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/* SPDX-License-Identifier: LGPL-2.1-or-later */
/*
* Copyright (C) 2022, Tomi Valkeinen <tomi.valkeinen@ideasonboard.com>
*
* Python bindings
*/
#include "py_main.h"
#include <memory>
#include <stdexcept>
#include <string>
#include <vector>
#include <libcamera/base/log.h>
#include <libcamera/libcamera.h>
#include <pybind11/functional.h>
#include <pybind11/pybind11.h>
#include <pybind11/stl.h>
#include <pybind11/stl_bind.h>
#include "py_camera_manager.h"
#include "py_helpers.h"
namespace py = pybind11;
using namespace libcamera;
namespace libcamera {
LOG_DEFINE_CATEGORY(Python)
}
/*
* This is a holder class used only for the Camera class, for the sole purpose
* of avoiding the compilation issue with Camera's private destructor.
*
* pybind11 requires a public destructor for classes held with shared_ptrs, even
* in cases where the public destructor is not strictly needed. The current
* understanding is that there are the following options to solve the problem:
*
* - Use pybind11 'smart_holder' branch. The downside is that 'smart_holder'
* is not the mainline branch, and not available in distributions.
* - https://github.com/pybind/pybind11/pull/2067
* - Make the Camera destructor public
* - Something like the PyCameraSmartPtr here, which adds a layer, hiding the
* issue.
*/
template<typename T>
class PyCameraSmartPtr
{
public:
using element_type = T;
PyCameraSmartPtr()
{
}
explicit PyCameraSmartPtr(T *)
{
throw std::runtime_error("invalid SmartPtr constructor call");
}
explicit PyCameraSmartPtr(std::shared_ptr<T> p)
: ptr_(p)
{
}
T *get() const { return ptr_.get(); }
operator std::shared_ptr<T>() const { return ptr_; }
private:
std::shared_ptr<T> ptr_;
};
PYBIND11_DECLARE_HOLDER_TYPE(T, PyCameraSmartPtr<T>)
/*
* Note: global C++ destructors can be ran on this before the py module is
* destructed.
*/
static std::weak_ptr<PyCameraManager> gCameraManager;
void init_py_color_space(py::module &m);
void init_py_controls_generated(py::module &m);
void init_py_enums(py::module &m);
void init_py_formats_generated(py::module &m);
void init_py_geometry(py::module &m);
void init_py_properties_generated(py::module &m);
void init_py_transform(py::module &m);
PYBIND11_MODULE(_libcamera, m)
{
init_py_enums(m);
init_py_controls_generated(m);
init_py_geometry(m);
init_py_properties_generated(m);
init_py_color_space(m);
init_py_transform(m);
/* Forward declarations */
/*
* We need to declare all the classes here so that Python docstrings
* can be generated correctly.
* https://pybind11.readthedocs.io/en/latest/advanced/misc.html#avoiding-c-types-in-docstrings
*/
auto pyCameraManager = py::class_<PyCameraManager, std::shared_ptr<PyCameraManager>>(m, "CameraManager");
auto pyCamera = py::class_<Camera, PyCameraSmartPtr<Camera>>(m, "Camera");
auto pySensorConfiguration = py::class_<SensorConfiguration>(m, "SensorConfiguration");
auto pyCameraConfiguration = py::class_<CameraConfiguration>(m, "CameraConfiguration");
auto pyCameraConfigurationStatus = py::enum_<CameraConfiguration::Status>(pyCameraConfiguration, "Status");
auto pyStreamConfiguration = py::class_<StreamConfiguration>(m, "StreamConfiguration");
auto pyStreamFormats = py::class_<StreamFormats>(m, "StreamFormats");
auto pyFrameBufferAllocator = py::class_<FrameBufferAllocator>(m, "FrameBufferAllocator");
auto pyFrameBuffer = py::class_<FrameBuffer>(m, "FrameBuffer");
auto pyFrameBufferPlane = py::class_<FrameBuffer::Plane>(pyFrameBuffer, "Plane");
