[nihav.git] / nihav-codec-support / src / imgwrite / mod.rs

//! Simple PNM image writers for RGB and YUV images.
use std::io::prelude::*;
use std::fs::File;
use nihav_core::frame::{NABufferType, NAFrameRef};

/// Writes PGMYUV for input frame.
pub fn write_pgmyuv(name: &str, frm: NAFrameRef) -> std::io::Result<()> {
    if let NABufferType::None = frm.get_buffer() { return Ok(()); }
    let mut ofile = File::create(name)?;
    let buf = frm.get_buffer().get_vbuf().unwrap();
    let is_flipped = buf.get_info().is_flipped();
    let (w, h) = buf.get_dimensions(0);
    let (w2, h2) = buf.get_dimensions(1);
    let full_w = w2 * 2 > w;
    let has_alpha = buf.get_info().get_format().has_alpha();
    let mut tot_h = h + h2;
    if has_alpha {
        tot_h += h;
    }
    if full_w {
        tot_h += h2;
    }
    let hdr = format!("P5\n{} {}\n255\n", w, tot_h);
    ofile.write_all(hdr.as_bytes())?;
    let dta = buf.get_data();
    let ls = buf.get_stride(0);
    let pad: Vec<u8> = vec![0xFF; if !full_w { (w - w2 * 2) / 2 } else { w - w2 } ];
    if !is_flipped {
        let ylines = dta.chunks(ls).take(h);
        for line in ylines {
            ofile.write_all(&line[..w])?;
        }
    } else {
        let ylines = dta[..h * ls].chunks(ls).rev();
        for line in ylines {
            ofile.write_all(&line[..w])?;
        }
    }
    let base1 = buf.get_offset(1);
    let stride1 = buf.get_stride(1);
    let base2 = buf.get_offset(2);
    let stride2 = buf.get_stride(2);
    let u = &dta[base1..][..h2*stride1];
    let v = &dta[base2..][..h2*stride2];
    let has_chroma = stride1 > 0 && stride2 > 0;
    if !full_w && has_chroma {
        if !is_flipped {
            for (uline, vline) in u.chunks(stride1).zip(v.chunks(stride2)) {
                ofile.write_all(&uline[..w2])?;
                ofile.write_all(pad.as_slice())?;

                ofile.write_all(&vline[..w2])?;
                ofile.write_all(pad.as_slice())?;
            }
        } else {
            for (uline, vline) in u.chunks(stride1).rev().zip(v.chunks(stride2).rev()) {
                ofile.write_all(&uline[..w2])?;
                ofile.write_all(pad.as_slice())?;

                ofile.write_all(&vline[..w2])?;
                ofile.write_all(pad.as_slice())?;
            }
        }
    } else if has_chroma {
        if !is_flipped {
            for uline in u.chunks(stride1) {
                ofile.write_all(&uline[..w2])?;
                ofile.write_all(pad.as_slice())?;
            }
            for vline in v.chunks(stride2) {
                ofile.write_all(&vline[..w2])?;
                ofile.write_all(pad.as_slice())?;
            }
        } else {
            for uline in u.chunks(stride1).rev() {
                ofile.write_all(&uline[..w2])?;
                ofile.write_all(pad.as_slice())?;
            }
            for vline in v.chunks(stride2).rev() {
                ofile.write_all(&vline[..w2])?;
                ofile.write_all(pad.as_slice())?;
            }
        }
    }
    if has_alpha {
        let ls = buf.get_stride(3);
        let mut idx = buf.get_offset(3);
        let mut idx2 = idx + w;
        for _ in 0..h {
            let line = &dta[idx..idx2];
            ofile.write_all(line)?;
            idx  += ls;
            idx2 += ls;
        }
    }
    Ok(())
}

/// Writes output PPM for input paletted input frame.
