429 lines
16 KiB
OpenEdge ABL
429 lines
16 KiB
OpenEdge ABL
/*
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* This file is part of the libsigrok project.
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*
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* Copyright (C) 2016 Aurelien Jacobs <aurel@gnuage.org>
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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%define DOCSTRING
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"
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= Introduction
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The sigrok Ruby API provides an object-oriented Ruby interface to the
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functionality in libsigrok. It is built on top of the libsigrokcxx C++ API.
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= Getting started
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Usage of the sigrok Ruby API needs to begin with a call to Context.create().
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This will create the global libsigrok context and returns a Context object.
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Methods on this object provide access to the hardware drivers, input and output
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formats supported by the library, as well as means of creating other objects
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such as sessions and triggers.
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= Error handling
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When any libsigrok C API call returns an error, an Error exception is raised,
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which provides access to the error code and description."
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%enddef
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%module(docstring=DOCSTRING) sigrok
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%{
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#include <stdio.h>
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#include <glibmm.h>
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#include "config.h"
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%}
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%include "../swig/templates.i"
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%{
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static const char *string_from_ruby(VALUE obj)
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{
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switch (TYPE(obj)) {
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case T_STRING:
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return StringValueCStr(obj);
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case T_SYMBOL:
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return rb_id2name(SYM2ID(obj));
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default:
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throw sigrok::Error(SR_ERR_ARG);
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}
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}
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/* Convert from Glib::Variant to native Ruby types. */
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static VALUE variant_to_ruby(Glib::VariantBase variant)
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{
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if (variant.is_of_type(Glib::VARIANT_TYPE_BOOL)) {
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return Glib::VariantBase::cast_dynamic< Glib::Variant<bool> >(variant).get() ? Qtrue : Qfalse;
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_BYTE)) {
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return UINT2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<unsigned char> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_INT16)) {
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return INT2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<gint16> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_UINT16)) {
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return UINT2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<guint16> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_INT32)) {
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return INT2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<gint32> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_UINT32)) {
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return UINT2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<guint32> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_INT64)) {
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return LL2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<gint64> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_UINT64)) {
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return ULL2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<guint64> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_DOUBLE)) {
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return DBL2NUM(Glib::VariantBase::cast_dynamic< Glib::Variant<double> >(variant).get());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_STRING)) {
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auto str = Glib::VariantBase::cast_dynamic< Glib::Variant<std::string> >(variant).get();
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return rb_str_new(str.c_str(), str.length());
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} else if (variant.is_of_type(Glib::VARIANT_TYPE_VARIANT)) {
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auto var = Glib::VariantBase::cast_dynamic< Glib::Variant<Glib::VariantBase> >(variant).get();
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return variant_to_ruby(var);
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} else if (variant.is_container()) {
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Glib::VariantContainerBase container = Glib::VariantBase::cast_dynamic< Glib::VariantContainerBase > (variant);
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gsize count = container.get_n_children();
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if (container.is_of_type(Glib::VARIANT_TYPE_DICTIONARY)) {
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VALUE hash = rb_hash_new();
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for (gsize i = 0; i < count; i++) {
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Glib::VariantContainerBase entry = Glib::VariantBase::cast_dynamic< Glib::VariantContainerBase > (container.get_child(i));
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VALUE key = variant_to_ruby(entry.get_child(0));
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VALUE val = variant_to_ruby(entry.get_child(1));
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rb_hash_aset(hash, key, val);
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}
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return hash;
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} else if (container.is_of_type(Glib::VARIANT_TYPE_ARRAY) ||
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container.is_of_type(Glib::VARIANT_TYPE_TUPLE)) {
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VALUE array = rb_ary_new2(count);
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for (gsize i = 0; i < count; i++) {
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VALUE val = variant_to_ruby(container.get_child(i));
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rb_ary_store(array, i, val);
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}
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return array;
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}
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} else {
