\n",
	__func__, (int)inst.slices.size() - 1,
	slice.x, slice.y, slice.size.width, slice.size.height);
	}
	}

	return inst;
	}

	private:
	static clip_image_size find_closest_aspect_ratio(
	float aspect_ratio,
	const std::vector<clip_image_size> & target_ratios,
	int width, int height) {
	float best_ratio_diff = std::numeric_limits<float>::max();
	clip_image_size best_ratio = {1, 1};
	const float area = static_cast<float>(width * height);

	for (const auto & ratio : target_ratios) {
	const float target_aspect_ratio = static_cast<float>(ratio.width) / ratio.height;
	const float ratio_diff = std::abs(aspect_ratio - target_aspect_ratio);
	if (ratio_diff < best_ratio_diff) {
	best_ratio_diff = ratio_diff;
	best_ratio = ratio;
	} else if (ratio_diff == best_ratio_diff) {
	const float target_area = static_cast<float>(tile_size * tile_size * ratio.width * ratio.height);
	if (area > 0.5f * target_area) {
	best_ratio = ratio;
	}
	}
	}
	return best_ratio;
	}

	static std::vector<clip_image_size> get_target_ratios() {
	std::vector<clip_image_size> ratios;
	for (int n = min_tiles; n <= max_tiles; n++) {
	for (int w = 1; w <= n; w++) {
	for (int h = 1; h <= n; h++) {
	if (w * h >= min_tiles && w * h <= max_tiles) {
	bool found = false;
	for (const auto & r : ratios) {
	if (r.width == w && r.height == h) {
	found = true;
	break;
	}
	}
	if (!found) {
	ratios.push_back({w, h});
	}
	}
	}
	}
	}
	std::sort(ratios.begin(), ratios.end(), [](const clip_image_size & a, const clip_image_size & b) {
	return a.width * a.height < b.width * b.height;
	});
	return ratios;
	}

	static clip_image_size get_grid_layout(int height, int width) {
	const float aspect_ratio = static_cast<float>(width) / height;
	const auto ratios = get_target_ratios();
	return find_closest_aspect_ratio(aspect_ratio, ratios, width, height);
	}
	};

	// returns the normalized float tensor for llava-1.5, for spatial_unpad with anyres processing for llava-1.6 it returns the normalized image patch tensors as a vector
	// res_imgs memory is being allocated here, previous allocations will be freed if found
	bool clip_image_preprocess(struct clip_ctx * ctx, const clip_image_u8 * img, struct clip_image_f32_batch * res_imgs) {
	clip_image_size original_size{img->nx, img->ny};
	auto & params = ctx->model.hparams;

	switch (ctx->proj_type()) {
	case PROJECTOR_TYPE_MINICPMV:
	{
	auto const inst = llava_uhd::get_slice_instructions(ctx, original_size);
	std::vector<clip_image_u8_ptr> imgs = llava_uhd::slice_image(img, inst);

	for (size_t i = 0; i < imgs.size(); ++i) {
	// clip_image_save_to_bmp(*imgs[i], "slice_" + std::to_string(i) + ".bmp");
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(imgs[i], res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	}

	res_imgs->grid_x = inst.grid_size.width;
	res_imgs->grid_y = inst.grid_size.height;
	} break;

	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_QWEN3VL:
	case PROJECTOR_TYPE_GLM4V:
	case PROJECTOR_TYPE_PADDLEOCR:
	{
	GGML_ASSERT(params.image_min_pixels > 0 && params.image_max_pixels > 0);
	clip_image_u8 resized;
	const clip_image_size new_size = img_tool::calc_size_preserved_ratio(
	original_size,
	params.patch_size * 2,
	params.image_min_pixels,
	params.image_max_pixels);
	img_tool::resize(*img, resized, new_size, img_tool::RESIZE_ALGO_BILINEAR, false);
	// clip_image_save_to_bmp(resized, "preproc.bmp");
	clip_image_f32_ptr img_f32(clip_image_f32_init());
	// clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(resized, *img_f32, params.image_mean, params.image_std);
	// res_imgs->data[0] = *res;
	res_imgs->entries.push_back(std::move(img_f32));
	} break;
	case PROJECTOR_TYPE_YOUTUVL:
	{
	const int patch_size = params.patch_size; // typically 16
	const int merge_size = params.n_merge; // typically 2
	const int align_size = patch_size * merge_size; // 32

	const int max_num_patches = params.image_max_pixels > 0 ?
	params.image_max_pixels / (patch_size * patch_size) : 256;

	// Linear search for optimal scale to fit within max_num_patches
	float scale = 1.0f;
	int target_height = original_size.height;
	int target_width = original_size.width;

	auto get_scaled_image_size = [align_size](float scale, int size) -> int {
	float scaled_size = size * scale;
	// Round up to nearest multiple of align_size
	int aligned = static_cast<int>(std::ceil(scaled_size / align_size)) * align_size;
	// Ensure at least one patch
	return std::max(align_size, aligned);
	};

	// Linear search with 0.02 step size
	while (scale > 0.0f) {
	target_height = get_scaled_image_size(scale, original_size.height);
	target_width = get_scaled_image_size(scale, original_size.width);

	int num_patches_h = target_height / patch_size;
	int num_patches_w = target_width / patch_size;
	int num_patches = num_patches_h * num_patches_w;

	if (num_patches > max_num_patches) {
	scale -= 0.02f;
	} else {
	break;
	}
	}

	clip_image_size new_size = {target_width, target_height};

	// Resize the image
	clip_image_u8 resized;
	img_tool::resize(*img, resized, new_size, img_tool::RESIZE_ALGO_BILINEAR, false);

	// Normalize to float32
	clip_image_f32_ptr img_f32(clip_image_f32_init());
	normalize_image_u8_to_f32(resized, *img_f32, params.image_mean, params.image_std);