pub fn write_palppm(name: &str, frm: NAFrameRef) -> std::io::Result<()> {
    if let NABufferType::None = frm.get_buffer() { return Ok(()); }
    let mut ofile = File::create(name)?;
    let buf = frm.get_buffer().get_vbuf().unwrap();
    let (w, h) = buf.get_dimensions(0);
    let paloff = buf.get_offset(1);
    let hdr = format!("P6\n{} {}\n255\n", w, h);
    ofile.write_all(hdr.as_bytes())?;
    let dta = buf.get_data();
    let ls = buf.get_stride(0);
    let offs: [usize; 3] = [
            buf.get_info().get_format().get_chromaton(0).unwrap().get_offset() as usize,
            buf.get_info().get_format().get_chromaton(1).unwrap().get_offset() as usize,
            buf.get_info().get_format().get_chromaton(2).unwrap().get_offset() as usize
        ];
    let flipped = buf.get_info().is_flipped();
    let mut idx  = if !flipped { 0 } else { ls * h };
    let mut line: Vec<u8> = vec![0; w * 3];
    for _ in 0..h {
        if flipped {
            idx -= ls;
        }
        let src = &dta[idx..(idx+w)];
        for x in 0..w {
            let pix = src[x] as usize;
            line[x * 3 + 0] = dta[paloff + pix * 3 + offs[0]];
            line[x * 3 + 1] = dta[paloff + pix * 3 + offs[1]];
            line[x * 3 + 2] = dta[paloff + pix * 3 + offs[2]];
        }
        ofile.write_all(line.as_slice())?;
        if !flipped {
            idx += ls;
        }
    }
    Ok(())
}

/// Writes PPM file for RGB input.
pub fn write_rgbppm(name: &str, frm: NAFrameRef) -> std::io::Result<()> {
    if let NABufferType::None = frm.get_buffer() { return Ok(()); }
    let mut ofile = File::create(name)?;
    let info = frm.get_buffer().get_video_info().unwrap();
    let flipped = info.is_flipped();
    let buffer = frm.get_buffer();
    if let Some(ref buf) = buffer.get_vbuf() {
        let (w, h) = buf.get_dimensions(0);
        let hdr = format!("P6\n{} {}\n255\n", w, h);
        ofile.write_all(hdr.as_bytes())?;
        let dta = buf.get_data();
        let stride = buf.get_stride(0);
        let offs: [usize; 3] = [
                info.get_format().get_chromaton(0).unwrap().get_offset() as usize,
                info.get_format().get_chromaton(1).unwrap().get_offset() as usize,
                info.get_format().get_chromaton(2).unwrap().get_offset() as usize
            ];
        let step = info.get_format().get_elem_size() as usize;
        let mut line: Vec<u8> = vec![0; w * 3];
        if !flipped {
            for src in dta.chunks(stride) {
                for x in 0..w {
                    line[x * 3 + 0] = src[x * step + offs[0]];
                    line[x * 3 + 1] = src[x * step + offs[1]];
                    line[x * 3 + 2] = src[x * step + offs[2]];
                }
                ofile.write_all(line.as_slice())?;
            }
        } else {
            for src in dta[..stride * h].chunks(stride).rev() {
                for x in 0..w {
                    line[x * 3 + 0] = src[x * step + offs[0]];
                    line[x * 3 + 1] = src[x * step + offs[1]];
                    line[x * 3 + 2] = src[x * step + offs[2]];
                }
                ofile.write_all(line.as_slice())?;
            }
        }
    } else if let NABufferType::Video16(ref buf) = buffer {
        let (w, h) = buf.get_dimensions(0);
        let hdr = format!("P6\n{} {}\n255\n", w, h);
        ofile.write_all(hdr.as_bytes())?;
        let dta = buf.get_data();
        let stride = buf.get_stride(0);
        let depths: [u8; 3] = [
                info.get_format().get_chromaton(0).unwrap().get_depth(),
                info.get_format().get_chromaton(1).unwrap().get_depth(),
                info.get_format().get_chromaton(2).unwrap().get_depth()
            ];
        let masks: [u16; 3] = [
                (1 << depths[0]) - 1,
                (1 << depths[1]) - 1,
                (1 << depths[2]) - 1
            ];
        let shifts: [u8; 3] = [
                info.get_format().get_chromaton(0).unwrap().get_shift(),
                info.get_format().get_chromaton(1).unwrap().get_shift(),
                info.get_format().get_chromaton(2).unwrap().get_shift()
            ];
        let mut line: Vec<u8> = vec![0; w * 3];
        if !flipped {
            for src in dta.chunks(stride) {
                for x in 0..w {
                    let elem = src[x];
                    let r = ((elem >> shifts[0]) & masks[0]) << (8 - depths[0]);
                    let g = ((elem >> shifts[1]) & masks[1]) << (8 - depths[1]);
                    let b = ((elem >> shifts[2]) & masks[2]) << (8 - depths[2]);
                    line[x * 3 + 0] = r as u8;
                    line[x * 3 + 1] = g as u8;
                    line[x * 3 + 2] = b as u8;
                }
                ofile.write_all(line.as_slice())?;
            }
        } else {
            for src in dta[..h * stride].chunks(stride).rev() {
                for x in 0..w {
                    let elem = src[x];
                    let r = ((elem >> shifts[0]) & masks[0]) << (8 - depths[0]);
                    let g = ((elem >> shifts[1]) & masks[1]) << (8 - depths[1]);
                    let b = ((elem >> shifts[2]) & masks[2]) << (8 - depths[2]);
                    line[x * 3 + 0] = r as u8;
                    line[x * 3 + 1] = g as u8;
                    line[x * 3 + 2] = b as u8;
                }
                ofile.write_all(line.as_slice())?;
            }
        }
    } else {
panic!(" unhandled buf format");
    }
    Ok(())
}

/// Writes PNM file with a format depending on input format.
