godot/thirdparty/jpeg-compressor/jpge.h

// jpge.h - C++ class for JPEG compression.
// Public Domain or Apache 2.0, Richard Geldreich <richgel99@gmail.com>
// Alex Evans: Added RGBA support, linear memory allocator.
#ifndef JPEG_ENCODER_H
#define JPEG_ENCODER_H

namespace jpge
{
	typedef unsigned char  uint8;
	typedef signed short   int16;
	typedef signed int     int32;
	typedef unsigned short uint16;
	typedef unsigned int   uint32;
	typedef unsigned int   uint;

	// JPEG chroma subsampling factors. Y_ONLY (grayscale images) and H2V2 (color images) are the most common.
	enum subsampling_t { Y_ONLY = 0, H1V1 = 1, H2V1 = 2, H2V2 = 3 };

	// JPEG compression parameters structure.
	struct params
	{
		inline params() : m_quality(85), m_subsampling(H2V2), m_no_chroma_discrim_flag(false), m_two_pass_flag(false), m_use_std_tables(false) { }

		inline bool check() const
		{
			if ((m_quality < 1) || (m_quality > 100)) return false;
			if ((uint)m_subsampling > (uint)H2V2) return false;
			return true;
		}

		// Quality: 1-100, higher is better. Typical values are around 50-95.
		int m_quality;

		// m_subsampling:
		// 0 = Y (grayscale) only
		// 1 = YCbCr, no subsampling (H1V1, YCbCr 1x1x1, 3 blocks per MCU)
		// 2 = YCbCr, H2V1 subsampling (YCbCr 2x1x1, 4 blocks per MCU)
		// 3 = YCbCr, H2V2 subsampling (YCbCr 4x1x1, 6 blocks per MCU-- very common)
		subsampling_t m_subsampling;

		// Disables CbCr discrimination - only intended for testing.
		// If true, the Y quantization table is also used for the CbCr channels.
		bool m_no_chroma_discrim_flag;

		bool m_two_pass_flag;

		// By default we use the same quantization tables as mozjpeg's default. 
		// Set to true to use the traditional tables from JPEG Annex K.
		bool m_use_std_tables;
	};

	// Writes JPEG image to a file. 
	// num_channels must be 1 (Y) or 3 (RGB), image pitch must be width*num_channels.
	bool compress_image_to_jpeg_file(const char* pFilename, int width, int height, int num_channels, const uint8* pImage_data, const params& comp_params = params());

	// Writes JPEG image to memory buffer. 
	// On entry, buf_size is the size of the output buffer pointed at by pBuf, which should be at least ~1024 bytes. 
	// If return value is true, buf_size will be set to the size of the compressed data.
	bool compress_image_to_jpeg_file_in_memory(void* pBuf, int& buf_size, int width, int height, int num_channels, const uint8* pImage_data, const params& comp_params = params());

	// Output stream abstract class - used by the jpeg_encoder class to write to the output stream. 
	// put_buf() is generally called with len==JPGE_OUT_BUF_SIZE bytes, but for headers it'll be called with smaller amounts.
	class output_stream
	{
	public:
		virtual ~output_stream() { };
		virtual bool put_buf(const void* Pbuf, int len) = 0;
		template<class T> inline bool put_obj(const T& obj) { return put_buf(&obj, sizeof(T)); }
	};

	// Lower level jpeg_encoder class - useful if more control is needed than the above helper functions.
	class jpeg_encoder
	{
	public:
		jpeg_encoder();
		~jpeg_encoder();

		// Initializes the compressor.
		// pStream: The stream object to use for writing compressed data.
		// params - Compression parameters structure, defined above.
		// width, height  - Image dimensions.
		// channels - May be 1, or 3. 1 indicates grayscale, 3 indicates RGB source data.
		// Returns false on out of memory or if a stream write fails.
		bool init(output_stream* pStream, int width, int height, int src_channels, const params& comp_params = params());

		const params& get_params() const { return m_params; }

		// Deinitializes the compressor, freeing any allocated memory. May be called at any time.
		void deinit();

		uint get_total_passes() const { return m_params.m_two_pass_flag ? 2 : 1; }
		inline uint get_cur_pass() { return m_pass_num; }