	// Add to results
	res_imgs->entries.push_back(std::move(img_f32));
	} break;

	case PROJECTOR_TYPE_IDEFICS3:
	{
	// The refined size has two steps:
	// 1. Resize w/ aspect-ratio preserving such that the longer side is
	// the preprocessor longest size
	// 2. Resize w/out preserving aspect ratio such that both sides are
	// multiples of image_size (always rounding up)
	//
	// CITE: https://github.com/huggingface/transformers/blob/main/src/transformers/models/idefics3/image_processing_idefics3.py#L737
	const clip_image_size refined_size = img_tool::calc_size_preserved_ratio(
	original_size, params.image_size, params.image_longest_edge);
	// LOG_INF("%s: original size: %d x %d, refined size: %d x %d\n",
	// __func__, original_size.width, original_size.height,
	// refined_size.width, refined_size.height);

	llava_uhd::slice_instructions instructions;
	instructions.overview_size = clip_image_size{params.image_size, params.image_size};
	instructions.refined_size = refined_size;
	instructions.grid_size = clip_image_size{
	static_cast<int>(std::ceil(static_cast<float>(refined_size.width) / params.image_size)),
	static_cast<int>(std::ceil(static_cast<float>(refined_size.height) / params.image_size)),
	};
	for (int y = 0; y < refined_size.height; y += params.image_size) {
	for (int x = 0; x < refined_size.width; x += params.image_size) {
	// LOG_INF("%s: adding slice at x=%d, y=%d\n", __func__, x, y);
	instructions.slices.push_back(llava_uhd::slice_coordinates{
	/* x */x,
	/* y */y,
	/* size */clip_image_size{
	std::min(params.image_size, refined_size.width - x),
	std::min(params.image_size, refined_size.height - y)
	}
	});
	}
	}
	auto imgs = llava_uhd::slice_image(img, instructions);

	// cast and normalize to f32
	for (size_t i = 0; i < imgs.size(); ++i) {
	// clip_image_save_to_bmp(*imgs[i], "slice_" + std::to_string(i) + ".bmp");
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(imgs[i], res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	}

	res_imgs->grid_x = instructions.grid_size.width;
	res_imgs->grid_y = instructions.grid_size.height;
	} break;

	case PROJECTOR_TYPE_GLM_EDGE:
	case PROJECTOR_TYPE_GEMMA3:
	case PROJECTOR_TYPE_INTERNVL: // TODO @ngxson : support dynamic resolution
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	{
	clip_image_u8 resized_image;
	int sz = params.image_size;
	img_tool::resize(*img, resized_image, {sz, sz}, img_tool::RESIZE_ALGO_BILINEAR);
	clip_image_f32_ptr img_f32(clip_image_f32_init());
	//clip_image_save_to_bmp(resized_image, "resized.bmp");
	normalize_image_u8_to_f32(resized_image, *img_f32, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(img_f32));
	} break;

	case PROJECTOR_TYPE_GEMMA3NV:
	{
	clip_image_u8 resized_image;
	int sz = params.image_size;
	img_tool::resize(*img, resized_image, {sz, sz}, img_tool::RESIZE_ALGO_BILINEAR, false);
	clip_image_f32_ptr img_f32(clip_image_f32_init());
	normalize_image_u8_to_f32(resized_image, *img_f32, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(img_f32));
	} break;

	case PROJECTOR_TYPE_JANUS_PRO:
	{
	// Janus Pro preprocessing: pad to square with gray(127), resize to 384x384
	const std::array<uint8_t, 3> pad_color = {127, 127, 127};
	clip_image_u8 resized_image;
	int sz = params.image_size;
	img_tool::resize(*img, resized_image, {sz, sz}, img_tool::RESIZE_ALGO_BILINEAR, true, pad_color);
	clip_image_f32_ptr img_f32(clip_image_f32_init());
	normalize_image_u8_to_f32(resized_image, *img_f32, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(img_f32));
	} break;

	case PROJECTOR_TYPE_PIXTRAL:
	case PROJECTOR_TYPE_LIGHTONOCR:
	{
	GGML_ASSERT(params.image_min_pixels > 0 && params.image_max_pixels > 0);
	clip_image_u8 resized_image;
	// the original pixtral model doesn't have n_merge
	const int cur_merge = params.n_merge == 0 ? 1 : params.n_merge;
	const clip_image_size target_size = img_tool::calc_size_preserved_ratio(
	original_size,
	params.patch_size * cur_merge,
	params.image_min_pixels,
	params.image_max_pixels);
	img_tool::resize(*img, resized_image, target_size, img_tool::RESIZE_ALGO_BILINEAR);
	clip_image_f32_ptr img_f32(clip_image_f32_init());
	normalize_image_u8_to_f32(resized_image, *img_f32, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(img_f32));
	} break;

	case PROJECTOR_TYPE_LLAMA4:
	{
	GGML_ASSERT(!params.image_res_candidates.empty());
	auto const inst = llava_uhd::get_slice_instructions(ctx, original_size);
	std::vector<clip_image_u8_ptr> imgs = llava_uhd::slice_image(img, inst);

	for (size_t i = 0; i < imgs.size(); ++i) {
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(imgs[i], res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	}

	res_imgs->grid_x = inst.grid_size.width;
	res_imgs->grid_y = inst.grid_size.height;
	} break;

	case PROJECTOR_TYPE_LFM2:
	{
	auto const inst = lfm2_vl_image_processor::get_slice_instructions(ctx, original_size);
	std::vector<clip_image_u8_ptr> imgs = llava_uhd::slice_image(img, inst);

	for (size_t i = 0; i < imgs.size(); ++i) {
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(imgs[i], res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	}

	res_imgs->grid_x = inst.grid_size.width;
	res_imgs->grid_y = inst.grid_size.height;
	} break;

	case PROJECTOR_TYPE_KIMIVL:
	{
	GGML_ASSERT(params.image_min_pixels > 0 && params.image_max_pixels > 0);
	const clip_image_size target_size = img_tool::calc_size_preserved_ratio(
	original_size,
	params.patch_size * params.n_merge,
	params.image_min_pixels,
	params.image_max_pixels);
	const std::array<uint8_t, 3> pad_color = {122, 116, 104};

	clip_image_u8 resized_img;
	img_tool::resize(*img, resized_img, target_size, img_tool::RESIZE_ALGO_BILINEAR, true, pad_color);
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(resized_img, *res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	} break;

	case PROJECTOR_TYPE_KIMIK25:
	{
	GGML_ASSERT(params.image_min_pixels > 0 && params.image_max_pixels > 0);
	const clip_image_size target_size = img_tool::calc_size_preserved_ratio(
	original_size,
	params.patch_size * params.n_merge,
	params.image_min_pixels,
	params.image_max_pixels);
	const std::array<uint8_t, 3> pad_color = {0, 0, 0};

	clip_image_u8 resized_img;
	img_tool::resize(*img, resized_img, target_size, img_tool::RESIZE_ALGO_BICUBIC, true, pad_color);
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(resized_img, *res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	} break;

	case PROJECTOR_TYPE_MLP:
	case PROJECTOR_TYPE_MLP_NORM:
	case PROJECTOR_TYPE_LDP:
	case PROJECTOR_TYPE_LDPV2:
	case PROJECTOR_TYPE_COGVLM: // TODO @ngxson : is this correct for cogvlm?
	{
	// TODO @ngxson : refactor the code below to avoid duplicated logic