pub fn write_pnm(pfx: &str, strno: usize, num: u64, frm: NAFrameRef) -> std::io::Result<()> {
    if let NABufferType::None = frm.get_buffer() { return Ok(()); }

    let vinfo = frm.get_buffer().get_video_info().unwrap();
    if vinfo.get_format().is_paletted() {
        let name = format!("{}{:02}_{:06}.ppm", pfx, strno, num);
        write_palppm(name.as_str(), frm)
    } else if vinfo.get_format().get_model().is_yuv() {
        let name = format!("{}{:02}_{:06}.pgm", pfx, strno, num);
        write_pgmyuv(name.as_str(), frm)
    } else if vinfo.get_format().get_model().is_rgb() {
        let name = format!("{}{:02}_{:06}.ppm", pfx, strno, num);
        write_rgbppm(name.as_str(), frm)
    } else {
panic!(" unknown format");
    }
}
Commit	Line	Data
8424ddfd KS	1	//! Simple PNM image writers for RGB and YUV images.
	2	use std::io::prelude::*;
	3	use std::fs::File;
	4	use nihav_core::frame::{NABufferType, NAFrameRef};
	5
	6	/// Writes PGMYUV for input frame.
	7	pub fn write_pgmyuv(name: &str, frm: NAFrameRef) -> std::io::Result<()> {
	8	if let NABufferType::None = frm.get_buffer() { return Ok(()); }
	9	let mut ofile = File::create(name)?;
	10	let buf = frm.get_buffer().get_vbuf().unwrap();
	11	let is_flipped = buf.get_info().is_flipped();
	12	let (w, h) = buf.get_dimensions(0);
	13	let (w2, h2) = buf.get_dimensions(1);
	14	let full_w = w2 * 2 > w;
	15	let has_alpha = buf.get_info().get_format().has_alpha();
	16	let mut tot_h = h + h2;
	17	if has_alpha {
	18	tot_h += h;
	19	}
	20	if full_w {
	21	tot_h += h2;
	22	}
	23	let hdr = format!("P5\n{} {}\n255\n", w, tot_h);
	24	ofile.write_all(hdr.as_bytes())?;
	25	let dta = buf.get_data();
	26	let ls = buf.get_stride(0);
	27	let pad: Vec<u8> = vec![0xFF; if !full_w { (w - w2 * 2) / 2 } else { w - w2 } ];
	28	if !is_flipped {
	29	let ylines = dta.chunks(ls).take(h);
	30	for line in ylines {
	31	ofile.write_all(&line[..w])?;
	32	}
	33	} else {
	34	let ylines = dta[..h * ls].chunks(ls).rev();
	35	for line in ylines {
	36	ofile.write_all(&line[..w])?;
	37	}
	38	}
	39	let base1 = buf.get_offset(1);
	40	let stride1 = buf.get_stride(1);
	41	let base2 = buf.get_offset(2);
	42	let stride2 = buf.get_stride(2);
	43	let u = &dta[base1..][..h2*stride1];
	44	let v = &dta[base2..][..h2*stride2];
	45	let has_chroma = stride1 > 0 && stride2 > 0;
	46	if !full_w && has_chroma {
	47	if !is_flipped {
	48	for (uline, vline) in u.chunks(stride1).zip(v.chunks(stride2)) {
	49	ofile.write_all(&uline[..w2])?;
	50	ofile.write_all(pad.as_slice())?;
	51
