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	#include "ggml/ggml.h"
	#include "ggml/ggml-alloc.h"
	#include "ggml/ggml-backend.h"

	#ifdef GGML_USE_CUBLAS
	#include "ggml-cuda.h"
	#endif

	#ifdef GGML_USE_METAL
	#include "ggml-metal.h"
	#endif

	#include "common.h"
	#include "common-ggml.h"

	#include <cassert>
	#include <cmath>
	#include <cstdio>
	#include <cstring>
	#include <fstream>
	#include <map>
	#include <string>
	#include <vector>

	#if defined(_MSC_VER)
	#pragma warning(disable: 4244 4267) // possible loss of data
	#endif

	static void ggml_log_callback_default(ggml_log_level level, const char * text, void * user_data) {
	(void) level;
	(void) user_data;
	fputs(text, stderr);
	fflush(stderr);
	}

	// default hparams (GPT-2 117M)
	struct gpt2_hparams {
	int32_t n_vocab = 50257;
	int32_t n_ctx = 1024;
	int32_t n_embd = 768;
	int32_t n_head = 12;
	int32_t n_layer = 12;
	int32_t ftype = 1;
	float eps = 1e-5f;
	};

	struct gpt2_layer {
	// normalization
	struct ggml_tensor * ln_1_g;
	struct ggml_tensor * ln_1_b;

	struct ggml_tensor * ln_2_g;
	struct ggml_tensor * ln_2_b;

	// attention
	struct ggml_tensor * c_attn_attn_w;
	struct ggml_tensor * c_attn_attn_b;

	struct ggml_tensor * c_attn_proj_w;
	struct ggml_tensor * c_attn_proj_b;

	// mlp
	struct ggml_tensor * c_mlp_fc_w;
	struct ggml_tensor * c_mlp_fc_b;

	struct ggml_tensor * c_mlp_proj_w;
	struct ggml_tensor * c_mlp_proj_b;
	};

	struct gpt2_model {
	gpt2_hparams hparams;

	// normalization
	struct ggml_tensor * ln_f_g;
	struct ggml_tensor * ln_f_b;

	struct ggml_tensor * wte; // position embedding
	struct ggml_tensor * wpe; // token embedding
	struct ggml_tensor * lm_head; // language model head

	std::vector<gpt2_layer> layers;

	// key + value memory
	struct ggml_tensor * memory_k;
	struct ggml_tensor * memory_v;

	//
	struct ggml_context * ctx;

	ggml_backend_t backend = NULL;

	ggml_backend_buffer_t buffer_w;
	ggml_backend_buffer_t buffer_kv;

	std::map<std::string, struct ggml_tensor *> tensors;
	};

	// load the model's weights from a file
	bool gpt2_model_load(const std::string & fname, gpt2_model & model, gpt_vocab & vocab, int n_ctx, int n_gpu_layers) {
	printf("%s: loading model from '%s'\n", __func__, fname.c_str());

	auto fin = std::ifstream(fname, std::ios::binary);
	if (!fin) {
	fprintf(stderr, "%s: failed to open '%s'\n", __func__, fname.c_str());
	return false;
	}

	// verify magic
	{
	uint32_t magic;
	fin.read((char *) &magic, sizeof(magic));
	if (magic != GGML_FILE_MAGIC) {
	fprintf(stderr, "%s: invalid model file '%s' (bad magic)\n", __func__, fname.c_str());
	return false;
	}
	}

	// load hparams
	{
	auto & hparams = model.hparams;

	fin.read((char *) &hparams.n_vocab, sizeof(hparams.n_vocab));
	fin.read((char *) &hparams.n_ctx, sizeof(hparams.n_ctx));
	fin.read((char *) &hparams.n_embd, sizeof(hparams.n_embd));
	fin.read((char *) &hparams.n_head, sizeof(hparams.n_head));
	fin.read((char *) &hparams.n_layer, sizeof(hparams.n_layer));
	fin.read((char *) &hparams.ftype, sizeof(hparams.ftype));

	const int32_t qntvr = hparams.ftype / GGML_QNT_VERSION_FACTOR;

	printf("%s: n_vocab = %d\n", __func__, hparams.n_vocab);
	printf("%s: n_ctx = %d\n", __func__, hparams.n_ctx);
	printf("%s: n_embd = %d\n", __func__, hparams.n_embd);
	printf("%s: n_head = %d\n", __func__, hparams.n_head);
	printf("%s: n_layer = %d\n", __func__, hparams.n_layer);
	printf("%s: ftype = %d\n", __func__, hparams.ftype);
	printf("%s: qntvr = %d\n", __func__, qntvr);

	hparams.ftype %= GGML_QNT_VERSION_FACTOR;
	}

	// load vocab
	{
	int32_t n_vocab = 0;
	fin.read((char *) &n_vocab, sizeof(n_vocab));

