Roformer.cpp/include/bs_roformer/inference.h

#pragma once

#include <vector>
#include <string>
#include <memory>
#include <functional>
// Forward declaration
class BSRoformer;

// Forward declaration
namespace ggml { struct context; struct cgraph; }

class Inference {
public:
    Inference(const std::string& model_path);
    ~Inference();

    // Process a full audio track (interleaved stereo float32)
    // Uses overlap-add chunking to handle long files
    // Process a full audio track (interleaved stereo float32)
    // Returns a vector of stems, where each stem is an interleaved stereo float vector
    std::vector<std::vector<float>> Process(const std::vector<float>& input_audio, 
                               int chunk_size = 352800, 
                               int num_overlap = 2,
                               std::function<void(float)> progress_callback = nullptr);

    // Low-level chunk processing (public for testing)
    std::vector<std::vector<float>> ProcessChunk(const std::vector<float>& chunk_audio);

    // Get model's recommended inference defaults
    int GetDefaultChunkSize() const;
    int GetDefaultNumOverlap() const;
    int GetSampleRate() const;

    // Static helper for Overlap-Add logic (matches Python exactly)
    // model_func: input [samples], output [stems][samples] (interleaved stereo)
    using ModelCallback = std::function<std::vector<std::vector<float>>(const std::vector<float>&)>;
    static std::vector<std::vector<float>> ProcessOverlapAdd(const std::vector<float>& input_audio, 
                                                int chunk_size, 
                                                int num_overlap,
                                                ModelCallback model_func,
                                                std::function<void(float)> progress_callback = nullptr); // Added callback

private:
    // Pipelined Overlap-Add
    std::vector<std::vector<float>> ProcessOverlapAddPipelined(const std::vector<float>& input_audio, 
                                                  int chunk_size, 
                                                  int num_overlap,
                                                  std::function<void(float)> progress_callback);

private:
    std::unique_ptr<BSRoformer> model_;
    
    // Persistent Graph State
    struct ggml_context* ctx_ = nullptr;
    struct ggml_cgraph* gf_ = nullptr;
    struct ggml_gallocr* allocr_ = nullptr;
    
    // Cached Input Tensors (owned by ctx_)
    struct ggml_tensor* input_tensor_ = nullptr;
    struct ggml_tensor* pos_time_ = nullptr;
    struct ggml_tensor* pos_freq_ = nullptr;
    struct ggml_tensor* mask_out_tensor_ = nullptr;

    // Current config state
    int cached_n_frames_ = -1;

    // Pipelined State Data
    struct ChunkState {
        int id = -1;
        std::vector<float> input_audio;       // Original chunk audio
        std::vector<float> stft_flattened;    // [Prepared Input for GPU]
        std::vector<std::vector<float>> stft_outputs; // Kept for reconstruction
        int n_frames = 0;
        
        std::vector<float> mask_output;       // Output from GPU
        std::vector<std::vector<float>> final_audio;       // Result after ISTFT [stems][samples]
    };

    // Helper to ensure graph is built for specific n_frames
    bool EnsureGraph(int n_frames);

    void ComputeSTFT(const std::vector<float>& input_audio,
                     std::vector<std::vector<float>>& stft_outputs,
                     int& n_frames);
                     
    void PrepareModelInput(const std::vector<std::vector<float>>& stft_outputs,
                           int n_frames,
                           std::vector<float>& model_input_rearranged);

    void PostProcessAndISTFT(const std::vector<float>& mask_output,
                             const std::vector<std::vector<float>>& stft_outputs,
                             int n_frames,
                             std::vector<std::vector<float>>& output_audio);

    // Pipeline Steps
    std::shared_ptr<ChunkState> PreProcessChunk(const std::vector<float>& chunk_audio, int id);
    void RunInference(std::shared_ptr<ChunkState> state);
    void PostProcessChunk(std::shared_ptr<ChunkState> state);
};