	// the logic below is to pad the shorter side to the longer side with a background color: rgb(122, 116, 104)
	// see https://github.com/haotian-liu/LLaVA/blob/e854a2bf85118c504f6f16bf5c3c7c92f8fa8c6b/llava/conversation.py#L113-L156

	clip_image_u8_ptr temp(clip_image_u8_init()); // we will keep the input image data here temporarily

	// The model config actually contains all we need to decide on how to preprocess, here we automatically switch to the new llava-1.6 preprocessing
	if (params.image_res_candidates.empty()) { // pad_to_square
	// for llava-1.5, we resize image to a square, and pad the shorter side with a background color
	// see https://github.com/haotian-liu/LLaVA/blob/e854a2bf85118c504f6f16bf5c3c7c92f8fa8c6b/llava/conversation.py#L113-L156
	const int longer_side = std::max(img->nx, img->ny);
	temp->nx = longer_side;
	temp->ny = longer_side;
	temp->buf.resize(3 * longer_side * longer_side);

	// background color in RGB from LLaVA (this is the mean rgb color * 255)
	const std::array<uint8_t, 3> pad_color = {122, 116, 104};

	// resize the image to the target_size
	img_tool::resize(img, temp, clip_image_size{params.image_size, params.image_size}, img_tool::RESIZE_ALGO_BILINEAR, true, pad_color);

	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(temp, res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));

	} else {
	// "spatial_unpad" with "anyres" processing for llava-1.6
	auto const inst = llava_uhd::get_slice_instructions(ctx, original_size);
	std::vector<clip_image_u8_ptr> imgs = llava_uhd::slice_image(img, inst);

	for (size_t i = 0; i < imgs.size(); ++i) {
	// clip_image_save_to_bmp(*imgs[i], "slice_" + std::to_string(i) + ".bmp");
	clip_image_f32_ptr res(clip_image_f32_init());
	normalize_image_u8_to_f32(imgs[i], res, params.image_mean, params.image_std);
	res_imgs->entries.push_back(std::move(res));
	}
	}
	} break;

	default:
	LOG_ERR("%s: unsupported projector type %d\n", __func__, ctx->proj_type());
	return false;
	}

	return true;
	}

	ggml_tensor * clip_get_newline_tensor(const struct clip_ctx * ctx) {
	return ctx->model.image_newline;
	}

	void clip_free(clip_ctx * ctx) {
	if (ctx == nullptr) {
	return;
	}
	delete ctx;
	}

	// deprecated
	size_t clip_embd_nbytes(const struct clip_ctx * ctx) {
	const int32_t nx = ctx->model.hparams.image_size;
	const int32_t ny = ctx->model.hparams.image_size;
	return clip_embd_nbytes_by_img(ctx, nx, ny);
	}

	size_t clip_embd_nbytes_by_img(const struct clip_ctx * ctx, int img_w, int img_h) {
	clip_image_f32 img;
	img.nx = img_w;
	img.ny = img_h;
	return clip_n_output_tokens(ctx, &img) * clip_n_mmproj_embd(ctx) * sizeof(float);
	}

	int32_t clip_get_image_size(const struct clip_ctx * ctx) {
	return ctx->model.hparams.image_size;
	}

	int32_t clip_get_patch_size(const struct clip_ctx * ctx) {
	return ctx->model.hparams.patch_size;
	}

	int32_t clip_get_hidden_size(const struct clip_ctx * ctx) {
	return ctx->model.hparams.n_embd;
	}

	const char * clip_patch_merge_type(const struct clip_ctx * ctx) {
	return ctx->model.hparams.mm_patch_merge_type == PATCH_MERGE_SPATIAL_UNPAD ? "spatial_unpad" : "flat";
	}

	int clip_n_output_tokens_x(const struct clip_ctx * ctx, struct clip_image_f32 * img) {
	const auto & params = ctx->model.hparams;
	const int n_total = clip_n_output_tokens(ctx, img);
	const auto & proj = ctx->proj_type();
	switch (proj) {
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_QWEN3VL:
	case PROJECTOR_TYPE_GLM4V:
	case PROJECTOR_TYPE_PADDLEOCR:
	case PROJECTOR_TYPE_YOUTUVL:
	return (img->nx / params.patch_size) / 2;
	default:
	break;
	}
	return n_total;
	}

	int clip_n_output_tokens_y(const struct clip_ctx * ctx, struct clip_image_f32 * img) {
	const auto & params = ctx->model.hparams;
	const auto & proj = ctx->proj_type();
	switch (proj) {
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_QWEN3VL:
	case PROJECTOR_TYPE_GLM4V:
	case PROJECTOR_TYPE_PADDLEOCR:
	case PROJECTOR_TYPE_YOUTUVL:
	return (img->ny / params.patch_size) / 2;
	default:
	break;
	}
	return 1;
	}

	int clip_n_output_tokens(const struct clip_ctx * ctx, struct clip_image_f32 * img) {
	const auto & params = ctx->model.hparams;