	if (n_vocab != model.hparams.n_vocab) {
	fprintf(stderr, "%s: invalid model file '%s' (bad vocab size %d != %d)\n",
	__func__, fname.c_str(), n_vocab, model.hparams.n_vocab);
	return false;
	}

	std::string word;
	std::vector<char> buf(128);

	for (int i = 0; i < n_vocab; i++) {
	uint32_t len;
	fin.read((char *) &len, sizeof(len));

	buf.resize(len);
	fin.read((char *) buf.data(), len);
	word.assign(buf.data(), len);

	vocab.token_to_id[word] = i;
	vocab.id_to_token[i] = word;
	}
	}

	// for the big tensors, we have the option to store the data in 16-bit floats or quantized
	// in order to save memory and also to speed up the computation
	ggml_type wtype = ggml_ftype_to_ggml_type((ggml_ftype) (model.hparams.ftype));
	if (wtype == GGML_TYPE_COUNT) {
	fprintf(stderr, "%s: invalid model file '%s' (bad ftype value %d)\n",
	__func__, fname.c_str(), model.hparams.ftype);
	return false;
	}

	auto & ctx = model.ctx;

	size_t buffer_size = 0;

	{
	const auto & hparams = model.hparams;

	const int n_embd = hparams.n_embd;
	const int n_layer = hparams.n_layer;
	const int n_ctx = hparams.n_ctx;
	const int n_vocab = hparams.n_vocab;

	buffer_size += n_embd*ggml_type_sizef(GGML_TYPE_F32); // ln_f_g
	buffer_size += n_embd*ggml_type_sizef(GGML_TYPE_F32); // ln_f_b

	buffer_size += n_vocabn_embdggml_type_sizef(wtype); // wte
	buffer_size += n_ctxn_embdggml_type_sizef(GGML_TYPE_F32); // wpe
	buffer_size += n_vocabn_embdggml_type_sizef(wtype); // lm_head

	buffer_size += n_layer(n_embdggml_type_sizef(GGML_TYPE_F32)); // ln_1_g
	buffer_size += n_layer(n_embdggml_type_sizef(GGML_TYPE_F32)); // ln_1_b

	buffer_size += n_layer(n_embdggml_type_sizef(GGML_TYPE_F32)); // ln_2_g
	buffer_size += n_layer(n_embdggml_type_sizef(GGML_TYPE_F32)); // ln_2_b

	buffer_size += n_layer(3n_embdn_embdggml_type_sizef(wtype)); // c_attn_attn_w
	buffer_size += n_layer( 3n_embd*ggml_type_sizef(GGML_TYPE_F32)); // c_attn_attn_b

	buffer_size += n_layer(n_embdn_embd*ggml_type_sizef(wtype)); // c_attn_proj_w
	buffer_size += n_layer( n_embdggml_type_sizef(GGML_TYPE_F32)); // c_attn_proj_b

	buffer_size += n_layer(4n_embdn_embdggml_type_sizef(wtype)); // c_mlp_fc_w
	buffer_size += n_layer( 4n_embd*ggml_type_sizef(GGML_TYPE_F32)); // c_mlp_fc_b

	buffer_size += n_layer(4n_embdn_embdggml_type_sizef(wtype)); // c_mlp_proj_w
	buffer_size += n_layer( n_embdggml_type_sizef(GGML_TYPE_F32)); // c_mlp_proj_b

	buffer_size += (6 + 12n_layer)128; // alignment overhead

	printf("%s: ggml tensor size = %d bytes\n", __func__, (int) sizeof(ggml_tensor));
	printf("%s: backend buffer size = %6.2f MB\n", __func__, buffer_size/(1024.0*1024.0));
	}

	// create the ggml context
	{
	size_t n_tensors = 2 + 6 + 12*model.hparams.n_layer;
	struct ggml_init_params params = {
	/.mem_size =/ ggml_tensor_overhead() * n_tensors,
	/.mem_buffer =/ NULL,
	/.no_alloc =/ true,
	};

	model.ctx = ggml_init(params);
	if (!model.ctx) {
	fprintf(stderr, "%s: ggml_init() failed\n", __func__);
	return false;
	}
	}

	// initialize the backend
	#ifdef GGML_USE_CUBLAS
	if (n_gpu_layers > 0) {
	fprintf(stderr, "%s: using CUDA backend\n", __func__);
	model.backend = ggml_backend_cuda_init();
	if (!model.backend) {
	fprintf(stderr, "%s: ggml_backend_cuda_init() failed\n", __func__);
	}
	}
	#endif

