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// helper functions for ggml-metal that are too difficult to implement in Objective-C
#pragma once
#include <stdbool.h>
#ifdef __cplusplus
extern "C" {
#endif
struct ggml_tensor;
struct ggml_cgraph;
enum ggml_mem_range_type {
MEM_RANGE_TYPE_SRC = 0,
MEM_RANGE_TYPE_DST = 1,
};
// a helper object that can be used for reordering operations to improve concurrency
//
// the fundamental idea is that a set of tasks (either ggml ops, or something else) can run concurrently if they
// don't write to a memory that is being read by another task or written to by another task in the set
//
// with this structure, we can add tasks to the set, setting memory constraints. we can also check if a new task
// can be added to the set without violating the constraints (i.e. if it can be executed concurrently with the
// tasks already in the set)
//
typedef struct ggml_mem_ranges * ggml_mem_ranges_t;
ggml_mem_ranges_t ggml_mem_ranges_init(int debug);
void ggml_mem_ranges_free(ggml_mem_ranges_t mrs);
// remove all ranges from the set
void ggml_mem_ranges_reset(ggml_mem_ranges_t mrs);
// add src or dst ranges to track
bool ggml_mem_ranges_add(ggml_mem_ranges_t mrs, const struct ggml_tensor * tensor);
// return false if:
// - new src range overlaps with any existing dst range
// - new dst range overlaps with any existing range (src or dst)
bool ggml_mem_ranges_check(ggml_mem_ranges_t mrs, const struct ggml_tensor * tensor);
// reorder the nodes in the graph to improve concurrency, while respecting fusion
//
// note: this implementation is generic and not specific to metal
// if it proves to work well, we can start using it for other backends in the future
void ggml_graph_optimize(struct ggml_cgraph * gf);
#ifdef __cplusplus
}
#endif