	// for models with fixed size image, the input image is already pre-processed and resized to square
	int patch_size = params.patch_size;
	int n_patches = (img->nx / patch_size) * (img->ny / patch_size);

	projector_type proj = ctx->proj_type();

	switch (proj) {
	case PROJECTOR_TYPE_MLP:
	case PROJECTOR_TYPE_MLP_NORM:
	case PROJECTOR_TYPE_JANUS_PRO:
	{
	// do nothing
	} break;
	case PROJECTOR_TYPE_LDP:
	case PROJECTOR_TYPE_LDPV2:
	case PROJECTOR_TYPE_GLM_EDGE:
	{
	n_patches /= 4;
	if (ctx->model.mm_boi) {
	n_patches += 2; // for BOI and EOI token embeddings
	}
	} break;
	case PROJECTOR_TYPE_MINICPMV:
	{
	// Use actual config value if available, otherwise fall back to hardcoded values
	if (params.minicpmv_query_num > 0) {
	n_patches = params.minicpmv_query_num;
	} else {
	// Fallback to hardcoded values for legacy models
	if (params.minicpmv_version == 2) {
	n_patches = 96;
	} else if (params.minicpmv_version == 3) {
	n_patches = 64;
	} else if (params.minicpmv_version == 4) {
	n_patches = 64;
	} else if (params.minicpmv_version == 5) {
	// MiniCPM-V 4.0
	n_patches = 64;
	} else if (params.minicpmv_version == 6) {
	// MiniCPM-V 4.5
	n_patches = 64;
	} else if (params.minicpmv_version == 100045) {
	// MiniCPM-o 4.5
	n_patches = 64;
	} else {
	GGML_ABORT("Unknown minicpmv version");
	}
	}
	} break;
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_QWEN3VL:
	case PROJECTOR_TYPE_GLM4V:
	case PROJECTOR_TYPE_YOUTUVL:
	{
	// dynamic size (2 conv, so double patch size)
	int x_patch = img->nx / (params.patch_size * 2);
	int y_patch = img->ny / (params.patch_size * 2);
	n_patches = x_patch * y_patch;
	} break;
	case PROJECTOR_TYPE_GEMMA3:
	case PROJECTOR_TYPE_IDEFICS3:
	case PROJECTOR_TYPE_INTERNVL:
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	case PROJECTOR_TYPE_LLAMA4:
	{
	// both X and Y are downscaled by the scale factor
	int scale_factor = ctx->model.hparams.n_merge;
	n_patches /= (scale_factor * scale_factor);
	} break;
	case PROJECTOR_TYPE_GEMMA3NV:
	{
	// MobileNetV5 MSFA adapter always outputs fixed 16x16 resolution
	// regardless of input size (see architecture description)
	n_patches = ctx->model.hparams.image_size / ctx->model.hparams.patch_size;
	} break;
	case PROJECTOR_TYPE_LFM2:
	case PROJECTOR_TYPE_KIMIVL:
	case PROJECTOR_TYPE_KIMIK25:
	{
	// dynamic size
	int out_patch_size = params.patch_size * ctx->model.hparams.n_merge;
	int x_patch = CLIP_ALIGN(img->nx, out_patch_size) / out_patch_size;
	int y_patch = CLIP_ALIGN(img->ny, out_patch_size) / out_patch_size;
	n_patches = x_patch * y_patch;
	} break;
	case PROJECTOR_TYPE_PADDLEOCR:
	{
	// dynamic size
	int n_merge = ctx->model.hparams.n_merge;
	int stride = n_merge * n_merge;
	n_patches = CLIP_ALIGN(n_patches, stride) / stride;
	} break;
	case PROJECTOR_TYPE_PIXTRAL:
	case PROJECTOR_TYPE_LIGHTONOCR:
	{
	// dynamic size
	int n_merge = ctx->model.hparams.n_merge;
	int n_patches_x = img->nx / patch_size / (n_merge > 0 ? n_merge : 1);
	int n_patches_y = img->ny / patch_size / (n_merge > 0 ? n_merge : 1);
	if (ctx->model.token_embd_img_break) {
	n_patches = n_patches_y * n_patches_x + n_patches_y - 1; // + one [IMG_BREAK] per row, except the last row
	} else {
	n_patches = n_patches_y * n_patches_x;
	}
	} break;
	case PROJECTOR_TYPE_VOXTRAL:
	case PROJECTOR_TYPE_ULTRAVOX:
	case PROJECTOR_TYPE_QWEN2A:
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	{
	n_patches = img->nx;

	const int proj_stack_factor = ctx->model.hparams.proj_stack_factor;
	if (ctx->model.audio_has_stack_frames()) {
	GGML_ASSERT(proj_stack_factor > 0);
	const int n_len = CLIP_ALIGN(n_patches, proj_stack_factor);
	n_patches = n_len / proj_stack_factor;
	}

	// whisper downscales input token by half after conv1d
	n_patches /= 2;

	if (ctx->model.audio_has_avgpool()) {
	// divide by 2 because of nn.AvgPool1d(2, stride=2)
	n_patches /= 2;
	}
	} break;
	case PROJECTOR_TYPE_GLMA:
	{
	n_patches = img->nx;
	// whisper downscales input token by half after conv1d
	n_patches /= 2;
	// reshape by merge_factor
	n_patches /= ctx->model.hparams.proj_stack_factor;
	// for BOI and EOI token embeddings
	n_patches += 2;
	} break;
	case PROJECTOR_TYPE_COGVLM:
	{
	n_patches += 2; // for BOI and EOI token embeddings
	} break;
	case PROJECTOR_TYPE_LFM2A:
	{
	n_patches = ((((img->nx + 1) / 2) + 1) / 2 + 1) / 2;
	} break;
	default:
	GGML_ABORT("unsupported projector type");
	}

	return n_patches;
	}

	bool clip_image_encode(struct clip_ctx * ctx, const int n_threads, clip_image_f32 * img, float * vec) {
	clip_image_f32_batch imgs;
	clip_image_f32_ptr img_copy(clip_image_f32_init());
	img_copy = img;
	imgs.entries.push_back(std::move(img_copy));

	return clip_image_batch_encode(ctx, n_threads, &imgs, vec);
	}

	bool clip_image_batch_encode(clip_ctx * ctx, const int n_threads, const clip_image_f32_batch * imgs_c_ptr, float * vec) {
	const clip_image_f32_batch & imgs = *imgs_c_ptr;
	int batch_size = imgs.entries.size();

	// TODO @ngxson : implement batch size > 1 as a loop
	// we don't need true batching support because the cgraph will gonna be big anyway
	if (batch_size != 1) {
	return false; // only support batch size of 1
	}

	// if buffers are not allocated, we need to do a warmup run to allocate them
	if (!ctx->is_allocated) {
	clip_model_loader::warmup(ctx, imgs_c_ptr);
	}

	// build the inference graph
	ggml_backend_sched_reset(ctx->sched.get());
	ggml_cgraph * gf = clip_image_build_graph(ctx, imgs);
	ggml_backend_sched_alloc_graph(ctx->sched.get(), gf);

