#include <memory>
#include <mutex>
#include <stack>
+#include <string>
#include <thread>
using namespace std;
using namespace std::placeholders;
-#define WIDTH 1280
-#define HEIGHT 750 /* 30 lines ancillary data? */
-//#define WIDTH 1920
-//#define HEIGHT 1125 /* ??? lines ancillary data? */
+#define MIN_WIDTH 640
#define HEADER_SIZE 44
//#define HEADER_SIZE 0
#define AUDIO_HEADER_SIZE 4
-//#define FRAME_SIZE (WIDTH * HEIGHT * 2 + HEADER_SIZE) // UYVY
-//#define FRAME_SIZE (WIDTH * HEIGHT * 2 * 4 / 3 + HEADER_SIZE) // v210
-#define FRAME_SIZE (8 << 20)
+#define FRAME_SIZE (8 << 20) // 8 MB.
+#define USB_VIDEO_TRANSFER_SIZE (128 << 10) // 128 kB.
+
+namespace {
FILE *audiofp;
thread usb_thread;
atomic<bool> should_quit;
-FrameAllocator::~FrameAllocator() {}
-
-// Audio is more important than video, and also much cheaper.
-// By having many more audio frames available, hopefully if something
-// starts to drop, we'll have CPU load go down (from not having to
-// process as much video) before we have to drop audio.
-#define NUM_QUEUED_VIDEO_FRAMES 16
-#define NUM_QUEUED_AUDIO_FRAMES 64
+int find_xfer_size_for_width(int width)
+{
+ // Video seems to require isochronous packets scaled with the width;
+ // seemingly six lines is about right, rounded up to the required 1kB
+ // multiple.
+ int size = width * 2 * 6;
+ // Note that for 10-bit input, you'll need to increase size accordingly.
+ //size = size * 4 / 3;
+ if (size % 1024 != 0) {
+ size &= ~1023;
+ size += 1024;
+ }
+ return size;
+}
-class MallocFrameAllocator : public FrameAllocator {
-public:
- MallocFrameAllocator(size_t frame_size, size_t num_queued_frames);
- Frame alloc_frame() override;
- void release_frame(Frame frame) override;
+void change_xfer_size_for_width(int width, libusb_transfer *xfr)
+{
+ assert(width >= MIN_WIDTH);
+ size_t size = find_xfer_size_for_width(width);
+ int num_iso_pack = xfr->length / size;
+ if (num_iso_pack != xfr->num_iso_packets ||
+ size != xfr->iso_packet_desc[0].length) {
+ xfr->num_iso_packets = num_iso_pack;
+ libusb_set_iso_packet_lengths(xfr, size);
+ }
+}
-private:
- size_t frame_size;
+} // namespace
- mutex freelist_mutex;
- stack<unique_ptr<uint8_t[]>> freelist; // All of size <frame_size>.
-};
+FrameAllocator::~FrameAllocator() {}
MallocFrameAllocator::MallocFrameAllocator(size_t frame_size, size_t num_queued_frames)
: frame_size(frame_size)
uint16_t video_timecode = pending_video_frames.front().timecode;
uint16_t audio_timecode = pending_audio_frames.front().timecode;
+ AudioFormat audio_format;
+ audio_format.bits_per_sample = 24;
+ audio_format.num_channels = 8;
if (uint16_less_than_with_wraparound(video_timecode, audio_timecode)) {
printf("Video block 0x%04x without corresponding audio block, dropping.\n",
video_timecode);
- video_frame_allocator->release_frame(pending_video_frames.front().frame);
+ QueuedFrame video_frame = pending_video_frames.front();
pending_video_frames.pop_front();
+ lock.unlock();
+ video_frame_allocator->release_frame(video_frame.frame);
} else if (uint16_less_than_with_wraparound(audio_timecode, video_timecode)) {
printf("Audio block 0x%04x without corresponding video block, sending blank frame.\n",
audio_timecode);
QueuedFrame audio_frame = pending_audio_frames.front();
pending_audio_frames.pop_front();
lock.unlock();
+ audio_format.id = audio_frame.format;
frame_callback(audio_timecode,
- FrameAllocator::Frame(), 0, 0x0000,
- audio_frame.frame, AUDIO_HEADER_SIZE, audio_frame.format);
+ FrameAllocator::Frame(), 0, VideoFormat(),
+ audio_frame.frame, AUDIO_HEADER_SIZE, audio_format);
} else {
QueuedFrame video_frame = pending_video_frames.front();
QueuedFrame audio_frame = pending_audio_frames.front();
dump_audio_block(audio_frame.frame.data, audio_frame.data_len);
#endif
- frame_callback(video_timecode,
- video_frame.frame, HEADER_SIZE, video_frame.format,
- audio_frame.frame, AUDIO_HEADER_SIZE, audio_frame.format);
+ VideoFormat video_format;
+ audio_format.id = audio_frame.format;
+ if (decode_video_format(video_frame.format, &video_format)) {
+ frame_callback(video_timecode,
+ video_frame.frame, HEADER_SIZE, video_format,
+ audio_frame.frame, AUDIO_HEADER_SIZE, audio_format);
+ } else {
+ frame_callback(video_timecode,
+ FrameAllocator::Frame(), 0, video_format,
+ audio_frame.frame, AUDIO_HEADER_SIZE, audio_format);
+ }
}
}
if (has_dequeue_callbacks) {
}
//dump_frame();
queue_frame(format, timecode, current_video_frame, &pending_video_frames);
+
+ // Update the assumed frame width. We might be one frame too late on format changes,
+ // but it's much better than asking the user to choose manually.