	#ifdef GGML_USE_METAL
	if (n_gpu_layers > 0) {
	fprintf(stderr, "%s: using Metal backend\n", __func__);
	ggml_metal_log_set_callback(ggml_log_callback_default, nullptr);
	model.backend = ggml_backend_metal_init();
	if (!model.backend) {
	fprintf(stderr, "%s: ggml_backend_metal_init() failed\n", __func__);
	}
	}
	#endif

	if (!model.backend) {
	// fallback to CPU backend
	fprintf(stderr, "%s: using CPU backend\n", __func__);
	model.backend = ggml_backend_cpu_init();
	}

	if (!model.backend) {
	fprintf(stderr, "%s: ggml_backend_cpu_init() failed\n", __func__);
	return false;
	}

	// allocate weights buffer
	model.buffer_w = ggml_backend_alloc_buffer(model.backend, buffer_size);

	// prepare memory for the weights
	{
	const auto & hparams = model.hparams;

	const int n_embd = hparams.n_embd;
	const int n_layer = hparams.n_layer;
	const int n_ctx = hparams.n_ctx;
	const int n_vocab = hparams.n_vocab;

	model.layers.resize(n_layer);

	model.ln_f_g = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);
	model.ln_f_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);

	model.wte = ggml_new_tensor_2d(ctx, wtype, n_embd, n_vocab);
	model.wpe = ggml_new_tensor_2d(ctx, GGML_TYPE_F32, n_embd, n_ctx);
	model.lm_head = ggml_new_tensor_2d(ctx, wtype, n_embd, n_vocab);

	// map by name
	model.tensors["model/ln_f/g"] = model.ln_f_g;
	model.tensors["model/ln_f/b"] = model.ln_f_b;

	model.tensors["model/wte"] = model.wte;
	model.tensors["model/wpe"] = model.wpe;
	model.tensors["model/lm_head"] = model.lm_head;

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

	layer.ln_1_g = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);
	layer.ln_1_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);

	layer.ln_2_g = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);
	layer.ln_2_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);

	layer.c_attn_attn_w = ggml_new_tensor_2d(ctx, wtype, n_embd, 3*n_embd);
	layer.c_attn_attn_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, 3*n_embd);

	layer.c_attn_proj_w = ggml_new_tensor_2d(ctx, wtype, n_embd, n_embd);
	layer.c_attn_proj_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);

	layer.c_mlp_fc_w = ggml_new_tensor_2d(ctx, wtype, n_embd, 4*n_embd);
	layer.c_mlp_fc_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, 4*n_embd);

	layer.c_mlp_proj_w = ggml_new_tensor_2d(ctx, wtype, 4*n_embd, n_embd);
	layer.c_mlp_proj_b = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_embd);

	// map by name
	model.tensors["model/h" + std::to_string(i) + "/ln_1/g"] = layer.ln_1_g;
	model.tensors["model/h" + std::to_string(i) + "/ln_1/b"] = layer.ln_1_b;

	model.tensors["model/h" + std::to_string(i) + "/ln_2/g"] = layer.ln_2_g;
	model.tensors["model/h" + std::to_string(i) + "/ln_2/b"] = layer.ln_2_b;

	model.tensors["model/h" + std::to_string(i) + "/attn/c_attn/w"] = layer.c_attn_attn_w;
	model.tensors["model/h" + std::to_string(i) + "/attn/c_attn/b"] = layer.c_attn_attn_b;

	model.tensors["model/h" + std::to_string(i) + "/attn/c_proj/w"] = layer.c_attn_proj_w;
	model.tensors["model/h" + std::to_string(i) + "/attn/c_proj/b"] = layer.c_attn_proj_b;

	model.tensors["model/h" + std::to_string(i) + "/mlp/c_fc/w"] = layer.c_mlp_fc_w;
	model.tensors["model/h" + std::to_string(i) + "/mlp/c_fc/b"] = layer.c_mlp_fc_b;

	model.tensors["model/h" + std::to_string(i) + "/mlp/c_proj/w"] = layer.c_mlp_proj_w;
	model.tensors["model/h" + std::to_string(i) + "/mlp/c_proj/b"] = layer.c_mlp_proj_b;
	}
	}

	// override the default training context with the user-provided
	model.hparams.n_ctx = n_ctx;

	// key + value memory
	{
	const auto & hparams = model.hparams;

	const int n_embd = hparams.n_embd;
	const int n_layer = hparams.n_layer;
	const int n_ctx = hparams.n_ctx;

	const int n_mem = n_layer*n_ctx;
	const int n_elements = n_embd*n_mem;

	model.memory_k = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_elements);
	model.memory_v = ggml_new_tensor_1d(ctx, GGML_TYPE_F32, n_elements);

	const size_t memory_size = ggml_nbytes(model.memory_k) + ggml_nbytes(model.memory_v);

	printf("%s: memory size = %8.2f MB, n_mem = %d\n", __func__, memory_size/1024.0/1024.0, n_mem);

