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diffusion_model.hpp
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339 lines (280 loc) · 11.5 KB
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#ifndef __DIFFUSION_MODEL_H__
#define __DIFFUSION_MODEL_H__
#include "flux.hpp"
#include "mmdit.hpp"
#include "qwen_image.hpp"
#include "unet.hpp"
#include "wan.hpp"
struct DiffusionParams {
struct ggml_tensor* x = nullptr;
struct ggml_tensor* timesteps = nullptr;
struct ggml_tensor* context = nullptr;
struct ggml_tensor* c_concat = nullptr;
struct ggml_tensor* y = nullptr;
struct ggml_tensor* guidance = nullptr;
std::vector<ggml_tensor*> ref_latents = {};
bool increase_ref_index = false;
int num_video_frames = -1;
std::vector<struct ggml_tensor*> controls = {};
float control_strength = 0.f;
struct ggml_tensor* vace_context = nullptr;
float vace_strength = 1.f;
std::vector<int> skip_layers = {};
};
struct DiffusionModel {
virtual std::string get_desc() = 0;
virtual void compute(int n_threads,
DiffusionParams diffusion_params,
struct ggml_tensor** output = nullptr,
struct ggml_context* output_ctx = nullptr) = 0;
virtual void alloc_params_buffer() = 0;
virtual void free_params_buffer() = 0;
virtual void free_compute_buffer() = 0;
virtual void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors) = 0;
virtual size_t get_params_buffer_size() = 0;
virtual int64_t get_adm_in_channels() = 0;
virtual void set_flash_attn_enabled(bool enabled) = 0;
};
struct UNetModel : public DiffusionModel {
UNetModelRunner unet;
UNetModel(ggml_backend_t backend,
bool offload_params_to_cpu,
const String2TensorStorage& tensor_storage_map = {},
SDVersion version = VERSION_SD1)
: unet(backend, offload_params_to_cpu, tensor_storage_map, "model.diffusion_model", version) {
}
std::string get_desc() override {
return unet.get_desc();
}
void alloc_params_buffer() override {
unet.alloc_params_buffer();
}
void free_params_buffer() override {
unet.free_params_buffer();
}
void free_compute_buffer() override {
unet.free_compute_buffer();
}
void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors) override {
unet.get_param_tensors(tensors, "model.diffusion_model");
}
size_t get_params_buffer_size() override {
return unet.get_params_buffer_size();
}
int64_t get_adm_in_channels() override {
return unet.unet.adm_in_channels;
}
void set_flash_attn_enabled(bool enabled) {
unet.set_flash_attention_enabled(enabled);
}
void compute(int n_threads,
DiffusionParams diffusion_params,
struct ggml_tensor** output = nullptr,
struct ggml_context* output_ctx = nullptr) override {
return unet.compute(n_threads,
diffusion_params.x,
diffusion_params.timesteps,
diffusion_params.context,
diffusion_params.c_concat,
diffusion_params.y,
diffusion_params.num_video_frames,
diffusion_params.controls,
diffusion_params.control_strength, output, output_ctx);
}
};
struct MMDiTModel : public DiffusionModel {
MMDiTRunner mmdit;
MMDiTModel(ggml_backend_t backend,
bool offload_params_to_cpu,
const String2TensorStorage& tensor_storage_map = {})
: mmdit(backend, offload_params_to_cpu, tensor_storage_map, "model.diffusion_model") {
}
std::string get_desc() override {
return mmdit.get_desc();
}
void alloc_params_buffer() override {
mmdit.alloc_params_buffer();
}
void free_params_buffer() override {
mmdit.free_params_buffer();
}
void free_compute_buffer() override {
mmdit.free_compute_buffer();
}
void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors) override {
mmdit.get_param_tensors(tensors, "model.diffusion_model");
}
size_t get_params_buffer_size() override {
return mmdit.get_params_buffer_size();
}
int64_t get_adm_in_channels() override {
return 768 + 1280;
}
void set_flash_attn_enabled(bool enabled) {
mmdit.set_flash_attention_enabled(enabled);
}
void compute(int n_threads,
DiffusionParams diffusion_params,
struct ggml_tensor** output = nullptr,
struct ggml_context* output_ctx = nullptr) override {
return mmdit.compute(n_threads,
diffusion_params.x,
diffusion_params.timesteps,
diffusion_params.context,
diffusion_params.y,
output,
output_ctx,
diffusion_params.skip_layers);
}
};
struct FluxModel : public DiffusionModel {
Flux::FluxRunner flux;