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SWIG_exception(SWIG_TypeError, ("TODO: GVariant(" + variant.get_type().get_string() + ") -> Ruby").c_str());
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}
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}
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%}
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/* Map from Glib::Variant to native Ruby types. */
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%typemap(out) Glib::VariantBase {
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$result = variant_to_ruby($1);
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}
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/* Map from Glib::VariantContainer to native Ruby types. */
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%typemap(out) Glib::VariantContainerBase {
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$result = variant_to_ruby($1);
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}
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/* Map from callable Ruby Proc to LogCallbackFunction */
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%typemap(in) sigrok::LogCallbackFunction {
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if (!rb_obj_is_proc($input))
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SWIG_exception(SWIG_TypeError, "Expected a callable Ruby object");
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std::shared_ptr<VALUE> proc(new VALUE($input), rb_gc_unregister_address);
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rb_gc_register_address(proc.get());
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$1 = [=] (const sigrok::LogLevel *loglevel, std::string message) {
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VALUE log_obj = SWIG_NewPointerObj(
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SWIG_as_voidptr(loglevel), SWIGTYPE_p_sigrok__LogLevel, 0);
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VALUE string_obj = rb_external_str_new_with_enc(message.c_str(), message.length(), rb_utf8_encoding());
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VALUE args = rb_ary_new_from_args(2, log_obj, string_obj);
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rb_proc_call(*proc.get(), args);
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};
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}
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/* Map from callable Ruby Proc to SessionStoppedCallback */
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%typemap(in) sigrok::SessionStoppedCallback {
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if (!rb_obj_is_proc($input))
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SWIG_exception(SWIG_TypeError, "Expected a callable Ruby object");
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std::shared_ptr<VALUE> proc(new VALUE($input), rb_gc_unregister_address);
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rb_gc_register_address(proc.get());
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$1 = [=] () {
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rb_proc_call(*proc.get(), rb_ary_new());
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};
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}
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/* Map from callable Ruby Proc to DatafeedCallbackFunction */
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%typemap(in) sigrok::DatafeedCallbackFunction {
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if (!rb_obj_is_proc($input))
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SWIG_exception(SWIG_TypeError, "Expected a callable Ruby object");
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std::shared_ptr<VALUE> proc(new VALUE($input), rb_gc_unregister_address);
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rb_gc_register_address(proc.get());
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$1 = [=] (std::shared_ptr<sigrok::Device> device,
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std::shared_ptr<sigrok::Packet> packet) {
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VALUE device_obj = SWIG_NewPointerObj(
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SWIG_as_voidptr(new std::shared_ptr<sigrok::Device>(device)),
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SWIGTYPE_p_std__shared_ptrT_sigrok__Device_t, SWIG_POINTER_OWN);
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VALUE packet_obj = SWIG_NewPointerObj(
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SWIG_as_voidptr(new std::shared_ptr<sigrok::Packet>(packet)),
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SWIGTYPE_p_std__shared_ptrT_sigrok__Packet_t, SWIG_POINTER_OWN);
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VALUE args = rb_ary_new_from_args(2, device_obj, packet_obj);
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rb_proc_call(*proc.get(), args);
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};
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}
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/* Cast PacketPayload pointers to correct subclass type. */
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%ignore sigrok::Packet::payload;
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%rename sigrok::Packet::_payload payload;
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%extend sigrok::Packet
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{
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VALUE _payload()
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{
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if ($self->type() == sigrok::PacketType::HEADER) {
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return SWIG_NewPointerObj(
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SWIG_as_voidptr(new std::shared_ptr<sigrok::Header>(dynamic_pointer_cast<sigrok::Header>($self->payload()))),
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SWIGTYPE_p_std__shared_ptrT_sigrok__Header_t, SWIG_POINTER_OWN);
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} else if ($self->type() == sigrok::PacketType::META) {
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return SWIG_NewPointerObj(
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SWIG_as_voidptr(new std::shared_ptr<sigrok::Meta>(dynamic_pointer_cast<sigrok::Meta>($self->payload()))),
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SWIGTYPE_p_std__shared_ptrT_sigrok__Meta_t, SWIG_POINTER_OWN);
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} else if ($self->type() == sigrok::PacketType::ANALOG) {
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return SWIG_NewPointerObj(
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SWIG_as_voidptr(new std::shared_ptr<sigrok::Analog>(dynamic_pointer_cast<sigrok::Analog>($self->payload()))),
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SWIGTYPE_p_std__shared_ptrT_sigrok__Analog_t, SWIG_POINTER_OWN);
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} else if ($self->type() == sigrok::PacketType::LOGIC) {
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return SWIG_NewPointerObj(
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SWIG_as_voidptr(new std::shared_ptr<sigrok::Logic>(dynamic_pointer_cast<sigrok::Logic>($self->payload()))),
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SWIGTYPE_p_std__shared_ptrT_sigrok__Logic_t, SWIG_POINTER_OWN);
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} else {
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return Qnil;
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}
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}
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}
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%{
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#include "libsigrokcxx/libsigrokcxx.hpp"
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/* Convert from a Ruby type to Glib::Variant, according to config key data type. */