	// create a backend buffer (can be in host or device memory)
	model.buffer_kv = ggml_backend_alloc_buffer(model.backend, memory_size + 256);

	// allocate the tensors into the backend buffer
	{
	ggml_allocr * alloc = ggml_allocr_new_from_buffer(model.buffer_kv);

	// this updates the pointers in the tensors to point to the correct location in the buffer
	// this is necessary since the ggml_context is .no_alloc == true
	// note that the buffer can actually be a device buffer, depending on the backend
	ggml_allocr_alloc(alloc, model.memory_k);
	ggml_allocr_alloc(alloc, model.memory_v);

	ggml_allocr_free(alloc);
	}
	}

	// load weights
	{
	ggml_allocr * alloc = ggml_allocr_new_from_buffer(model.buffer_w);

	size_t total_size = 0;

	bool has_lm_head = false;

	std::vector<char> read_buf;

	while (true) {
	int32_t n_dims;
	int32_t length;
	int32_t ttype;

	fin.read(reinterpret_cast<char *>(&n_dims), sizeof(n_dims));
	fin.read(reinterpret_cast<char *>(&length), sizeof(length));
	fin.read(reinterpret_cast<char *>(&ttype), sizeof(ttype));

	if (fin.eof()) {
	break;
	}

	int32_t nelements = 1;
	int32_t ne[2] = { 1, 1 };
	for (int i = 0; i < n_dims; ++i) {
	fin.read(reinterpret_cast<char *>(&ne[i]), sizeof(ne[i]));
	nelements *= ne[i];
	}

	std::string name(length, 0);
	fin.read(&name[0], length);

	if (model.tensors.find(name) == model.tensors.end()) {
	fprintf(stderr, "%s: unknown tensor '%s' in model file\n", __func__, name.c_str());
	return false;
	}

	auto tensor = model.tensors[name];
	ggml_set_name(tensor, name.c_str());
	if (ggml_nelements(tensor) != nelements) {
	fprintf(stderr, "%s: tensor '%s' has wrong size in model file\n", __func__, name.c_str());
	return false;
	}

	if (tensor->ne[0] != ne[0] \|\| tensor->ne[1] != ne[1]) {
	fprintf(stderr, "%s: tensor '%s' has wrong shape in model file: got [%d, %d], expected [%d, %d]\n",
	__func__, name.c_str(), (int) tensor->ne[0], (int) tensor->ne[1], ne[0], ne[1]);
	return false;
	}

	// for debugging
	if (0) {
	printf("%24s - [%5d, %5d], type = %6s, %6.2f MB, %9zu bytes\n", name.c_str(), ne[0], ne[1], ggml_type_name(ggml_type(ttype)), ggml_nbytes(tensor)/1024.0/1024.0, ggml_nbytes(tensor));
	}

	const size_t bpe = ggml_type_size(ggml_type(ttype));

	if ((nelements*bpe)/ggml_blck_size(tensor->type) != ggml_nbytes(tensor)) {
	fprintf(stderr, "%s: tensor '%s' has wrong size in model file: got %zu, expected %zu\n",
	__func__, name.c_str(), ggml_nbytes(tensor), nelements*bpe);
	return false;
	}

	ggml_allocr_alloc(alloc, tensor);

	if (ggml_backend_is_cpu (model.backend)
	#ifdef GGML_USE_METAL
	\|\| ggml_backend_is_metal(model.backend)
	#endif
	) {
	// for the CPU and Metal backend, we can read directly into the tensor
	fin.read(reinterpret_cast<char *>(tensor->data), ggml_nbytes(tensor));
	} else {
	// read into a temporary buffer first, then copy to device memory
	read_buf.resize(ggml_nbytes(tensor));
	fin.read(read_buf.data(), ggml_nbytes(tensor));
	ggml_backend_tensor_set(tensor, read_buf.data(), 0, ggml_nbytes(tensor));
	}

	// GPT-2 models share the WTE tensor as the LM head
	if (name == "model/wte" && has_lm_head == false) {
	//ggml_allocr_alloc(alloc, model.lm_head);
	//ggml_backend_tensor_copy(tensor, model.lm_head);
	model.lm_head = tensor;
	}

	if (name == "model/lm_head") {
	has_lm_head = true;
	}

	total_size += ggml_nbytes(tensor);
	}

	ggml_allocr_free(alloc);
	printf("%s: model size = %8.2f MB\n", __func__, total_size/1024.0/1024.0);
	}

	fin.close();

	return true;
	}

	// build the computation graph
	struct ggml_cgraph * gpt2_graph(
	const gpt2_model & model,
	struct ggml_allocr * allocr,
	const int n_past,
	const std::vector<gpt_vocab::id> & embd_inp) {
	const int N = embd_inp.size();

	const auto & hparams = model.hparams;

	const int n_embd = hparams.n_embd;
	const int n_layer = hparams.n_layer;
	const int n_ctx = hparams.n_ctx;
	const int n_head = hparams.n_head;