FluxModel(ggml_backend_t backend,
bool offload_params_to_cpu,
const String2TensorStorage& tensor_storage_map = {},
SDVersion version = VERSION_FLUX,
bool use_mask = false)
: flux(backend, offload_params_to_cpu, tensor_storage_map, "model.diffusion_model", version, use_mask) {
}
std::string get_desc() override {
return flux.get_desc();
}
void alloc_params_buffer() override {
flux.alloc_params_buffer();
}
void free_params_buffer() override {
flux.free_params_buffer();
}
void free_compute_buffer() override {
flux.free_compute_buffer();
}
void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors) override {
flux.get_param_tensors(tensors, "model.diffusion_model");
}
size_t get_params_buffer_size() override {
return flux.get_params_buffer_size();
}
int64_t get_adm_in_channels() override {
return 768;
}
void set_flash_attn_enabled(bool enabled) {
flux.set_flash_attention_enabled(enabled);
}
void compute(int n_threads,
DiffusionParams diffusion_params,
struct ggml_tensor** output = nullptr,
struct ggml_context* output_ctx = nullptr) override {
return flux.compute(n_threads,
diffusion_params.x,
diffusion_params.timesteps,
diffusion_params.context,
diffusion_params.c_concat,
diffusion_params.y,
diffusion_params.guidance,
diffusion_params.ref_latents,
diffusion_params.increase_ref_index,
output,
output_ctx,
diffusion_params.skip_layers);
}
};
struct WanModel : public DiffusionModel {
std::string prefix;
WAN::WanRunner wan;
WanModel(ggml_backend_t backend,
bool offload_params_to_cpu,
const String2TensorStorage& tensor_storage_map = {},
const std::string prefix = "model.diffusion_model",
SDVersion version = VERSION_WAN2)
: prefix(prefix), wan(backend, offload_params_to_cpu, tensor_storage_map, prefix, version) {
}
std::string get_desc() override {
return wan.get_desc();
}
void alloc_params_buffer() override {
wan.alloc_params_buffer();
}
void free_params_buffer() override {
wan.free_params_buffer();
}
void free_compute_buffer() override {
wan.free_compute_buffer();
}
void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors) override {
wan.get_param_tensors(tensors, prefix);
}
size_t get_params_buffer_size() override {
return wan.get_params_buffer_size();
}
int64_t get_adm_in_channels() override {
return 768;
}
void set_flash_attn_enabled(bool enabled) {
wan.set_flash_attention_enabled(enabled);
}
void compute(int n_threads,
DiffusionParams diffusion_params,
struct ggml_tensor** output = nullptr,
struct ggml_context* output_ctx = nullptr) override {
return wan.compute(n_threads,
diffusion_params.x,
diffusion_params.timesteps,
diffusion_params.context,
diffusion_params.y,
diffusion_params.c_concat,
nullptr,
diffusion_params.vace_context,
diffusion_params.vace_strength,
output,
output_ctx);
}
};
struct QwenImageModel : public DiffusionModel {
std::string prefix;
Qwen::QwenImageRunner qwen_image;
QwenImageModel(ggml_backend_t backend,
bool offload_params_to_cpu,
const String2TensorStorage& tensor_storage_map = {},
const std::string prefix = "model.diffusion_model",
SDVersion version = VERSION_QWEN_IMAGE)
: prefix(prefix), qwen_image(backend, offload_params_to_cpu, tensor_storage_map, prefix, version) {
}
std::string get_desc() override {
return qwen_image.get_desc();
}
void alloc_params_buffer() override {
qwen_image.alloc_params_buffer();
}
void free_params_buffer() override {
qwen_image.free_params_buffer();
}
void free_compute_buffer() override {
qwen_image.free_compute_buffer();
}
void get_param_tensors(std::map<std::string, struct ggml_tensor*>& tensors) override {
qwen_image.get_param_tensors(tensors, prefix);
}
size_t get_params_buffer_size() override {
return qwen_image.get_params_buffer_size();
}
int64_t get_adm_in_channels() override {
return 768;
}
void set_flash_attn_enabled(bool enabled) {
qwen_image.set_flash_attention_enabled(enabled);
}
void compute(int n_threads,
DiffusionParams diffusion_params,
struct ggml_tensor** output = nullptr,
struct ggml_context* output_ctx = nullptr) override {
return qwen_image.compute(n_threads,
diffusion_params.x,
diffusion_params.timesteps,
diffusion_params.context,
diffusion_params.ref_latents,
true, // increase_ref_index
output,
output_ctx);
}
};
#endif