	// set inputs
	const auto & model = ctx->model;
	const auto & hparams = model.hparams;

	const int image_size_width = imgs.entries[0]->nx;
	const int image_size_height = imgs.entries[0]->ny;

	const int patch_size = hparams.patch_size;
	const int num_patches = ((image_size_width / patch_size) * (image_size_height / patch_size));
	const int n_pos = num_patches + (model.class_embedding ? 1 : 0);
	const int pos_w = image_size_width / patch_size;
	const int pos_h = image_size_height / patch_size;


	auto get_inp_tensor = [&gf](const char * name) {
	ggml_tensor * inp = ggml_graph_get_tensor(gf, name);
	if (inp == nullptr) {
	GGML_ABORT("Failed to get tensor %s", name);
	}
	if (!(inp->flags & GGML_TENSOR_FLAG_INPUT)) {
	GGML_ABORT("Tensor %s is not an input tensor", name);
	}
	return inp;
	};

	auto set_input_f32 = [&get_inp_tensor](const char * name, std::vector<float> & values) {
	ggml_tensor * cur = get_inp_tensor(name);
	GGML_ASSERT(cur->type == GGML_TYPE_F32);
	GGML_ASSERT(ggml_nelements(cur) == (int64_t)values.size());
	ggml_backend_tensor_set(cur, values.data(), 0, ggml_nbytes(cur));
	};

	auto set_input_i32 = [&get_inp_tensor](const char * name, std::vector<int32_t> & values) {
	ggml_tensor * cur = get_inp_tensor(name);
	GGML_ASSERT(cur->type == GGML_TYPE_I32);
	GGML_ASSERT(ggml_nelements(cur) == (int64_t)values.size());
	ggml_backend_tensor_set(cur, values.data(), 0, ggml_nbytes(cur));
	};

	// set input pixel values
	if (!imgs.is_audio) {
	size_t nelem = 0;
	for (const auto & img : imgs.entries) {
	nelem += img->nx * img->ny * 3;
	}
	std::vector<float> inp_raw(nelem);

	// layout of data (note: the channel dim is unrolled to better visualize the layout):
	//
	// ┌──W──┐
	// │ H │ channel = R
	// ├─────┤ │
	// │ H │ channel = G
	// ├─────┤ │
	// │ H │ channel = B
	// └─────┘ │
	// ──────┘ x B

	for (size_t i = 0; i < imgs.entries.size(); i++) {
	const int nx = imgs.entries[i]->nx;
	const int ny = imgs.entries[i]->ny;
	const int n = nx * ny;

	for (int b = 0; b < batch_size; b++) {
	float * batch_entry = inp_raw.data() + b * (3*n);
	for (int y = 0; y < ny; y++) {
	for (int x = 0; x < nx; x++) {
	size_t base_src = 3(y nx + x); // idx of the first channel
	size_t base_dst = y * nx + x; // idx of the first channel
	batch_entry[ base_dst] = imgs.entries[b]->buf[base_src ];
	batch_entry[1*n + base_dst] = imgs.entries[b]->buf[base_src + 1];
	batch_entry[2*n + base_dst] = imgs.entries[b]->buf[base_src + 2];
	}
	}
	}
	}
	set_input_f32("inp_raw", inp_raw);

	} else {
	// audio input
	GGML_ASSERT(imgs.entries.size() == 1);
	const auto & mel_inp = imgs.entries[0];
	const int n_step = mel_inp->nx;
	const int n_mel = mel_inp->ny;
	std::vector<float> inp_raw(n_step * n_mel);
	std::memcpy(inp_raw.data(), mel_inp->buf.data(), n_step * n_mel * sizeof(float));
	set_input_f32("inp_raw", inp_raw);
	}

	// set input per projector
	switch (ctx->model.proj_type) {
	case PROJECTOR_TYPE_MINICPMV:
	{
	// inspired from siglip:
	// -> https://huggingface.co/HuggingFaceM4/siglip-so400m-14-980-flash-attn2-navit
	// -> https://huggingface.co/HuggingFaceM4/siglip-so400m-14-980-flash-attn2-navit/blob/d66538faeba44480d0bfaa42145eef26f9423199/modeling_siglip.py#L316
	std::vector<int32_t> positions(pos_h * pos_w);
	int bucket_coords_h[1024];
	int bucket_coords_w[1024];
	for (int i = 0; i < pos_h; i++){
	bucket_coords_h[i] = std::floor(70.0*i/pos_h);
	}
	for (int i = 0; i < pos_w; i++){
	bucket_coords_w[i] = std::floor(70.0*i/pos_w);
	}
	for (int i = 0, id = 0; i < pos_h; i++){
	for (int j = 0; j < pos_w; j++){
	positions[id++] = bucket_coords_h[i]*70 + bucket_coords_w[j];
	}
	}
	set_input_i32("positions", positions);

	// inputs for resampler projector
	// set the 2D positions (using float for sinusoidal embedding)
	int n_patches_per_col = image_size_width / patch_size;
	std::vector<float> pos_data(n_pos);
	// dimension H
	for (int i = 0; i < n_pos; i++) {
	pos_data[i] = static_cast<float>(i / n_patches_per_col);
	}
	set_input_f32("pos_h", pos_data);
	// dimension W
	for (int i = 0; i < n_pos; i++) {
	pos_data[i] = static_cast<float>(i % n_patches_per_col);
	}
	set_input_f32("pos_w", pos_data);
	// base frequency omega
	const float base_freq = 10000.0f;
	const int n_embd_proj = clip_n_mmproj_embd(ctx);
	std::vector<float> omega(n_embd_proj / 4);
	for (int i = 0; i < n_embd_proj / 4; ++i) {
	omega[i] = 1.0f / std::pow(base_freq, static_cast<float>(i) / (n_embd_proj / 4));
	}
	set_input_f32("omega", omega);
	} break;
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN3VL:
	case PROJECTOR_TYPE_GLM4V:
	{
	const int merge_ratio = hparams.n_merge;
	const int pw = image_size_width / patch_size;
	const int ph = image_size_height / patch_size;
	std::vector<int> positions(n_pos * 4);
	int ptr = 0;
	for (int y = 0; y < ph; y += merge_ratio) {
	for (int x = 0; x < pw; x += merge_ratio) {
	for (int dy = 0; dy < 2; dy++) {
	for (int dx = 0; dx < 2; dx++) {
	positions[ ptr] = y + dy;
	positions[ num_patches + ptr] = x + dx;
	positions[2 * num_patches + ptr] = y + dy;
	positions[3 * num_patches + ptr] = x + dx;
	ptr++;
	}
	}
	}
	}