	52	ofile.write_all(&vline[..w2])?;
	53	ofile.write_all(pad.as_slice())?;
	54	}
	55	} else {
	56	for (uline, vline) in u.chunks(stride1).rev().zip(v.chunks(stride2).rev()) {
	57	ofile.write_all(&uline[..w2])?;
	58	ofile.write_all(pad.as_slice())?;
	59
	60	ofile.write_all(&vline[..w2])?;
	61	ofile.write_all(pad.as_slice())?;
	62	}
	63	}
	64	} else if has_chroma {
65	if !is_flipped {
66	for uline in u.chunks(stride1) {
67	ofile.write_all(&uline[..w2])?;
68	ofile.write_all(pad.as_slice())?;
69	}
70	for vline in v.chunks(stride2) {
71	ofile.write_all(&vline[..w2])?;
72	ofile.write_all(pad.as_slice())?;
73	}
74	} else {
75	for uline in u.chunks(stride1).rev() {
76	ofile.write_all(&uline[..w2])?;
77	ofile.write_all(pad.as_slice())?;
78	}
79	for vline in v.chunks(stride2).rev() {
80	ofile.write_all(&vline[..w2])?;
81	ofile.write_all(pad.as_slice())?;
82	}
83	}
84	}
85	if has_alpha {
86	let ls = buf.get_stride(3);
87	let mut idx = buf.get_offset(3);
88	let mut idx2 = idx + w;
89	for _ in 0..h {
90	let line = &dta[idx..idx2];
91	ofile.write_all(line)?;
92	idx += ls;
93	idx2 += ls;
94	}
95	}
96	Ok(())
97	}
98
99	/// Writes output PPM for input paletted input frame.
100	pub fn write_palppm(name: &str, frm: NAFrameRef) -> std::io::Result<()> {
101	if let NABufferType::None = frm.get_buffer() { return Ok(()); }
102	let mut ofile = File::create(name)?;
103	let buf = frm.get_buffer().get_vbuf().unwrap();
104	let (w, h) = buf.get_dimensions(0);
105	let paloff = buf.get_offset(1);
106	let hdr = format!("P6\n{} {}\n255\n", w, h);
107	ofile.write_all(hdr.as_bytes())?;
108	let dta = buf.get_data();
109	let ls = buf.get_stride(0);
110	let offs: [usize; 3] = [
111	buf.get_info().get_format().get_chromaton(0).unwrap().get_offset() as usize,
112	buf.get_info().get_format().get_chromaton(1).unwrap().get_offset() as usize,
113	buf.get_info().get_format().get_chromaton(2).unwrap().get_offset() as usize
114	];
115	let flipped = buf.get_info().is_flipped();
116	let mut idx = if !flipped { 0 } else { ls * h };
117	let mut line: Vec<u8> = vec![0; w * 3];
118	for _ in 0..h {
119	if flipped {
120	idx -= ls;
121	}
122	let src = &dta[idx..(idx+w)];
123	for x in 0..w {
124	let pix = src[x] as usize;
125	line[x * 3 + 0] = dta[paloff + pix * 3 + offs[0]];
126	line[x * 3 + 1] = dta[paloff + pix * 3 + offs[1]];
127	line[x * 3 + 2] = dta[paloff + pix * 3 + offs[2]];
128	}
129	ofile.write_all(line.as_slice())?;
130	if !flipped {
131	idx += ls;
132	}
133	}
134	Ok(())
135	}
136
137	/// Writes PPM file for RGB input.