	// since we are using ggml-alloc, this buffer only needs enough space to hold the ggml_tensor and ggml_cgraph structs, but not the tensor data
	static size_t buf_size = ggml_tensor_overhead()*GGML_MAX_NODES + ggml_graph_overhead();
	static std::vector<uint8_t> buf(buf_size);

	struct ggml_init_params params = {
	/.mem_size =/ buf_size,
	/.mem_buffer =/ buf.data(),
	/.no_alloc =/ true, // the tensors will be allocated later by ggml_allocr_alloc_graph()
	};

	struct ggml_context * ctx0 = ggml_init(params);

	struct ggml_cgraph * gf = ggml_new_graph(ctx0);

	struct ggml_tensor * embd = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, N);
	ggml_allocr_alloc(allocr, embd);

	// avoid writing to tensors if we are only measuring the memory usage
	if (!ggml_allocr_is_measure(allocr)) {
	ggml_backend_tensor_set(embd, embd_inp.data(), 0, N*ggml_element_size(embd));
	}

	struct ggml_tensor * position = ggml_new_tensor_1d(ctx0, GGML_TYPE_I32, N);
	ggml_allocr_alloc(allocr, position);
	if (!ggml_allocr_is_measure(allocr)) {
	for (int i = 0; i < N; ++i) {
	int32_t v = n_past + i;
	ggml_backend_tensor_set(position, &v, i*sizeof(int32_t), sizeof(v));
	}
	}

	struct ggml_tensor * KQ_scale = ggml_new_tensor_1d(ctx0, GGML_TYPE_F32, 1);
	ggml_allocr_alloc(allocr, KQ_scale);
	if (!ggml_allocr_is_measure(allocr)) {
	float s = 1.0f/sqrtf(float(n_embd)/n_head);
	ggml_backend_tensor_set(KQ_scale, &s, 0, sizeof(s));
	}

	// wte + wpe
	struct ggml_tensor * inpL =
	ggml_add(ctx0,
	ggml_get_rows(ctx0, model.wte, embd),
	ggml_get_rows(ctx0, model.wpe, position));

	for (int il = 0; il < n_layer; ++il) {
	struct ggml_tensor * cur;

	// norm
	{
	// [ 768, N]
	cur = ggml_norm(ctx0, inpL, hparams.eps);

	// cur = ln_1_g*cur + ln_1_b
	// [ 768, N]
	cur = ggml_add(ctx0,
	ggml_mul(ctx0,
	cur,
	model.layers[il].ln_1_g),
	model.layers[il].ln_1_b);
	}

	// attn
	// [2304, 768] - model.layers[il].c_attn_attn_w
	// [2304, 1] - model.layers[il].c_attn_attn_b
	// [ 768, N] - cur (in)
	// [2304, N] - cur (out)
	//
	// cur = attn_w*cur + attn_b
	// [2304, N]
	{
	cur = ggml_mul_mat(ctx0,
	model.layers[il].c_attn_attn_w,
	cur);

	cur = ggml_add(ctx0,
	cur,
	model.layers[il].c_attn_attn_b);
	}

	// self-attention
	{
	struct ggml_tensor * Qcur = ggml_view_2d(ctx0, cur, n_embd, N, cur->nb[1], 0sizeof(float)n_embd);
	struct ggml_tensor * Kcur = ggml_view_2d(ctx0, cur, n_embd, N, cur->nb[1], 1sizeof(float)n_embd);
	struct ggml_tensor * Vcur = ggml_view_2d(ctx0, cur, n_embd, N, cur->nb[1], 2sizeof(float)n_embd);

	// store key and value to memory
	if (N >= 1) {
	struct ggml_tensor * k = ggml_view_1d(ctx0, model.memory_k, Nn_embd, (ggml_element_size(model.memory_k)n_embd)(iln_ctx + n_past));
	struct ggml_tensor * v = ggml_view_1d(ctx0, model.memory_v, Nn_embd, (ggml_element_size(model.memory_v)n_embd)(iln_ctx + n_past));

	ggml_build_forward_expand(gf, ggml_cpy(ctx0, Kcur, k));
	ggml_build_forward_expand(gf, ggml_cpy(ctx0, Vcur, v));
	}

	// Q = Qcur.contiguous().view(n_embd/n_head, n_head, N).permute(0, 2, 1, 3)
	// [64, N, 12]
	struct ggml_tensor * Q =
	ggml_permute(ctx0,
	ggml_cpy(ctx0,
	Qcur,
	ggml_new_tensor_3d(ctx0, GGML_TYPE_F32, n_embd/n_head, n_head, N)),
	0, 2, 1, 3);