	set_input_i32("positions", positions);
	} break;
	case PROJECTOR_TYPE_PADDLEOCR:
	{
	const int merge_ratio = hparams.n_merge;
	const int pw = image_size_width / patch_size;
	const int ph = image_size_height / patch_size;
	std::vector<int> positions(n_pos * 4);
	int ptr = 0;
	// NOTE: same as Qwen-VL, but x and y are swapped
	for (int y = 0; y < ph; y += merge_ratio) {
	for (int dy = 0; dy < 2; dy++) {
	for (int x = 0; x < pw; x += merge_ratio) {
	for (int dx = 0; dx < 2; dx++) {
	positions[ ptr] = y + dy;
	positions[ num_patches + ptr] = x + dx;
	positions[2 * num_patches + ptr] = y + dy;
	positions[3 * num_patches + ptr] = x + dx;
	ptr++;
	}
	}
	}
	}

	set_input_i32("positions", positions);
	} break;
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_YOUTUVL:
	{
	// pw * ph = number of tokens output by ViT after apply patch merger
	// ipw * ipw = number of vision token been processed inside ViT
	const bool use_window_attn = ctx->model.proj_type == PROJECTOR_TYPE_QWEN25VL ? hparams.n_wa_pattern > 0 : !hparams.wa_layer_indexes.empty();
	const int merge_ratio = 2;
	const int pw = image_size_width / patch_size / merge_ratio;
	const int ph = image_size_height / patch_size / merge_ratio;
	const int ipw = image_size_width / patch_size;
	const int iph = image_size_height / patch_size;

	std::vector<int> idx (ph * pw);
	std::vector<int> inv_idx(ph * pw);

	if (use_window_attn) {
	const int attn_window_size = hparams.attn_window_size > 0 ? hparams.attn_window_size : 112;
	const int grid_window = attn_window_size / patch_size / merge_ratio;
	int dst = 0;
	// [num_vision_tokens, num_vision_tokens] attention mask tensor
	std::vector<float> mask(pow(ipw * iph, 2), std::numeric_limits<float>::lowest());
	int mask_row = 0;

	for (int y = 0; y < ph; y += grid_window) {
	for (int x = 0; x < pw; x += grid_window) {
	const int win_h = std::min(grid_window, ph - y);
	const int win_w = std::min(grid_window, pw - x);
	const int dst_0 = dst;
	// group all tokens belong to the same window togather (to a continue range)
	for (int dy = 0; dy < win_h; dy++) {
	for (int dx = 0; dx < win_w; dx++) {
	const int src = (y + dy) * pw + (x + dx);
	GGML_ASSERT(src < (int)idx.size());
	GGML_ASSERT(dst < (int)inv_idx.size());
	idx [src] = dst;
	inv_idx[dst] = src;
	dst++;
	}
	}

	for (int r=0; r < win_h * win_w * merge_ratio * merge_ratio; r++) {
	int row_offset = mask_row * (ipw * iph);
	std::fill(
	mask.begin() + row_offset + (dst_0 * merge_ratio * merge_ratio),
	mask.begin() + row_offset + (dst * merge_ratio * merge_ratio),
	0.0);
	mask_row++;
	}
	}
	}

	set_input_i32("window_idx", idx);
	set_input_i32("inv_window_idx", inv_idx);
	set_input_f32("window_mask", mask);
	} else {
	for (int i = 0; i < ph * pw; i++) {
	idx[i] = i;
	}
	}

	const int mpow = merge_ratio * merge_ratio;
	std::vector<int> positions(n_pos * 4);

	int ptr = 0;
	for (int y = 0; y < iph; y += merge_ratio) {
	for (int x = 0; x < ipw; x += merge_ratio) {
	for (int dy = 0; dy < 2; dy++) {
	for (int dx = 0; dx < 2; dx++) {
	auto remap = idx[ptr / mpow];
	remap = (remap * mpow) + (ptr % mpow);

	positions[ remap] = y + dy;
	positions[ num_patches + remap] = x + dx;
	positions[2 * num_patches + remap] = y + dy;
	positions[3 * num_patches + remap] = x + dx;
	ptr++;
	}
	}
	}
	}

	set_input_i32("positions", positions);
	} break;
	case PROJECTOR_TYPE_PIXTRAL:
	case PROJECTOR_TYPE_KIMIVL:
	case PROJECTOR_TYPE_KIMIK25:
	case PROJECTOR_TYPE_LIGHTONOCR:
	{
	// set the 2D positions
	int n_patches_per_col = image_size_width / patch_size;
	std::vector<int> pos_data(n_pos);
	// dimension H
	for (int i = 0; i < n_pos; i++) {
	pos_data[i] = i / n_patches_per_col;
	}
	set_input_i32("pos_h", pos_data);
	// dimension W
	for (int i = 0; i < n_pos; i++) {
	pos_data[i] = i % n_patches_per_col;
	}
	set_input_i32("pos_w", pos_data);
	} break;
	case PROJECTOR_TYPE_GLM_EDGE:
	{
	// llava and other models
	std::vector<int32_t> positions(n_pos);
	for (int i = 0; i < n_pos; i++) {
	positions[i] = i;
	}
	set_input_i32("positions", positions);
	} break;
	case PROJECTOR_TYPE_MLP:
	case PROJECTOR_TYPE_MLP_NORM:
	case PROJECTOR_TYPE_LDP:
	case PROJECTOR_TYPE_LDPV2:
	{
	// llava and other models
	std::vector<int32_t> positions(n_pos);
	for (int i = 0; i < n_pos; i++) {
	positions[i] = i;
	}
	set_input_i32("positions", positions);