+ VideoFormat video_format;
+ if (decode_video_format(format, &video_format)) {
+ assumed_frame_width = video_format.width;
+ }
}
//printf("Found frame start, format 0x%04x timecode 0x%04x, previous frame length was %d/%d\n",
// format, timecode,
decode_packs(xfr, "DeckLinkAudioResyncT", 20, &usb->current_audio_frame, "audio", bind(&BMUSBCapture::start_new_audio_block, usb, _1));
} else {
decode_packs(xfr, "\x00\x00\xff\xff", 4, &usb->current_video_frame, "video", bind(&BMUSBCapture::start_new_frame, usb, _1));
+
+ // Update the transfer with the new assumed width, if we're in the process of changing formats.
+ change_xfer_size_for_width(usb->assumed_frame_width, xfr);
}
}
if (xfr->type == LIBUSB_TRANSFER_TYPE_CONTROL) {
libusb_device *device;
};
-libusb_device_handle *open_card(int card_index)
+libusb_device_handle *open_card(int card_index, string *description)
{
libusb_device **devices;
ssize_t num_devices = libusb_get_device_list(nullptr, &devices);
});
for (size_t i = 0; i < found_cards.size(); ++i) {
- fprintf(stderr, "Card %d: Bus %03u Device %03u ", int(i), found_cards[i].bus, found_cards[i].port);
+ const char *product_name = nullptr;
if (found_cards[i].product == 0xbd3b) {
- fprintf(stderr, "Intensity Shuttle\n");
+ product_name = "Intensity Shuttle";
} else if (found_cards[i].product == 0xbd4f) {
- fprintf(stderr, "UltraStudio SDI\n");
+ product_name = "UltraStudio SDI";
} else {
assert(false);
}
+
+ char buf[256];
+ snprintf(buf, sizeof(buf), "Card %d: Bus %03u Device %03u %s",
+ int(i), found_cards[i].bus, found_cards[i].port, product_name);
+ if (i == size_t(card_index)) {
+ *description = buf;
+ }
+ fprintf(stderr, "%s\n", buf);
}
if (size_t(card_index) >= found_cards.size()) {
exit(1);
}
- libusb_device_handle *devh = open_card(card_index);
+ libusb_device_handle *devh = open_card(card_index, &description);
if (!devh) {
fprintf(stderr, "Error finding USB device\n");
exit(1);
fprintf(stderr, "Error getting configuration: %s\n", libusb_error_name(rc));
exit(1);
}
+
+#if 0
printf("%d interface\n", config->bNumInterfaces);
for (int interface_number = 0; interface_number < config->bNumInterfaces; ++interface_number) {
printf(" interface %d\n", interface_number);
}
}
}
+#endif
rc = libusb_set_configuration(devh, /*configuration=*/1);
if (rc < 0) {
fprintf(stderr, "Error on control %d: %s\n", ctrls[req].index, libusb_error_name(rc));
exit(1);
}
-
+
+ if (ctrls[req].index == 16 && rc == 4) {
+ printf("Card firmware version: 0x%02x%02x\n", value[2], value[3]);
+ }
+
+#if 0
printf("rc=%d: ep=%d@%d %d -> 0x", rc, ctrls[req].endpoint, ctrls[req].request, ctrls[req].index);
for (int i = 0; i < rc; ++i) {
printf("%02x", value[i]);
}
printf("\n");
+#endif
}
#if 0
//int num_transfers = (e == 3) ? 6 : 6;
int num_transfers = 10;
for (int i = 0; i < num_transfers; ++i) {
+ size_t buf_size;
int num_iso_pack, size;
if (e == 3) {
- // Video seems to require isochronous packets scaled with the width;
- // seemingly six lines is about right, rounded up to the required 1kB
- // multiple.