	// K = Kmem.view(n_embd/n_head, n_head, n_past + N).permute(0, 2, 1, 3)
	// [64, n_past + N, 12]
	struct ggml_tensor * K =
	ggml_permute(ctx0,
	ggml_reshape_3d(ctx0,
	ggml_view_1d(ctx0, model.memory_k, (n_past + N)n_embd, iln_ctxggml_element_size(model.memory_k)n_embd),
	n_embd/n_head, n_head, n_past + N),
	0, 2, 1, 3);

	// GG: flash attention
	//struct ggml_tensor * V =
	// ggml_cpy(ctx0,
	// ggml_permute(ctx0,
	// ggml_reshape_3d(ctx0,
	// ggml_view_1d(ctx0, model.memory_v, (n_past + N)n_embd, iln_ctxggml_element_size(model.memory_v)n_embd),
	// n_embd/n_head, n_head, n_past + N),
	// 1, 2, 0, 3),
	// ggml_new_tensor_3d(ctx0, GGML_TYPE_F32, n_past + N, n_embd/n_head, n_head));

	//struct ggml_tensor * KQV = ggml_flash_attn(ctx0, Q, K, V, true);

	// K * Q
	// [n_past + N, N, 12]
	struct ggml_tensor * KQ = ggml_mul_mat(ctx0, K, Q);

	// KQ_scaled = KQ / sqrt(n_embd/n_head)
	// [n_past + N, N, 12]
	struct ggml_tensor * KQ_scaled =
	ggml_scale(ctx0,
	KQ,
	KQ_scale);

	// KQ_masked = mask_past(KQ_scaled)
	// [n_past + N, N, 12]
	struct ggml_tensor * KQ_masked = ggml_diag_mask_inf(ctx0, KQ_scaled, n_past);

	// KQ = soft_max(KQ_masked)
	// [n_past + N, N, 12]
	struct ggml_tensor * KQ_soft_max = ggml_soft_max(ctx0, KQ_masked);

	// V_trans = Vmem.view(n_embd/n_head, n_head, n_past + N).permute(1, 2, 0, 3).contiguous()
	// [n_past + N, 64, 12]
	struct ggml_tensor * V_trans =
	ggml_cpy(ctx0,
	ggml_permute(ctx0,
	ggml_reshape_3d(ctx0,
	ggml_view_1d(ctx0, model.memory_v, (n_past + N)n_embd, iln_ctxggml_element_size(model.memory_v)n_embd),
	n_embd/n_head, n_head, n_past + N),
	1, 2, 0, 3),
	ggml_new_tensor_3d(ctx0, model.memory_v->type, n_past + N, n_embd/n_head, n_head));

	// KQV = transpose(V) * KQ_soft_max
	// [64, N, 12]
	struct ggml_tensor * KQV = ggml_mul_mat(ctx0, V_trans, KQ_soft_max);

	// KQV_merged = KQV.permute(0, 2, 1, 3)
	// [64, 12, N]
	struct ggml_tensor * KQV_merged = ggml_permute(ctx0, KQV, 0, 2, 1, 3);

	// cur = KQV_merged.contiguous().view(n_embd, N)
	// [768, N]
	cur = ggml_cpy(ctx0,
	KQV_merged,
	ggml_new_tensor_2d(ctx0, GGML_TYPE_F32, n_embd, N));
	}

	// projection
	// [ 768, 768] - model.layers[il].c_attn_proj_w
	// [ 768, 1] - model.layers[il].c_attn_proj_b
	// [ 768, N] - cur (in)
	// [ 768, N] - cur (out)
	//
	// cur = proj_w*cur + proj_b
	// [768, N]
	{
	cur = ggml_mul_mat(ctx0,
	model.layers[il].c_attn_proj_w,
	cur);

	cur = ggml_add(ctx0,
	cur,
	model.layers[il].c_attn_proj_b);
	}

	// add the input
	cur = ggml_add(ctx0, cur, inpL);

	struct ggml_tensor * inpFF = cur;

	// feed-forward network
	{
	// norm
	{
	cur = ggml_norm(ctx0, inpFF, hparams.eps);

	// cur = ln_2_g*cur + ln_2_b
	// [ 768, N]
	cur = ggml_add(ctx0,
	ggml_mul(ctx0,
	cur,
	model.layers[il].ln_2_g),
	model.layers[il].ln_2_b);
	}