	// The patches vector is used to get rows to index into the embeds with;
	// we should skip dim 0 only if we have CLS to avoid going out of bounds
	// when retrieving the rows.
	int patch_offset = model.class_embedding ? 1 : 0;
	std::vector<int32_t> patches(num_patches);
	for (int i = 0; i < num_patches; i++) {
	patches[i] = i + patch_offset;
	}
	set_input_i32("patches", patches);
	} break;
	case PROJECTOR_TYPE_GEMMA3:
	case PROJECTOR_TYPE_GEMMA3NV:
	case PROJECTOR_TYPE_IDEFICS3:
	case PROJECTOR_TYPE_INTERNVL:
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	case PROJECTOR_TYPE_QWEN2A:
	case PROJECTOR_TYPE_GLMA:
	case PROJECTOR_TYPE_ULTRAVOX:
	case PROJECTOR_TYPE_LFM2:
	case PROJECTOR_TYPE_VOXTRAL:
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	case PROJECTOR_TYPE_JANUS_PRO:
	case PROJECTOR_TYPE_COGVLM:
	{
	// do nothing
	} break;
	case PROJECTOR_TYPE_LLAMA4:
	{
	// set the 2D positions
	int n_patches_per_col = image_size_width / patch_size;
	std::vector<int> pos_data(num_patches + 1, 0); // +1 for the [CLS] token
	// last pos is always kept 0, it's for CLS
	// dimension H
	for (int i = 0; i < num_patches; i++) {
	pos_data[i] = (i / n_patches_per_col) + 1;
	}
	set_input_i32("pos_h", pos_data);
	// dimension W
	for (int i = 0; i < num_patches; i++) {
	pos_data[i] = (i % n_patches_per_col) + 1;
	}
	set_input_i32("pos_w", pos_data);
	} break;
	case PROJECTOR_TYPE_LFM2A:
	{
	GGML_ASSERT(imgs.entries.size() == 1);
	const auto n_frames = clip_n_output_tokens(ctx, imgs.entries.front().get());

	auto d_model = 512;
	auto seq_len = n_frames * 2 - 1;
	std::vector<float> pos_emb(d_model*seq_len);
	std::vector<double> inv_freq(d_model / 2);
	for (size_t i = 0; i < inv_freq.size(); ++i) {
	inv_freq[i] = std::exp(-(std::log(10000.0) / (float)d_model) * (2.0f * (float)(i)));
	}
	for (int64_t pos = 0; pos < seq_len; ++pos) {
	for (size_t i = 0; i < inv_freq.size(); ++i) {
	const float ang = (n_frames - pos - 1) * inv_freq[i];
	pos_emb[posd_model + 2i + 0] = sinf(ang); // even
	pos_emb[posd_model + 2i + 1] = cosf(ang); // odd
	}
	}
	set_input_f32("pos_emb", pos_emb);
	} break;
	default:
	GGML_ABORT("Unknown projector type");
	}

	// ggml_backend_cpu_set_n_threads(ctx->backend_cpu, n_threads);
	ggml_backend_dev_t dev = ggml_backend_get_device(ctx->backend_cpu);
	ggml_backend_reg_t reg = dev ? ggml_backend_dev_backend_reg(dev) : nullptr;
	if (reg) {
	auto ggml_backend_set_n_threads_fn = (ggml_backend_set_n_threads_t) ggml_backend_reg_get_proc_address(reg, "ggml_backend_set_n_threads");
	if (ggml_backend_set_n_threads_fn) {
	ggml_backend_set_n_threads_fn(ctx->backend_cpu, n_threads);
	}
	}

	auto status = ggml_backend_sched_graph_compute(ctx->sched.get(), gf);
	if (status != GGML_STATUS_SUCCESS) {
	LOG_ERR("%s: ggml_backend_sched_graph_compute failed with error %d\n", __func__, status);
	return false;
	}

	// the last node is the embedding tensor
	ggml_tensor * embeddings = ggml_graph_node(gf, -1);

	// sanity check (only support batch size of 1 for now)
	const int n_tokens_out = embeddings->ne[1];
	const int expected_n_tokens_out = clip_n_output_tokens(ctx, imgs.entries[0].get());
	if (n_tokens_out != expected_n_tokens_out) {
	LOG_ERR("%s: expected output %d tokens, got %d\n", __func__, expected_n_tokens_out, n_tokens_out);
	GGML_ABORT("Invalid number of output tokens");
	}

	// copy the embeddings to the location passed by the user
	if (vec != nullptr) {
	ggml_backend_tensor_get(embeddings, vec, 0, ggml_nbytes(embeddings));
	}

	// Debug: dump final embeddings if MTMD_DEBUG_EMBEDDINGS is set
	if (std::getenv("MTMD_DEBUG_EMBEDDINGS") != nullptr) {
	const int64_t n_embd = embeddings->ne[0];
	const int64_t n_tokens = embeddings->ne[1];
	std::vector<float> emb_data(n_embd * n_tokens);
	ggml_backend_tensor_get(embeddings, emb_data.data(), 0, ggml_nbytes(embeddings));

	LOG_INF("\n=== MTMD_DEBUG_EMBEDDINGS ===\n");
	LOG_INF("Shape: [%lld, %lld]\n", (long long)n_embd, (long long)n_tokens);

	// Print first few values of first token
	LOG_INF("Token 0 (first 16 values): ");
	for (int i = 0; i < std::min((int64_t)16, n_embd); i++) {
	LOG_INF("%.6f ", emb_data[i]);
	}
	LOG_INF("\n");

	// Print last few values of first token
	if (n_embd > 16) {
	LOG_INF("Token 0 (last 16 values): ");
	for (int64_t i = n_embd - 16; i < n_embd; i++) {
	LOG_INF("%.6f ", emb_data[i]);
	}
	LOG_INF("\n");
	}