		// Call this method with each source scanline.
		// width * src_channels bytes per scanline is expected (RGB or Y format).
		// You must call with NULL after all scanlines are processed to finish compression.
		// Returns false on out of memory or if a stream write fails.
		bool process_scanline(const void* pScanline);

	private:
		jpeg_encoder(const jpeg_encoder&);
		jpeg_encoder& operator =(const jpeg_encoder&);

		typedef int32 sample_array_t;

		output_stream* m_pStream;
		params m_params;
		uint8 m_num_components;
		uint8 m_comp_h_samp[3], m_comp_v_samp[3];
		int m_image_x, m_image_y, m_image_bpp, m_image_bpl;
		int m_image_x_mcu, m_image_y_mcu;
		int m_image_bpl_xlt, m_image_bpl_mcu;
		int m_mcus_per_row;
		int m_mcu_x, m_mcu_y;
		uint8* m_mcu_lines[16];
		uint8 m_mcu_y_ofs;
		sample_array_t m_sample_array[64];
		int16 m_coefficient_array[64];
		int32 m_quantization_tables[2][64];
		uint m_huff_codes[4][256];
		uint8 m_huff_code_sizes[4][256];
		uint8 m_huff_bits[4][17];
		uint8 m_huff_val[4][256];
		uint32 m_huff_count[4][256];
		int m_last_dc_val[3];
		enum { JPGE_OUT_BUF_SIZE = 2048 };
		uint8 m_out_buf[JPGE_OUT_BUF_SIZE];
		uint8* m_pOut_buf;
		uint m_out_buf_left;
		uint32 m_bit_buffer;
		uint m_bits_in;
		uint8 m_pass_num;
		bool m_all_stream_writes_succeeded;

		void optimize_huffman_table(int table_num, int table_len);
		void emit_byte(uint8 i);
		void emit_word(uint i);
		void emit_marker(int marker);
		void emit_jfif_app0();
		void emit_dqt();
		void emit_sof();
		void emit_dht(uint8* bits, uint8* val, int index, bool ac_flag);
		void emit_dhts();
		void emit_sos();
		void emit_markers();
		void compute_huffman_table(uint* codes, uint8* code_sizes, uint8* bits, uint8* val);
		void compute_quant_table(int32* dst, int16* src);
		void adjust_quant_table(int32* dst, int32* src);
		void first_pass_init();
		bool second_pass_init();
		bool jpg_open(int p_x_res, int p_y_res, int src_channels);
		void load_block_8_8_grey(int x);
		void load_block_8_8(int x, int y, int c);
		void load_block_16_8(int x, int c);
		void load_block_16_8_8(int x, int c);
		void load_quantized_coefficients(int component_num);
		void flush_output_buffer();
		void put_bits(uint bits, uint len);
		void code_coefficients_pass_one(int component_num);
		void code_coefficients_pass_two(int component_num);
		void code_block(int component_num);
		void process_mcu_row();
		bool terminate_pass_one();
		bool terminate_pass_two();
		bool process_end_of_image();
		void load_mcu(const void* src);
		void clear();
		void init();
	};

} // namespace jpge

#endif // JPEG_ENCODER
Implement Running Godot as Movie Writer * Allows running the game in "movie writer" mode. * It ensures entirely stable framerate, so your run can be saved stable and with proper sound (which is impossible if your CPU/GPU can't sustain doing this in real-time). * If disabling vsync, it can save movies faster than the game is run, but if you want to control the interaction it can get difficult. * Implements a simple, default MJPEG writer. This new features has two main use cases, which have high demand: * Saving game videos in high quality and ensuring the frame rate is completely stable, always. * Using Godot as a tool to make movies and animations (which is ideal if you want interaction, or creating them procedurally. No other software is as good for this). Note: This feature IS NOT for capturing real-time footage. Use something like OBS, SimpleScreenRecorder or FRAPS to achieve that, as they do a much better job at intercepting the compositor than Godot can probably do using Vulkan or OpenGL natively. If your game runs near real-time when capturing, you can still use this feature but it will play no sound (sound will be saved directly). Usage: $ godot --write-movie movie.avi [scene_file.tscn] Missing: * Options for configuring video writing via GLOBAL_DEF * UI Menu for launching with this mode from the editor. * Add to list of command line options. * Add a feature tag to override configurations when movie writing (fantastic for saving videos with highest quality settings). 2022-06-17 00:55:19 +02:00			`// jpge.h - C++ class for JPEG compression.`
			`// Public Domain or Apache 2.0, Richard Geldreich <richgel99@gmail.com>`
			`// Alex Evans: Added RGBA support, linear memory allocator.`
			`#ifndef JPEG_ENCODER_H`
			`#define JPEG_ENCODER_H`