	// fully connected
	// [3072, 768] - model.layers[il].c_mlp_fc_w
	// [3072, 1] - model.layers[il].c_mlp_fc_b
	// [ 768, N] - cur (in)
	// [3072, N] - cur (out)
	//
	// cur = fc_w*cur + fc_b
	// [3072, N]
	cur = ggml_mul_mat(ctx0,
	model.layers[il].c_mlp_fc_w,
	cur);

	cur = ggml_add(ctx0,
	cur,
	model.layers[il].c_mlp_fc_b);

	// GELU activation
	// [3072, N]
	cur = ggml_gelu(ctx0, cur);

	// projection
	// [ 768, 3072] - model.layers[il].c_mlp_proj_w
	// [ 768, 1] - model.layers[il].c_mlp_proj_b
	// [3072, N] - cur (in)
	// [ 768, N] - cur (out)
	//
	// cur = proj_w*cur + proj_b
	// [768, N]
	cur = ggml_mul_mat(ctx0,
	model.layers[il].c_mlp_proj_w,
	cur);

	cur = ggml_add(ctx0,
	cur,
	model.layers[il].c_mlp_proj_b);
	}

	// input for next layer
	inpL = ggml_add(ctx0, cur, inpFF);
	}

	// norm
	{
	// [ 768, N]
	inpL = ggml_norm(ctx0, inpL, hparams.eps);

	// inpL = ln_f_g*inpL + ln_f_b
	// [ 768, N]
	inpL = ggml_add(ctx0,
	ggml_mul(ctx0,
	inpL,
	model.ln_f_g),
	model.ln_f_b);
	}

	// inpL = WTE * inpL
	// [ 768, 50257] - model.lm_head
	// [ 768, N] - inpL
	inpL = ggml_mul_mat(ctx0, model.lm_head, inpL);

	// logits -> probs
	//inpL = ggml_soft_max(ctx0, inpL);

	ggml_build_forward_expand(gf, inpL);

	ggml_free(ctx0);

	return gf;
	}

	// evaluate the transformer
	//
	// - model: the model
	// - allocr: ggml_allocr to use to allocate the compute buffer
	// - n_threads: number of threads to use
	// - n_past: the context size so far
	// - embd_inp: the embeddings of the tokens in the context
	// - embd_w: the predicted logits for the next token
	//
	bool gpt2_eval(
	const gpt2_model & model,
	struct ggml_allocr * allocr,
	const int n_threads,
	const int n_past,
	const std::vector<gpt_vocab::id> & embd_inp,
	std::vector<float> & embd_w) {
	const int N = embd_inp.size();

	const auto & hparams = model.hparams;

	const int n_vocab = hparams.n_vocab;

	// reset the allocator to free all the memory allocated during the previous inference
	ggml_allocr_reset(allocr);

	struct ggml_cgraph * gf = gpt2_graph(model, allocr, n_past, embd_inp);

	// allocate tensors
	ggml_allocr_alloc_graph(allocr, gf);

	// run the computation
	if (ggml_backend_is_cpu(model.backend)) {
	ggml_backend_cpu_set_n_threads(model.backend, n_threads);
	}
	#ifdef GGML_USE_METAL
	if (ggml_backend_is_metal(model.backend)) {
	ggml_backend_metal_set_n_cb(model.backend, n_threads);
	}
	#endif
	ggml_backend_graph_compute(model.backend, gf);

	//if (n_past%100 == 0) {
	// ggml_graph_print (&gf);
	// ggml_graph_dump_dot(&gf, NULL, "gpt-2.dot");
	//}

	// in this case, the output tensor is the last one in the graph
	struct ggml_tensor * inpL = gf->nodes[gf->n_nodes - 1];

	//embd_w.resize(n_vocab*N);
	//ggml_backend_tensor_get(inpL, embd_w.data(), 0, sizeof(float)n_vocabN);

	// return result just for the last token
	embd_w.resize(n_vocab);
	ggml_backend_tensor_get(inpL, embd_w.data(), (n_vocab(N-1))sizeof(float), sizeof(float)*n_vocab);

	return true;
	}

	int main(int argc, char ** argv) {
	ggml_time_init();

	const int64_t t_main_start_us = ggml_time_us();

	gpt_params params;
	params.model = "models/gpt-2-117M/ggml-model.bin";

	if (gpt_params_parse(argc, argv, params) == false) {
	return 1;
	}

	if (params.seed < 0) {
	params.seed = time(NULL);
	}

	printf("%s: seed = %d\n", __func__, params.seed);

	std::mt19937 rng(params.seed);
	if (params.prompt.empty()) {
	params.prompt = gpt_random_prompt(rng);
	}

	int64_t t_load_us = 0;

	gpt_vocab vocab;
	gpt2_model model;