	// Compute and print statistics
	float sum = 0.0f, sum_sq = 0.0f, min_val = emb_data[0], max_val = emb_data[0];
	for (size_t i = 0; i < emb_data.size(); i++) {
	sum += emb_data[i];
	sum_sq += emb_data[i] * emb_data[i];
	min_val = std::min(min_val, emb_data[i]);
	max_val = std::max(max_val, emb_data[i]);
	}
	float mean = sum / emb_data.size();
	float variance = (sum_sq / emb_data.size()) - (mean * mean);
	LOG_INF("Stats: mean=%.6f, std=%.6f, min=%.6f, max=%.6f, sum=%.6f\n",
	mean, sqrtf(variance), min_val, max_val, sum);
	LOG_INF("=== END MTMD_DEBUG_EMBEDDINGS ===\n\n");
	}

	return true;
	}

	int clip_n_mmproj_embd(const struct clip_ctx * ctx) {
	switch (ctx->model.proj_type) {
	case PROJECTOR_TYPE_LDP:
	return ctx->model.mm_model_block_1_block_2_1_b->ne[0];
	case PROJECTOR_TYPE_LDPV2:
	return ctx->model.mm_model_peg_0_b->ne[0];
	case PROJECTOR_TYPE_MLP:
	case PROJECTOR_TYPE_PIXTRAL:
	case PROJECTOR_TYPE_LIGHTONOCR:
	return ctx->model.mm_2_w->ne[1];
	case PROJECTOR_TYPE_MLP_NORM:
	return ctx->model.mm_3_b->ne[0];
	case PROJECTOR_TYPE_MINICPMV:
	return ctx->model.mm_model_proj->ne[0];
	case PROJECTOR_TYPE_GLM_EDGE:
	return ctx->model.mm_model_mlp_3_w->ne[1];
	case PROJECTOR_TYPE_QWEN2VL:
	case PROJECTOR_TYPE_QWEN25VL:
	case PROJECTOR_TYPE_JANUS_PRO:
	case PROJECTOR_TYPE_YOUTUVL:
	return ctx->model.mm_1_b->ne[0];
	case PROJECTOR_TYPE_QWEN3VL:
	// main path + deepstack paths
	return ctx->model.mm_1_b->ne[0] * (1 + ctx->model.n_deepstack_layers);
	case PROJECTOR_TYPE_GEMMA3:
	case PROJECTOR_TYPE_GEMMA3NV:
	return ctx->model.mm_input_proj_w->ne[0];
	case PROJECTOR_TYPE_IDEFICS3:
	return ctx->model.projection->ne[1];
	case PROJECTOR_TYPE_ULTRAVOX:
	case PROJECTOR_TYPE_VOXTRAL:
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	return ctx->model.mm_2_w->ne[1];
	case PROJECTOR_TYPE_INTERNVL:
	case PROJECTOR_TYPE_NEMOTRON_V2_VL:
	return ctx->model.mm_3_w->ne[1];
	case PROJECTOR_TYPE_LLAMA4:
	return ctx->model.mm_model_proj->ne[1];
	case PROJECTOR_TYPE_QWEN2A:
	return ctx->model.mm_fc_w->ne[1];
	case PROJECTOR_TYPE_GLMA:
	return ctx->model.mm_2_w->ne[1];
	case PROJECTOR_TYPE_LFM2:
	case PROJECTOR_TYPE_KIMIVL:
	case PROJECTOR_TYPE_PADDLEOCR:
	case PROJECTOR_TYPE_KIMIK25:
	return ctx->model.mm_2_w->ne[1];
	case PROJECTOR_TYPE_COGVLM:
	return ctx->model.mm_4h_to_h_w->ne[1];
	case PROJECTOR_TYPE_LFM2A:
	return ctx->model.position_embeddings->ne[0];
	case PROJECTOR_TYPE_GLM4V:
	return ctx->model.mm_ffn_down_w->ne[1];
	default:
	GGML_ABORT("Unknown projector type");
	}
	}

	int clip_is_minicpmv(const struct clip_ctx * ctx) {
	// TODO: remove this function
	if (ctx->proj_type() == PROJECTOR_TYPE_MINICPMV) {
	return ctx->model.hparams.minicpmv_version;
	}
	return 0;
	}

	bool clip_is_glm(const struct clip_ctx * ctx) {
	// TODO: remove this function
	return ctx->proj_type() == PROJECTOR_TYPE_GLM_EDGE;
	}

	bool clip_is_llava(const struct clip_ctx * ctx) {
	return ctx->model.hparams.has_llava_projector;
	}

	bool clip_has_vision_encoder(const struct clip_ctx * ctx) {
	return ctx->model.modality == CLIP_MODALITY_VISION;
	}

	bool clip_has_audio_encoder(const struct clip_ctx * ctx) {
	return ctx->model.modality == CLIP_MODALITY_AUDIO;
	}

	bool clip_has_whisper_encoder(const struct clip_ctx * ctx) {
	switch (ctx->proj_type()) {
	case PROJECTOR_TYPE_ULTRAVOX:
	case PROJECTOR_TYPE_QWEN2A:
	case PROJECTOR_TYPE_GLMA:
	case PROJECTOR_TYPE_VOXTRAL:
	case PROJECTOR_TYPE_MUSIC_FLAMINGO:
	return true;
	default:
	return false;
	}
	}

	bool clip_encode_float_image (struct clip_ctx * ctx, int n_threads, float * img, int h, int w, float * vec) {
	clip_image_f32 clip_img;
	clip_img.buf.resize(h * w * 3);
	for (int i = 0; i < hw3; i++)
	{
	clip_img.buf[i] = img[i];
	}
	clip_img.nx = w;
	clip_img.ny = h;
	clip_image_encode(ctx, n_threads, &clip_img, vec);
	return true;
	}

	//
	// API used internally with mtmd
	//

	projector_type clip_get_projector_type(const struct clip_ctx * ctx) {
	return ctx->proj_type();
	}

	void clip_image_f32_batch_add_mel(struct clip_image_f32_batch * batch, int n_mel, int n_frames, float * mel) {
	clip_image_f32 * audio = new clip_image_f32;
	audio->nx = n_frames;
	audio->ny = n_mel;
	audio->buf.resize(n_frames * n_mel);
	std::memcpy(audio->buf.data(), mel, n_frames * n_mel * sizeof(float));

	batch->entries.push_back(clip_image_f32_ptr(audio));
	batch->is_audio = true;
	}

	const clip_hparams * clip_get_hparams(const struct clip_ctx * ctx) {
	return &ctx->model.hparams;
	}

	//
	// API for debugging
	//
	void clip_debug_encode(clip_ctx * ctx, int h, int w, float fill_value) {
	clip_image_f32 img;
	img.nx = w;
	img.ny = h;
	img.buf.resize(h * w * 3);
	for (int i = 0; i < h * w * 3; i++) {
	img.buf[i] = static_cast<float>(fill_value);
	}
	clip_image_encode(ctx, 1, &img, nullptr);
	GGML_ASSERT(img.buf.empty() && "expected, always stop here");
	}