			`namespace jpge`
			`{`
			`typedef unsigned char uint8;`
			`typedef signed short int16;`
			`typedef signed int int32;`
			`typedef unsigned short uint16;`
			`typedef unsigned int uint32;`
			`typedef unsigned int uint;`

			`// JPEG chroma subsampling factors. Y_ONLY (grayscale images) and H2V2 (color images) are the most common.`
			`enum subsampling_t { Y_ONLY = 0, H1V1 = 1, H2V1 = 2, H2V2 = 3 };`

			`// JPEG compression parameters structure.`
			`struct params`
			`{`
			`inline params() : m_quality(85), m_subsampling(H2V2), m_no_chroma_discrim_flag(false), m_two_pass_flag(false), m_use_std_tables(false) { }`

			`inline bool check() const`
			`{`
			`if ((m_quality < 1) \|\| (m_quality > 100)) return false;`
			`if ((uint)m_subsampling > (uint)H2V2) return false;`
			`return true;`
			`}`

			`// Quality: 1-100, higher is better. Typical values are around 50-95.`
			`int m_quality;`

			`// m_subsampling:`
			`// 0 = Y (grayscale) only`
			`// 1 = YCbCr, no subsampling (H1V1, YCbCr 1x1x1, 3 blocks per MCU)`
			`// 2 = YCbCr, H2V1 subsampling (YCbCr 2x1x1, 4 blocks per MCU)`
			`// 3 = YCbCr, H2V2 subsampling (YCbCr 4x1x1, 6 blocks per MCU-- very common)`
			`subsampling_t m_subsampling;`

			`// Disables CbCr discrimination - only intended for testing.`
			`// If true, the Y quantization table is also used for the CbCr channels.`
			`bool m_no_chroma_discrim_flag;`

			`bool m_two_pass_flag;`

			`// By default we use the same quantization tables as mozjpeg's default.`
			`// Set to true to use the traditional tables from JPEG Annex K.`
			`bool m_use_std_tables;`
			`};`

			`// Writes JPEG image to a file.`
			`// num_channels must be 1 (Y) or 3 (RGB), image pitch must be width*num_channels.`
			`bool compress_image_to_jpeg_file(const char* pFilename, int width, int height, int num_channels, const uint8* pImage_data, const params& comp_params = params());`

			`// Writes JPEG image to memory buffer.`
			`// On entry, buf_size is the size of the output buffer pointed at by pBuf, which should be at least ~1024 bytes.`
			`// If return value is true, buf_size will be set to the size of the compressed data.`
			`bool compress_image_to_jpeg_file_in_memory(void* pBuf, int& buf_size, int width, int height, int num_channels, const uint8* pImage_data, const params& comp_params = params());`

			`// Output stream abstract class - used by the jpeg_encoder class to write to the output stream.`
			`// put_buf() is generally called with len==JPGE_OUT_BUF_SIZE bytes, but for headers it'll be called with smaller amounts.`
			`class output_stream`
			`{`
			`public:`
			`virtual ~output_stream() { };`
			`virtual bool put_buf(const void* Pbuf, int len) = 0;`
			`template<class T> inline bool put_obj(const T& obj) { return put_buf(&obj, sizeof(T)); }`
			`};`

			`// Lower level jpeg_encoder class - useful if more control is needed than the above helper functions.`
			`class jpeg_encoder`
			`{`
			`public:`
			`jpeg_encoder();`
			`~jpeg_encoder();`