	// load the model
	{
	const int64_t t_start_us = ggml_time_us();

	if (!gpt2_model_load(params.model, model, vocab, params.n_ctx, params.n_gpu_layers)) {
	fprintf(stderr, "%s: failed to load model from '%s'\n", __func__, params.model.c_str());
	return 1;
	}

	t_load_us = ggml_time_us() - t_start_us;

	test_gpt_tokenizer(vocab, params.token_test);
	}

	// keep this buffer alive while evaluating the model
	ggml_backend_buffer_t buf_compute;

	struct ggml_allocr * allocr = NULL;
	// allocate the compute buffer
	{
	// alignment required by the backend
	size_t align = ggml_backend_get_alignment(model.backend);
	allocr = ggml_allocr_new_measure(align);

	// create the worst case graph for memory usage estimation
	int n_tokens = std::min(model.hparams.n_ctx, params.n_batch);
	int n_past = model.hparams.n_ctx - n_tokens;
	struct ggml_cgraph * gf = gpt2_graph(model, allocr, n_past, std::vector<gpt_vocab::id>(n_tokens, 0));

	// compute the required memory
	size_t mem_size = ggml_allocr_alloc_graph(allocr, gf);

	// recreate the allocator with the required memory
	ggml_allocr_free(allocr);
	buf_compute = ggml_backend_alloc_buffer(model.backend, mem_size);
	allocr = ggml_allocr_new_from_buffer(buf_compute);

	fprintf(stderr, "%s: compute buffer size: %.2f MB\n", __func__, mem_size/1024.0/1024.0);
	}

	int n_past = 0;

	int64_t t_sample_us = 0;
	int64_t t_predict_us = 0;

	std::vector<float> logits;

	// tokenize the prompt
	std::vector<gpt_vocab::id> embd_inp = ::gpt_tokenize(vocab, params.prompt);

	params.n_predict = std::min(params.n_predict, model.hparams.n_ctx - (int) embd_inp.size());

	printf("%s: prompt: '%s'\n", __func__, params.prompt.c_str());
	printf("%s: number of tokens in prompt = %zu, first 8 tokens: ", __func__, embd_inp.size());
	for (int i = 0; i < std::min(8, (int) embd_inp.size()); i++) {
	printf("%d ", embd_inp[i]);
	}
	printf("\n\n");

	// submit the input prompt token-by-token
	// this reduces the memory usage during inference, at the cost of a bit of speed at the beginning
	std::vector<gpt_vocab::id> embd;

	for (size_t i = embd.size(); i < embd_inp.size() + params.n_predict; i++) {
	// predict
	if (embd.size() > 0) {
	const int64_t t_start_us = ggml_time_us();

	if (!gpt2_eval(model, allocr, params.n_threads, n_past, embd, logits)) {
	printf("Failed to predict\n");
	return 1;
	}

	t_predict_us += ggml_time_us() - t_start_us;
	}

	n_past += embd.size();
	embd.clear();

	if (i >= embd_inp.size()) {
	// sample next token
	const int top_k = params.top_k;
	const float top_p = params.top_p;
	const float temp = params.temp;

	const int n_vocab = model.hparams.n_vocab;

	gpt_vocab::id id = 0;

	{
	const int64_t t_start_sample_us = ggml_time_us();

	id = gpt_sample_top_k_top_p(vocab, logits.data() + (logits.size() - n_vocab), top_k, top_p, temp, rng);

	t_sample_us += ggml_time_us() - t_start_sample_us;
	}

	// add it to the context
	embd.push_back(id);
	} else {
	// if here, it means we are still processing the input prompt
	for (size_t k = i; k < embd_inp.size(); k++) {
	embd.push_back(embd_inp[k]);
	if (int32_t(embd.size()) >= params.n_batch) {
	break;
	}
	}
	i += embd.size() - 1;
	}

	// display text
	for (auto id : embd) {
	printf("%s", vocab.id_to_token[id].c_str());
	}
	fflush(stdout);

	// end of text token
	if (!params.ignore_eos && embd.back() == 50256) {
	break;
	}
	}

	// report timing
	{
	const int64_t t_main_end_us = ggml_time_us();

	printf("\n\n");
	printf("%s: load time = %8.2f ms\n", __func__, t_load_us/1000.0f);
	printf("%s: sample time = %8.2f ms\n", __func__, t_sample_us/1000.0f);
	printf("%s: predict time = %8.2f ms / %.2f ms per token\n", __func__, t_predict_us/1000.0f, t_predict_us/1000.0f/n_past);
	printf("%s: total time = %8.2f ms\n", __func__, (t_main_end_us - t_main_start_us)/1000.0f);
	}

	ggml_free(model.ctx);

	ggml_backend_buffer_free(model.buffer_w);
	ggml_backend_buffer_free(model.buffer_kv);
	ggml_backend_buffer_free(buf_compute);
	ggml_backend_free(model.backend);

	return 0;
	}