auto pyStream = py::class_<Stream>(m, "Stream");
auto pyControlId = py::class_<ControlId>(m, "ControlId");
auto pyControlInfo = py::class_<ControlInfo>(m, "ControlInfo");
auto pyRequest = py::class_<Request>(m, "Request");
auto pyRequestStatus = py::enum_<Request::Status>(pyRequest, "Status");
auto pyRequestReuse = py::enum_<Request::ReuseFlag>(pyRequest, "Reuse");
auto pyFrameMetadata = py::class_<FrameMetadata>(m, "FrameMetadata");
auto pyFrameMetadataStatus = py::enum_<FrameMetadata::Status>(pyFrameMetadata, "Status");
auto pyFrameMetadataPlane = py::class_<FrameMetadata::Plane>(pyFrameMetadata, "Plane");
auto pyPixelFormat = py::class_<PixelFormat>(m, "PixelFormat");
init_py_formats_generated(m);
/* Global functions */
m.def("log_set_level", &logSetLevel);
/* Classes */
pyCameraManager
.def_static("singleton", []() {
std::shared_ptr<PyCameraManager> cm = gCameraManager.lock();
if (!cm) {
cm = std::make_shared<PyCameraManager>();
gCameraManager = cm;
}
return cm;
})
.def_property_readonly_static("version", [](py::object /* self */) { return PyCameraManager::version(); })
.def("get", &PyCameraManager::get, py::keep_alive<0, 1>())
.def_property_readonly("cameras", &PyCameraManager::cameras)
.def_property_readonly("event_fd", &PyCameraManager::eventFd)
.def("get_ready_requests", &PyCameraManager::getReadyRequests);
pyCamera
.def_property_readonly("id", &Camera::id)
.def("acquire", [](Camera &self) {
int ret = self.acquire();
if (ret)
throw std::system_error(-ret, std::generic_category(),
"Failed to acquire camera");
})
.def("release", [](Camera &self) {
int ret = self.release();
if (ret)
throw std::system_error(-ret, std::generic_category(),
"Failed to release camera");
})
.def("start", [](Camera &self,
const std::unordered_map<const ControlId *, py::object> &controls) {
/* \todo What happens if someone calls start() multiple times? */
auto cm = gCameraManager.lock();
ASSERT(cm);
self.requestCompleted.connect(cm.get(), &PyCameraManager::handleRequestCompleted);
ControlList controlList(self.controls());
for (const auto &[id, obj] : controls) {
auto val = pyToControlValue(obj, id->type());
controlList.set(id->id(), val);
}
int ret = self.start(&controlList);
if (ret) {
self.requestCompleted.disconnect();
throw std::system_error(-ret, std::generic_category(),
"Failed to start camera");
}
}, py::arg("controls") = std::unordered_map<const ControlId *, py::object>())
.def("stop", [](Camera &self) {
int ret = self.stop();
self.requestCompleted.disconnect();
if (ret)
throw std::system_error(-ret, std::generic_category(),
"Failed to stop camera");
})
.def("__str__", [](Camera &self) {
return "<libcamera.Camera '" + self.id() + "'>";
})
/* Keep the camera alive, as StreamConfiguration contains a Stream* */
.def("generate_configuration", [](Camera &self, const std::vector<StreamRole> &roles) {
return self.generateConfiguration(roles);
}, py::keep_alive<0, 1>())
.def("configure", [](Camera &self, CameraConfiguration *config) {
int ret = self.configure(config);
if (ret)
throw std::system_error(-ret, std::generic_category(),
"Failed to configure camera");
})
.def("create_request", [](Camera &self, uint64_t cookie) {
std::unique_ptr<Request> req = self.createRequest(cookie);
if (!req)
throw std::system_error(ENOMEM, std::generic_category(),
"Failed to create request");
return req;
}, py::arg("cookie") = 0)
.def("queue_request", [](Camera &self, Request *req) {
py::object py_req = py::cast(req);
/*
* Increase the reference count, will be dropped in
* CameraManager.get_ready_requests().