			`// Initializes the compressor.`
			`// pStream: The stream object to use for writing compressed data.`
			`// params - Compression parameters structure, defined above.`
			`// width, height - Image dimensions.`
			`// channels - May be 1, or 3. 1 indicates grayscale, 3 indicates RGB source data.`
			`// Returns false on out of memory or if a stream write fails.`
			`bool init(output_stream* pStream, int width, int height, int src_channels, const params& comp_params = params());`

			`const params& get_params() const { return m_params; }`

			`// Deinitializes the compressor, freeing any allocated memory. May be called at any time.`
			`void deinit();`

			`uint get_total_passes() const { return m_params.m_two_pass_flag ? 2 : 1; }`
			`inline uint get_cur_pass() { return m_pass_num; }`

			`// Call this method with each source scanline.`
			`// width * src_channels bytes per scanline is expected (RGB or Y format).`
			`// You must call with NULL after all scanlines are processed to finish compression.`
			`// Returns false on out of memory or if a stream write fails.`
			`bool process_scanline(const void* pScanline);`

			`private:`
			`jpeg_encoder(const jpeg_encoder&);`
			`jpeg_encoder& operator =(const jpeg_encoder&);`

			`typedef int32 sample_array_t;`

			`output_stream* m_pStream;`
			`params m_params;`
			`uint8 m_num_components;`
			`uint8 m_comp_h_samp[3], m_comp_v_samp[3];`
			`int m_image_x, m_image_y, m_image_bpp, m_image_bpl;`
			`int m_image_x_mcu, m_image_y_mcu;`
			`int m_image_bpl_xlt, m_image_bpl_mcu;`
			`int m_mcus_per_row;`
			`int m_mcu_x, m_mcu_y;`
			`uint8* m_mcu_lines[16];`
			`uint8 m_mcu_y_ofs;`
			`sample_array_t m_sample_array[64];`
			`int16 m_coefficient_array[64];`
			`int32 m_quantization_tables[2][64];`
			`uint m_huff_codes[4][256];`
			`uint8 m_huff_code_sizes[4][256];`
			`uint8 m_huff_bits[4][17];`
			`uint8 m_huff_val[4][256];`
			`uint32 m_huff_count[4][256];`
			`int m_last_dc_val[3];`
			`enum { JPGE_OUT_BUF_SIZE = 2048 };`
			`uint8 m_out_buf[JPGE_OUT_BUF_SIZE];`
			`uint8* m_pOut_buf;`
			`uint m_out_buf_left;`
			`uint32 m_bit_buffer;`
			`uint m_bits_in;`
			`uint8 m_pass_num;`
			`bool m_all_stream_writes_succeeded;`

			`void optimize_huffman_table(int table_num, int table_len);`
			`void emit_byte(uint8 i);`
			`void emit_word(uint i);`
			`void emit_marker(int marker);`
			`void emit_jfif_app0();`
			`void emit_dqt();`
			`void emit_sof();`
			`void emit_dht(uint8* bits, uint8* val, int index, bool ac_flag);`
			`void emit_dhts();`
			`void emit_sos();`
			`void emit_markers();`
			`void compute_huffman_table(uint* codes, uint8* code_sizes, uint8* bits, uint8* val);`
			`void compute_quant_table(int32* dst, int16* src);`
			`void adjust_quant_table(int32* dst, int32* src);`
			`void first_pass_init();`
			`bool second_pass_init();`
			`bool jpg_open(int p_x_res, int p_y_res, int src_channels);`
			`void load_block_8_8_grey(int x);`
			`void load_block_8_8(int x, int y, int c);`
			`void load_block_16_8(int x, int c);`
			`void load_block_16_8_8(int x, int c);`
			`void load_quantized_coefficients(int component_num);`
			`void flush_output_buffer();`
			`void put_bits(uint bits, uint len);`
			`void code_coefficients_pass_one(int component_num);`
			`void code_coefficients_pass_two(int component_num);`
			`void code_block(int component_num);`
			`void process_mcu_row();`
			`bool terminate_pass_one();`
			`bool terminate_pass_two();`
			`bool process_end_of_image();`
			`void load_mcu(const void* src);`
			`void clear();`
			`void init();`
			`};`

			`} // namespace jpge`

			`#endif // JPEG_ENCODER`