138	pub fn write_rgbppm(name: &str, frm: NAFrameRef) -> std::io::Result<()> {
139	if let NABufferType::None = frm.get_buffer() { return Ok(()); }
140	let mut ofile = File::create(name)?;
141	let info = frm.get_buffer().get_video_info().unwrap();
142	let flipped = info.is_flipped();
143	let buffer = frm.get_buffer();
144	if let Some(ref buf) = buffer.get_vbuf() {
145	let (w, h) = buf.get_dimensions(0);
146	let hdr = format!("P6\n{} {}\n255\n", w, h);
147	ofile.write_all(hdr.as_bytes())?;
148	let dta = buf.get_data();
149	let stride = buf.get_stride(0);
150	let offs: [usize; 3] = [
151	info.get_format().get_chromaton(0).unwrap().get_offset() as usize,
152	info.get_format().get_chromaton(1).unwrap().get_offset() as usize,
153	info.get_format().get_chromaton(2).unwrap().get_offset() as usize
154	];
155	let step = info.get_format().get_elem_size() as usize;
156	let mut line: Vec<u8> = vec![0; w * 3];
157	if !flipped {
158	for src in dta.chunks(stride) {
159	for x in 0..w {
160	line[x * 3 + 0] = src[x * step + offs[0]];
161	line[x * 3 + 1] = src[x * step + offs[1]];
162	line[x * 3 + 2] = src[x * step + offs[2]];
163	}
164	ofile.write_all(line.as_slice())?;
165	}
166	} else {
167	for src in dta[..stride * h].chunks(stride).rev() {
168	for x in 0..w {
169	line[x * 3 + 0] = src[x * step + offs[0]];
170	line[x * 3 + 1] = src[x * step + offs[1]];
171	line[x * 3 + 2] = src[x * step + offs[2]];
172	}
173	ofile.write_all(line.as_slice())?;
174	}
175	}
176	} else if let NABufferType::Video16(ref buf) = buffer {
177	let (w, h) = buf.get_dimensions(0);
178	let hdr = format!("P6\n{} {}\n255\n", w, h);
179	ofile.write_all(hdr.as_bytes())?;
180	let dta = buf.get_data();
181	let stride = buf.get_stride(0);
182	let depths: [u8; 3] = [
183	info.get_format().get_chromaton(0).unwrap().get_depth(),
184	info.get_format().get_chromaton(1).unwrap().get_depth(),
185	info.get_format().get_chromaton(2).unwrap().get_depth()
186	];
187	let masks: [u16; 3] = [
188	(1 << depths[0]) - 1,
189	(1 << depths[1]) - 1,
190	(1 << depths[2]) - 1
191	];
192	let shifts: [u8; 3] = [
193	info.get_format().get_chromaton(0).unwrap().get_shift(),
194	info.get_format().get_chromaton(1).unwrap().get_shift(),
195	info.get_format().get_chromaton(2).unwrap().get_shift()
196	];
197	let mut line: Vec<u8> = vec![0; w * 3];
198	if !flipped {
199	for src in dta.chunks(stride) {
200	for x in 0..w {
201	let elem = src[x];
202	let r = ((elem >> shifts[0]) & masks[0]) << (8 - depths[0]);
203	let g = ((elem >> shifts[1]) & masks[1]) << (8 - depths[1]);
204	let b = ((elem >> shifts[2]) & masks[2]) << (8 - depths[2]);
205	line[x * 3 + 0] = r as u8;
206	line[x * 3 + 1] = g as u8;
207	line[x * 3 + 2] = b as u8;
208	}
209	ofile.write_all(line.as_slice())?;
210	}
211	} else {
212	for src in dta[..h * stride].chunks(stride).rev() {
213	for x in 0..w {
214	let elem = src[x];
215	let r = ((elem >> shifts[0]) & masks[0]) << (8 - depths[0]);
216	let g = ((elem >> shifts[1]) & masks[1]) << (8 - depths[1]);
217	let b = ((elem >> shifts[2]) & masks[2]) << (8 - depths[2]);
218	line[x * 3 + 0] = r as u8;
219	line[x * 3 + 1] = g as u8;
220	line[x * 3 + 2] = b as u8;
221	}
222	ofile.write_all(line.as_slice())?;
223	}
224	}
225	} else {
226	panic!(" unhandled buf format");
227	}
228	Ok(())
229	}
230
231	/// Writes PNM file with a format depending on input format.
232	pub fn write_pnm(pfx: &str, strno: usize, num: u64, frm: NAFrameRef) -> std::io::Result<()> {
233	if let NABufferType::None = frm.get_buffer() { return Ok(()); }
234
235	let vinfo = frm.get_buffer().get_video_info().unwrap();
236	if vinfo.get_format().is_paletted() {
237	let name = format!("{}{:02}_{:06}.ppm", pfx, strno, num);
238	write_palppm(name.as_str(), frm)
239	} else if vinfo.get_format().get_model().is_yuv() {
240	let name = format!("{}{:02}_{:06}.pgm", pfx, strno, num);
241	write_pgmyuv(name.as_str(), frm)
242	} else if vinfo.get_format().get_model().is_rgb() {
243	let name = format!("{}{:02}_{:06}.ppm", pfx, strno, num);
244	write_rgbppm(name.as_str(), frm)
245	} else {
246	panic!(" unknown format");
247	}
248	}
249