*/
py_req.inc_ref();
int ret = self.queueRequest(req);
if (ret) {
py_req.dec_ref();
throw std::system_error(-ret, std::generic_category(),
"Failed to queue request");
}
})
.def_property_readonly("streams", [](Camera &self) {
py::set set;
for (auto &s : self.streams()) {
py::object py_self = py::cast(self);
py::object py_s = py::cast(s);
py::detail::keep_alive_impl(py_s, py_self);
set.add(py_s);
}
return set;
})
.def_property_readonly("controls", [](Camera &self) {
/* Convert ControlInfoMap to std container */
std::unordered_map<const ControlId *, ControlInfo> ret;
for (const auto &[k, cv] : self.controls())
ret[k] = cv;
return ret;
})
.def_property_readonly("properties", [](Camera &self) {
/* Convert ControlList to std container */
std::unordered_map<const ControlId *, py::object> ret;
for (const auto &[k, cv] : self.properties()) {
const ControlId *id = properties::properties.at(k);
py::object ob = controlValueToPy(cv);
ret[id] = ob;
}
return ret;
});
pySensorConfiguration
.def(py::init<>())
.def_readwrite("bit_depth", &SensorConfiguration::bitDepth)
.def_readwrite("analog_crop", &SensorConfiguration::analogCrop)
.def_property(
"binning",
[](SensorConfiguration &self) {
return py::make_tuple(self.binning.binX, self.binning.binY);
},
[](SensorConfiguration &self, py::object value) {
auto vec = value.cast<std::vector<unsigned int>>();
if (vec.size() != 2)
throw std::runtime_error("binning requires iterable of 2 values");
self.binning.binX = vec[0];
self.binning.binY = vec[1];
})
.def_property(
"skipping",
[](SensorConfiguration &self) {
return py::make_tuple(self.skipping.xOddInc, self.skipping.xEvenInc,
self.skipping.yOddInc, self.skipping.yEvenInc);
},
[](SensorConfiguration &self, py::object value) {
auto vec = value.cast<std::vector<unsigned int>>();
if (vec.size() != 4)
throw std::runtime_error("skipping requires iterable of 4 values");
self.skipping.xOddInc = vec[0];
self.skipping.xEvenInc = vec[1];
self.skipping.yOddInc = vec[2];
self.skipping.yEvenInc = vec[3];
})
.def_readwrite("output_size", &SensorConfiguration::outputSize)
.def("is_valid", &SensorConfiguration::isValid);
pyCameraConfiguration
.def("__iter__", [](CameraConfiguration &self) {
return py::make_iterator<py::return_value_policy::reference_internal>(self);
}, py::keep_alive<0, 1>())
.def("__len__", [](CameraConfiguration &self) {
return self.size();
})
.def("validate", &CameraConfiguration::validate)
.def("at", py::overload_cast<unsigned int>(&CameraConfiguration::at),
py::return_value_policy::reference_internal)
.def_property_readonly("size", &CameraConfiguration::size)
.def_property_readonly("empty", &CameraConfiguration::empty)
.def_readwrite("sensor_config", &CameraConfiguration::sensorConfig)
.def_readwrite("transform", &CameraConfiguration::transform);
pyCameraConfigurationStatus
.value("Valid", CameraConfiguration::Valid)
.value("Adjusted", CameraConfiguration::Adjusted)
.value("Invalid", CameraConfiguration::Invalid);
pyStreamConfiguration
.def("__str__", &StreamConfiguration::toString)
.def_property_readonly("stream", &StreamConfiguration::stream,
py::return_value_policy::reference_internal)
.def_readwrite("size", &StreamConfiguration::size)
.def_readwrite("pixel_format", &StreamConfiguration::pixelFormat)
.def_readwrite("stride", &StreamConfiguration::stride)
.def_readwrite("frame_size", &StreamConfiguration::frameSize)
.def_readwrite("buffer_count", &StreamConfiguration::bufferCount)
.def_property_readonly("formats", &StreamConfiguration::formats,
py::return_value_policy::reference_internal)
.def_readwrite("color_space", &StreamConfiguration::colorSpace);
pyStreamFormats
.def_property_readonly("pixel_formats", &StreamFormats::pixelformats)
.def("sizes", &StreamFormats::sizes)
.def("range", &StreamFormats::range);
pyFrameBufferAllocator
.def(py::init<PyCameraSmartPtr<Camera>>(), py::keep_alive<1, 2>())
.def("allocate", [](FrameBufferAllocator &self, Stream *stream) {
int ret = self.allocate(stream);
if (ret < 0)
throw std::system_error(-ret, std::generic_category(),
"Failed to allocate buffers");
return ret;
})
.def_property_readonly("allocated", &FrameBufferAllocator::allocated)
/* Create a list of FrameBuffers, where each FrameBuffer has a keep-alive to FrameBufferAllocator */
.def("buffers", [](FrameBufferAllocator &self, Stream *stream) {
py::object py_self = py::cast(self);
py::list l;
for (auto &ub : self.buffers(stream)) {
py::object py_buf = py::cast(ub.get(), py::return_value_policy::reference_internal, py_self);
l.append(py_buf);
}
return l;
});
pyFrameBuffer
.def(py::init<std::vector<FrameBuffer::Plane>, unsigned int>(),
py::arg("planes"), py::arg("cookie") = 0)
