/* * cx18 Vertical Blank Interval support functions * * Derived from ivtv-vbi.c * * Copyright (C) 2007 Hans Verkuil * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA * 02111-1307 USA */ #include "cx18-driver.h" #include "cx18-vbi.h" #include "cx18-ioctl.h" #include "cx18-queue.h" /* * Raster Reference/Protection (RP) bytes, used in Start/End Active * Video codes emitted from the digitzer in VIP 1.x mode, that flag the start * of VBI sample or VBI ancillary data regions in the digitial ratser line. * * Task FieldEven VerticalBlank HorizontalBlank 0 0 0 0 */ static const u8 raw_vbi_sav_rp[2] = { 0x20, 0x60 }; /* __V_, _FV_ */ static const u8 sliced_vbi_eav_rp[2] = { 0xb0, 0xf0 }; /* T_VH, TFVH */ static void copy_vbi_data(struct cx18 *cx, int lines, u32 pts_stamp) { int line = 0; int i; u32 linemask[2] = { 0, 0 }; unsigned short size; static const u8 mpeg_hdr_data[] = { /* MPEG-2 Program Pack */ 0x00, 0x00, 0x01, 0xba, /* Prog Pack start code */ 0x44, 0x00, 0x0c, 0x66, 0x24, 0x01, /* SCR, SCR Ext, markers */ 0x01, 0xd1, 0xd3, /* Mux Rate, markers */ 0xfa, 0xff, 0xff, /* Res, Suff cnt, Stuff */ /* MPEG-2 Private Stream 1 PES Packet */ 0x00, 0x00, 0x01, 0xbd, /* Priv Stream 1 start */ 0x00, 0x1a, /* length */ 0x84, 0x80, 0x07, /* flags, hdr data len */ 0x21, 0x00, 0x5d, 0x63, 0xa7, /* PTS, markers */ 0xff, 0xff /* stuffing */ }; const int sd = sizeof(mpeg_hdr_data); /* start of vbi data */ int idx = cx->vbi.frame % CX18_VBI_FRAMES; u8 *dst = &cx->vbi.sliced_mpeg_data[idx][0]; for (i = 0; i < lines; i++) { struct v4l2_sliced_vbi_data *sdata = cx->vbi.sliced_data + i; int f, l; if (sdata->id == 0) continue; l = sdata->line - 6; f = sdata->field; if (f) l += 18; if (l < 32) linemask[0] |= (1 << l); else linemask[1] |= (1 << (l - 32)); dst[sd + 12 + line * 43] = cx18_service2vbi(sdata->id); memcpy(dst + sd + 12 + line * 43 + 1, sdata->data, 42); line++; } memcpy(dst, mpeg_hdr_data, sizeof(mpeg_hdr_data)); if (line == 36) { /* All lines are used, so there is no space for the linemask (the max size of the VBI data is 36 * 43 + 4 bytes). So in this case we use the magic number 'ITV0'. */ memcpy(dst + sd, "ITV0", 4); memcpy(dst + sd + 4, dst + sd + 12, line * 43); size = 4 + ((43 * line + 3) & ~3); } else { memcpy(dst + sd, "itv0", 4); cpu_to_le32s(&linemask[0]); cpu_to_le32s(&linemask[1]); memcpy(dst + sd + 4, &linemask[0], 8); size = 12 + ((43 * line + 3) & ~3); } dst[4+16] = (size + 10) >> 8; dst[5+16] = (size + 10) & 0xff; dst[9+16] = 0x21 | ((pts_stamp >> 29) & 0x6); dst[10+16] = (pts_stamp >> 22) & 0xff; dst[11+16] = 1 | ((pts_stamp >> 14) & 0xff); dst[12+16] = (pts_stamp >> 7) & 0xff; dst[13+16] = 1 | ((pts_stamp & 0x7f) << 1); cx->vbi.sliced_mpeg_size[idx] = sd + size; } /* Compress raw VBI format, removes leading SAV codes and surplus space after the frame. Returns new compressed size. */ /* FIXME - this function ignores the input size. */ static u32 compress_raw_buf(struct cx18 *cx, u8 *buf, u32 size, u32 hdr_size) { u32 line_size = vbi_active_samples; u32 lines = cx->vbi.count * 2; u8 *q = buf; u8 *p; int i; /* Skip the header */ buf += hdr_size; for (i = 0; i < lines; i++) { p = buf + i * line_size; /* Look for SAV code */ if (p[0] != 0xff || p[1] || p[2] || (p[3] != raw_vbi_sav_rp[0] && p[3] != raw_vbi_sav_rp[1])) break; if (i == lines - 1) { /* last line is hdr_size bytes short - extrapolate it */ memcpy(q, p + 4, line_size - 4 - hdr_size); q += line_size - 4 - hdr_size; p += line_size - hdr_size - 1; memset(q, (int) *p, hdr_size); } else { memcpy(q, p + 4, line_size - 4); q += line_size - 4; } } return lines * (line_size - 4); } static u32 compress_sliced_buf(struct cx18 *cx, u8 *buf, u32 size, const u32 hdr_size) { struct v4l2_decode_vbi_line vbi; int i; u32 line = 0; u32 line_size = cx->is_60hz ? vbi_hblank_samples_60Hz : vbi_hblank_samples_50Hz; /* find the first valid line */ for (i = hdr_size, buf += hdr_size; i < size; i++, buf++) { if (buf[0] == 0xff && !buf[1] && !buf[2] && (buf[3] == sliced_vbi_eav_rp[0] || buf[3] == sliced_vbi_eav_rp[1])) break; } /* * The last line is short by hdr_size bytes, but for the remaining * checks against size, we pretend that it is not, by counting the * header bytes we knowingly skipped */ size -= (i - hdr_size); if (size < line_size) return line; for (i = 0; i < size / line_size; i++) { u8 *p = buf + i * line_size; /* Look for EAV code */ if (p[0] != 0xff || p[1] || p[2] || (p[3] != sliced_vbi_eav_rp[0] && p[3] != sliced_vbi_eav_rp[1])) continue; vbi.p = p + 4; v4l2_subdev_call(cx->sd_av, vbi, decode_vbi_line, &vbi); if (vbi.type) { cx->vbi.sliced_data[line].id = vbi.type; cx->vbi.sliced_data[line].field = vbi.is_second_field; cx->vbi.sliced_data[line].line = vbi.line; memcpy(cx->vbi.sliced_data[line].data, vbi.p, 42); line++; } } return line; } static void _cx18_process_vbi_data(struct cx18 *cx, struct cx18_buffer *buf) { /* * The CX23418 provides a 12 byte header in its raw VBI buffers to us: * 0x3fffffff [4 bytes of something] [4 byte presentation time stamp] */ struct vbi_data_hdr { __be32 magic; __be32 unknown; __be32 pts; } *hdr = (struct vbi_data_hdr *) buf->buf; u8 *p = (u8 *) buf->buf; u32 size = buf->bytesused; u32 pts; int lines; /* * The CX23418 sends us data that is 32 bit little-endian swapped, * but we want the raw VBI bytes in the order they were in the raster * line. This has a side effect of making the header big endian */ cx18_buf_swap(buf); /* Raw VBI data */ if (cx18_raw_vbi(cx)) { size = buf->bytesused = compress_raw_buf(cx, p, size, sizeof(struct vbi_data_hdr)); /* * Hack needed for compatibility with old VBI software. * Write the frame # at the last 4 bytes of the frame */ p += size - 4; memcpy(p, &cx->vbi.frame, 4); cx->vbi.frame++; return; } /* Sliced VBI data with data insertion */ pts = (be32_to_cpu(hdr->magic) == 0x3fffffff) ? be32_to_cpu(hdr->pts) : 0; lines = compress_sliced_buf(cx, p, size, sizeof(struct vbi_data_hdr)); /* always return at least one empty line */ if (lines == 0) { cx->vbi.sliced_data[0].id = 0; cx->vbi.sliced_data[0].line = 0; cx->vbi.sliced_data[0].field = 0; lines = 1; } buf->bytesused = size = lines * sizeof(cx->vbi.sliced_data[0]); memcpy(p, &cx->vbi.sliced_data[0], size); if (cx->vbi.insert_mpeg) copy_vbi_data(cx, lines, pts); cx->vbi.frame++; } void cx18_process_vbi_data(struct cx18 *cx, struct cx18_mdl *mdl, int streamtype) { struct cx18_buffer *buf; u32 orig_used; if (streamtype != CX18_ENC_STREAM_TYPE_VBI) return; /* * Big assumption here: * Every buffer hooked to the MDL's buf_list is a complete VBI frame * that ends at the end of the buffer. * * To assume anything else would make the code in this file * more complex, or require extra memcpy()'s to make the * buffers satisfy the above assumption. It's just simpler to set * up the encoder buffer transfers to make the assumption true. */ list_for_each_entry(buf, &mdl->buf_list, list) { orig_used = buf->bytesused; if (orig_used == 0) break; _cx18_process_vbi_data(cx, buf); mdl->bytesused -= (orig_used - buf->bytesused); } }