- size = WIDTH * 2 * 6;
- // Note that for 10-bit input, you'll need to increase size accordingly.
- //size = size * 4 / 3;
- if (size % 1024 != 0) {
- size &= ~1023;
- size += 1024;
- }
- num_iso_pack = (2 << 16) / size; // 128 kB.
- printf("Picking %d packets of 0x%x bytes each\n", num_iso_pack, size);
+ // Allocate for minimum width (because that will give us the most
+ // number of packets, so we don't need to reallocated, but we'll
+ // default to 720p for the first frame.
+ size = find_xfer_size_for_width(MIN_WIDTH);
+ num_iso_pack = USB_VIDEO_TRANSFER_SIZE / size;
+ buf_size = USB_VIDEO_TRANSFER_SIZE;
} else {
size = 0xc0;
num_iso_pack = 80;
+ buf_size = num_iso_pack * size;
}
- int num_bytes = num_iso_pack * size;
- uint8_t *buf = new uint8_t[num_bytes];
+ assert(size_t(num_iso_pack * size) <= buf_size);
+ uint8_t *buf = new uint8_t[buf_size];
xfr = libusb_alloc_transfer(num_iso_pack);
if (!xfr) {
}
int ep = LIBUSB_ENDPOINT_IN | e;
- libusb_fill_iso_transfer(xfr, devh, ep, buf, num_bytes,
+ libusb_fill_iso_transfer(xfr, devh, ep, buf, buf_size,
num_iso_pack, cb_xfr, nullptr, 0);
libusb_set_iso_packet_lengths(xfr, size);
xfr->user_data = this;
+
+ if (e == 3) {
+ change_xfer_size_for_width(assumed_frame_width, xfr);
+ }
+
iso_xfrs.push_back(xfr);
}
}
void BMUSBCapture::start_bm_capture()
{
- printf("starting capture\n");
int i = 0;
for (libusb_transfer *xfr : iso_xfrs) {
- printf("submitting transfer...\n");
int rc = libusb_submit_transfer(xfr);
++i;
if (rc < 0) {
should_quit = true;
usb_thread.join();
}
+
+struct VideoFormatEntry {
+ uint16_t normalized_video_format;
+ unsigned width, height, second_field_start;
+ unsigned extra_lines_top, extra_lines_bottom;
+ unsigned frame_rate_nom, frame_rate_den;
+ bool interlaced;
+};
+
+bool decode_video_format(uint16_t video_format, VideoFormat *decoded_video_format)
+{
+ decoded_video_format->id = video_format;
+ decoded_video_format->interlaced = false;
+
+ // TODO: Add these for all formats as we find them.
+ decoded_video_format->extra_lines_top = decoded_video_format->extra_lines_bottom = decoded_video_format->second_field_start = 0;
+
+ if (video_format == 0x0800) {
+ // No video signal. These green pseudo-frames seem to come at about 30.13 Hz.
+ // It's a strange thing, but what can you do.
+ decoded_video_format->width = 720;
+ decoded_video_format->height = 525;
+ decoded_video_format->extra_lines_top = 0;
+ decoded_video_format->extra_lines_bottom = 0;
+ decoded_video_format->frame_rate_nom = 3013;
+ decoded_video_format->frame_rate_den = 100;
+ decoded_video_format->has_signal = false;
+ return true;
+ }
+ if ((video_format & 0xe800) != 0xe800) {
+ printf("Video format 0x%04x does not appear to be a video format. Assuming 60 Hz.\n",
+ video_format);
+ decoded_video_format->width = 0;
+ decoded_video_format->height = 0;
+ decoded_video_format->extra_lines_top = 0;
+ decoded_video_format->extra_lines_bottom = 0;
+ decoded_video_format->frame_rate_nom = 60;
+ decoded_video_format->frame_rate_den = 1;
+ decoded_video_format->has_signal = false;
+ return false;
+ }
+
+ decoded_video_format->has_signal = true;
+
+ // NTSC (480i59.94, I suppose). A special case, see below.