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Glib::VariantBase ruby_to_variant_by_key(VALUE input, const sigrok::ConfigKey *key)
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{
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enum sr_datatype type = (enum sr_datatype) key->data_type()->id();
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if (type == SR_T_UINT64 && RB_TYPE_P(input, T_FIXNUM))
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return Glib::Variant<guint64>::create(NUM2ULL(input));
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if (type == SR_T_UINT64 && RB_TYPE_P(input, T_BIGNUM))
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return Glib::Variant<guint64>::create(NUM2ULL(input));
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else if (type == SR_T_STRING && RB_TYPE_P(input, T_STRING))
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return Glib::Variant<Glib::ustring>::create(string_from_ruby(input));
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else if (type == SR_T_STRING && RB_TYPE_P(input, T_SYMBOL))
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return Glib::Variant<Glib::ustring>::create(string_from_ruby(input));
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else if (type == SR_T_BOOL && RB_TYPE_P(input, T_TRUE))
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return Glib::Variant<bool>::create(true);
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else if (type == SR_T_BOOL && RB_TYPE_P(input, T_FALSE))
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return Glib::Variant<bool>::create(false);
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else if (type == SR_T_FLOAT && RB_TYPE_P(input, T_FLOAT))
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return Glib::Variant<double>::create(RFLOAT_VALUE(input));
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else if (type == SR_T_INT32 && RB_TYPE_P(input, T_FIXNUM))
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return Glib::Variant<gint32>::create(NUM2INT(input));
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else
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throw sigrok::Error(SR_ERR_ARG);
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}
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/* Convert from a Ruby type to Glib::Variant, according to Option data type. */
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Glib::VariantBase ruby_to_variant_by_option(VALUE input, std::shared_ptr<sigrok::Option> option)
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{
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Glib::VariantBase variant = option->default_value();
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if (variant.is_of_type(Glib::VARIANT_TYPE_UINT64) && RB_TYPE_P(input, T_FIXNUM))
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return Glib::Variant<guint64>::create(NUM2ULL(input));
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else if (variant.is_of_type(Glib::VARIANT_TYPE_UINT64) && RB_TYPE_P(input, T_BIGNUM))
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return Glib::Variant<guint64>::create(NUM2ULL(input));
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else if (variant.is_of_type(Glib::VARIANT_TYPE_STRING) && RB_TYPE_P(input, T_STRING))
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return Glib::Variant<Glib::ustring>::create(string_from_ruby(input));
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else if (variant.is_of_type(Glib::VARIANT_TYPE_STRING) && RB_TYPE_P(input, T_SYMBOL))
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return Glib::Variant<Glib::ustring>::create(string_from_ruby(input));
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else if (variant.is_of_type(Glib::VARIANT_TYPE_BOOL) && RB_TYPE_P(input, T_TRUE))
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return Glib::Variant<bool>::create(true);
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else if (variant.is_of_type(Glib::VARIANT_TYPE_BOOL) && RB_TYPE_P(input, T_FALSE))
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return Glib::Variant<bool>::create(false);
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else if (variant.is_of_type(Glib::VARIANT_TYPE_DOUBLE) && RB_TYPE_P(input, T_FLOAT))
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return Glib::Variant<double>::create(RFLOAT_VALUE(input));
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else if (variant.is_of_type(Glib::VARIANT_TYPE_INT32) && RB_TYPE_P(input, T_FIXNUM))
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return Glib::Variant<gint32>::create(NUM2INT(input));
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else
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throw sigrok::Error(SR_ERR_ARG);
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}
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struct hash_to_map_options_params {
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std::map<std::string, std::shared_ptr<sigrok::Option> > options;
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std::map<std::string, Glib::VariantBase> output;
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};
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int convert_option(VALUE key, VALUE val, VALUE in) {
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struct hash_to_map_options_params *params;
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params = (struct hash_to_map_options_params *)in;
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auto k = string_from_ruby(key);
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auto v = ruby_to_variant_by_option(val, params->options[k]);
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params->output[k] = v;
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return ST_CONTINUE;
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}
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/* Convert from a Ruby hash to a std::map<std::string, Glib::VariantBase> */
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std::map<std::string, Glib::VariantBase> hash_to_map_options(VALUE hash,
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std::map<std::string, std::shared_ptr<sigrok::Option> > options)
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{
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if (!RB_TYPE_P(hash, T_HASH))
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throw sigrok::Error(SR_ERR_ARG);
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struct hash_to_map_options_params params = { options };
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rb_hash_foreach(hash, (int (*)(ANYARGS))convert_option, (VALUE)¶ms);
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return params.output;
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}
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int convert_option_by_key(VALUE key, VALUE val, VALUE in) {
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std::map<const sigrok::ConfigKey *, Glib::VariantBase> *options;
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options = (std::map<const sigrok::ConfigKey *, Glib::VariantBase> *)in;
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auto k = sigrok::ConfigKey::get_by_identifier(string_from_ruby(key));
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auto v = ruby_to_variant_by_key(val, k);
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(*options)[k] = v;
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return ST_CONTINUE;
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}
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%}
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/* Ignore these methods, we will override them below. */
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%ignore sigrok::Analog::data;
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%ignore sigrok::Driver::scan;