.def_property_readonly("metadata", &FrameBuffer::metadata, py::return_value_policy::reference_internal)
.def_property_readonly("planes", &FrameBuffer::planes)
.def_property("cookie", &FrameBuffer::cookie, &FrameBuffer::setCookie);
pyFrameBufferPlane
.def(py::init())
.def(py::init([](int fd, unsigned int offset, unsigned int length) {
auto p = FrameBuffer::Plane();
p.fd = SharedFD(fd);
p.offset = offset;
p.length = length;
return p;
}), py::arg("fd"), py::arg("offset"), py::arg("length"))
.def_property("fd",
[](const FrameBuffer::Plane &self) {
return self.fd.get();
},
[](FrameBuffer::Plane &self, int fd) {
self.fd = SharedFD(fd);
})
.def_readwrite("offset", &FrameBuffer::Plane::offset)
.def_readwrite("length", &FrameBuffer::Plane::length);
pyStream
.def_property_readonly("configuration", &Stream::configuration);
pyControlId
.def_property_readonly("id", &ControlId::id)
.def_property_readonly("name", &ControlId::name)
.def_property_readonly("type", &ControlId::type)
.def("__str__", [](const ControlId &self) { return self.name(); })
.def("__repr__", [](const ControlId &self) {
return py::str("libcamera.ControlId({}, {}, {})")
.format(self.id(), self.name(), self.type());
});
pyControlInfo
.def_property_readonly("min", [](const ControlInfo &self) {
return controlValueToPy(self.min());
})
.def_property_readonly("max", [](const ControlInfo &self) {
return controlValueToPy(self.max());
})
.def_property_readonly("default", [](const ControlInfo &self) {
return controlValueToPy(self.def());
})
.def_property_readonly("values", [](const ControlInfo &self) {
py::list l;
for (const auto &v : self.values())
l.append(controlValueToPy(v));
return l;
})
.def("__str__", &ControlInfo::toString)
.def("__repr__", [](const ControlInfo &self) {
return py::str("libcamera.ControlInfo({})")
.format(self.toString());
});
pyRequest
/* \todo Fence is not supported, so we cannot expose addBuffer() directly */
.def("add_buffer", [](Request &self, const Stream *stream, FrameBuffer *buffer) {
int ret = self.addBuffer(stream, buffer);
if (ret)
throw std::system_error(-ret, std::generic_category(),
"Failed to add buffer");
}, py::keep_alive<1, 3>()) /* Request keeps Framebuffer alive */
.def_property_readonly("status", &Request::status)
.def_property_readonly("buffers", &Request::buffers)
.def_property_readonly("cookie", &Request::cookie)
.def_property_readonly("sequence", &Request::sequence)
.def_property_readonly("has_pending_buffers", &Request::hasPendingBuffers)
.def("set_control", [](Request &self, const ControlId &id, py::object value) {
self.controls().set(id.id(), pyToControlValue(value, id.type()));
})
.def_property_readonly("metadata", [](Request &self) {
/* Convert ControlList to std container */
std::unordered_map<const ControlId *, py::object> ret;
for (const auto &[key, cv] : self.metadata()) {
const ControlId *id = controls::controls.at(key);
py::object ob = controlValueToPy(cv);
ret[id] = ob;
}
return ret;
})
/*
* \todo As we add a keep_alive to the fb in addBuffers(), we
* can only allow reuse with ReuseBuffers.
*/
.def("reuse", [](Request &self) { self.reuse(Request::ReuseFlag::ReuseBuffers); })
.def("__str__", &Request::toString);
pyRequestStatus
.value("Pending", Request::RequestPending)
.value("Complete", Request::RequestComplete)
.value("Cancelled", Request::RequestCancelled);
pyRequestReuse
.value("Default", Request::ReuseFlag::Default)
.value("ReuseBuffers", Request::ReuseFlag::ReuseBuffers);
pyFrameMetadata
.def_readonly("status", &FrameMetadata::status)
.def_readonly("sequence", &FrameMetadata::sequence)
.def_readonly("timestamp", &FrameMetadata::timestamp)
.def_property_readonly("planes", [](const FrameMetadata &self) {
/* Convert from Span<> to std::vector<> */
/* Note: this creates a copy */
std::vector<FrameMetadata::Plane> v(self.planes().begin(), self.planes().end());
return v;
});
pyFrameMetadataStatus
.value("Success", FrameMetadata::FrameSuccess)
.value("Error", FrameMetadata::FrameError)
.value("Cancelled", FrameMetadata::FrameCancelled);
pyFrameMetadataPlane
.def_readwrite("bytes_used", &FrameMetadata::Plane::bytesused);
pyPixelFormat
.def(py::init<>())
.def(py::init<uint32_t, uint64_t>())
.def(py::init<>([](const std::string &str) {
return PixelFormat::fromString(str);
}))
.def_property_readonly("fourcc", &PixelFormat::fourcc)
.def_property_readonly("modifier", &PixelFormat::modifier)
.def(py::self == py::self)
.def("__str__", &PixelFormat::toString)
.def("__repr__", [](const PixelFormat &self) {
return "libcamera.PixelFormat('" + self.toString() + "')";
});
}
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