+ if (video_format == 0xe901 || video_format == 0xe9c1 || video_format == 0xe801) {
+ decoded_video_format->width = 720;
+ decoded_video_format->height = 480;
+ decoded_video_format->extra_lines_top = 17;
+ decoded_video_format->extra_lines_bottom = 28;
+ decoded_video_format->frame_rate_nom = 30000;
+ decoded_video_format->frame_rate_den = 1001;
+ decoded_video_format->second_field_start = 280;
+ decoded_video_format->interlaced = true;
+ return true;
+ }
+
+ // PAL (576i50, I suppose). A special case, see below.
+ if (video_format == 0xe909 || video_format == 0xe9c9 || video_format == 0xe809 || video_format == 0xebe9 || video_format == 0xebe1) {
+ decoded_video_format->width = 720;
+ decoded_video_format->height = 576;
+ decoded_video_format->extra_lines_top = 22;
+ decoded_video_format->extra_lines_bottom = 27;
+ decoded_video_format->frame_rate_nom = 25;
+ decoded_video_format->frame_rate_den = 1;
+ decoded_video_format->second_field_start = 335;
+ decoded_video_format->interlaced = true;
+ return true;
+ }
+
+ // 0x8 seems to be a flag about availability of deep color on the input,
+ // except when it's not (e.g. it's the only difference between NTSC
+ // and PAL). Rather confusing. But we clear it here nevertheless, because
+ // usually it doesn't mean anything.
+ //
+ // 0x4 is a flag I've only seen from the D4. I don't know what it is.
+ uint16_t normalized_video_format = video_format & ~0xe80c;
+ constexpr VideoFormatEntry entries[] = {
+ { 0x01f1, 720, 480, 0, 40, 5, 60000, 1001, false }, // 480p59.94 (believed).
+ { 0x0131, 720, 576, 0, 44, 5, 50, 1, false }, // 576p50.
+ { 0x0011, 720, 576, 0, 44, 5, 50, 1, false }, // 576p50 (5:4).
+ { 0x0143, 1280, 720, 0, 25, 5, 50, 1, false }, // 720p50.
+ { 0x0103, 1280, 720, 0, 25, 5, 60, 1, false }, // 720p60.
+ { 0x0125, 1280, 720, 0, 25, 5, 60, 1, false }, // 720p60.
+ { 0x0121, 1280, 720, 0, 25, 5, 60000, 1001, false }, // 720p59.94.
+ { 0x01c3, 1920, 1080, 0, 0, 0, 30, 1, false }, // 1080p30.
+ { 0x0003, 1920, 1080, 583, 20, 25, 30, 1, true }, // 1080i60.
+ { 0x01e1, 1920, 1080, 0, 0, 0, 30000, 1001, false }, // 1080p29.97.
+ { 0x0021, 1920, 1080, 583, 20, 25, 30000, 1001, true }, // 1080i59.94.
+ { 0x0063, 1920, 1080, 0, 0, 0, 25, 1, false }, // 1080p25.
+ { 0x0043, 1920, 1080, 0, 0, 0, 25, 1, true }, // 1080p50.
+ { 0x008e, 1920, 1080, 0, 0, 0, 24, 1, false }, // 1080p24.
+ { 0x00a1, 1920, 1080, 0, 0, 0, 24000, 1001, false }, // 1080p23.98.
+ };
+ for (const VideoFormatEntry &entry : entries) {
+ if (normalized_video_format == entry.normalized_video_format) {
+ decoded_video_format->width = entry.width;
+ decoded_video_format->height = entry.height;
+ decoded_video_format->second_field_start = entry.second_field_start;
+ decoded_video_format->extra_lines_top = entry.extra_lines_top;
+ decoded_video_format->extra_lines_bottom = entry.extra_lines_bottom;
+ decoded_video_format->frame_rate_nom = entry.frame_rate_nom;
+ decoded_video_format->frame_rate_den = entry.frame_rate_den;
+ decoded_video_format->interlaced = entry.interlaced;
+ return true;
+ }
+ }
+
+ printf("Unknown video format 0x%04x (normalized 0x%04x). Assuming 720p60.\n", video_format, normalized_video_format);
+ decoded_video_format->width = 1280;
+ decoded_video_format->height = 720;
+ decoded_video_format->frame_rate_nom = 60;
+ decoded_video_format->frame_rate_den = 1;
+ return false;
+}