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%ignore sigrok::Input::send;
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%ignore sigrok::InputFormat::create_input;
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%ignore sigrok::OutputFormat::create_output;
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%include "doc.i"
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%define %attributevector(Class, Type, Name, Get)
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%alias sigrok::Class::_ ## Get #Name;
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%enddef
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%define %attributemap(Class, Type, Name, Get)
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%alias sigrok::Class::_ ## Get #Name;
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%enddef
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%define %enumextras(Class)
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%extend sigrok::Class
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{
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VALUE to_s()
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{
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std::string str = $self->name();
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return rb_external_str_new_with_enc(str.c_str(), str.length(), rb_utf8_encoding());
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}
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bool operator==(void *other)
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{
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return (long) $self == (long) other;
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}
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}
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%enddef
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%include "../swig/classes.i"
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/* Replace the original Driver.scan with a keyword arguments version. */
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%rename sigrok::Driver::_scan scan;
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%extend sigrok::Driver
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{
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std::vector<std::shared_ptr<sigrok::HardwareDevice> > _scan(VALUE kwargs = rb_hash_new())
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{
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if (!RB_TYPE_P(kwargs, T_HASH))
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throw sigrok::Error(SR_ERR_ARG);
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std::map<const sigrok::ConfigKey *, Glib::VariantBase> options;
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rb_hash_foreach(kwargs, (int (*)(ANYARGS))convert_option_by_key, (VALUE)&options);
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return $self->scan(options);
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}
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}
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/* Support Input.send() with string argument. */
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%rename sigrok::Input::_send send;
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%extend sigrok::Input
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{
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void _send(VALUE data)
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{
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data = StringValue(data);
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return $self->send(RSTRING_PTR(data), RSTRING_LEN(data));
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}
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}
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/* Support InputFormat.create_input() with keyword arguments. */
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%rename sigrok::InputFormat::_create_input create_input;
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%extend sigrok::InputFormat
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{
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std::shared_ptr<sigrok::Input> _create_input(VALUE hash = rb_hash_new())
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{
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return $self->create_input(hash_to_map_options(hash, $self->options()));
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}
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}
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/* Support OutputFormat.create_output() with keyword arguments. */
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%rename sigrok::OutputFormat::_create_output create_output;
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%extend sigrok::OutputFormat
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{
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std::shared_ptr<sigrok::Output> _create_output(
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std::shared_ptr<sigrok::Device> device, VALUE hash = rb_hash_new())
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{
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return $self->create_output(device,
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hash_to_map_options(hash, $self->options()));
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}
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std::shared_ptr<sigrok::Output> _create_output(string filename,
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std::shared_ptr<sigrok::Device> device, VALUE hash = rb_hash_new())
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{
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return $self->create_output(filename, device,
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hash_to_map_options(hash, $self->options()));
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}
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}
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/* Support config_set() with Ruby input types. */
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%extend sigrok::Configurable
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{
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void config_set(const ConfigKey *key, VALUE input)
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{
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$self->config_set(key, ruby_to_variant_by_key(input, key));
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}
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}
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/* Return Ruby array from Analog::data(). */
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%rename sigrok::Analog::_data data;
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%extend sigrok::Analog
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{
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VALUE _data()
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{
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int num_channels = $self->channels().size();
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int num_samples = $self->num_samples();
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float *data = (float *) $self->data_pointer();
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VALUE channels = rb_ary_new2(num_channels);
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for(int i = 0; i < num_channels; i++) {
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VALUE samples = rb_ary_new2(num_samples);
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for (int j = 0; j < num_samples; j++) {
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rb_ary_store(samples, j, DBL2NUM(data[i*num_samples+j]));
|
|
}
|
|
rb_ary_store(channels, i, samples);
|
|
}
|
|
return channels;
|
|
}
|
|
}
|