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//
// Copyright 2011-2013 Ettus Research LLC
// Copyright 2018 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#ifndef INCLUDED_LIBUHD_CONVERT_COMMON_HPP
#define INCLUDED_LIBUHD_CONVERT_COMMON_HPP
#include <uhd/convert.hpp>
#include <uhd/utils/static.hpp>
#include <stdint.h>
#include <complex>
#define _DECLARE_CONVERTER(name, in_form, num_in, out_form, num_out, prio) \
struct name : public uhd::convert::converter \
{ \
static sptr make(void) \
{ \
return sptr(new name()); \
} \
double scale_factor; \
void set_scalar(const double s) \
{ \
scale_factor = s; \
} \
void operator()(const input_type&, const output_type&, const size_t); \
}; \
UHD_STATIC_BLOCK(__register_##name##_##prio) \
{ \
uhd::convert::id_type id; \
id.input_format = #in_form; \
id.num_inputs = num_in; \
id.output_format = #out_form; \
id.num_outputs = num_out; \
uhd::convert::register_converter(id, &name::make, prio); \
} \
void name::operator()( \
const input_type& inputs, const output_type& outputs, const size_t nsamps)
/*! Convenience macro to declare a single-function converter
*
* Most converters consist of a single for loop, and can make use of
* this macro for declaration and registering.
*
* Following this macro should be a function block in curly braces
* which runs the conversion. Available parameters in this function block
* are:
* - `inputs`: Vector of pointers to the input data. Size of the vector == `num_in`
* - `outputs`: Vector of pointers to where the output data goes. Size of the vector ==
* `num_out`
* - `nsamps`: Number of items per input buffer to convert
* - `scale_factor`: Scaling factor for float conversions
*/
#define DECLARE_CONVERTER(in_form, num_in, out_form, num_out, prio) \
_DECLARE_CONVERTER(__convert_##in_form##_##num_in##_##out_form##_##num_out##_##prio, \
in_form, \
num_in, \
out_form, \
num_out, \
prio)
/***********************************************************************
* Setup priorities
**********************************************************************/
static const int PRIORITY_GENERAL = 0;
static const int PRIORITY_EMPTY = -1;
#ifdef __ARM_NEON__
static const int PRIORITY_SIMD = 2;
static const int PRIORITY_TABLE =
1; // tables require large cache, so they are slower on arm
#else
// We used to have ORC, too, so SIMD is 3
static const int PRIORITY_SIMD = 3;
static const int PRIORITY_TABLE = 1;
#endif
/***********************************************************************
* Typedefs
**********************************************************************/
typedef std::complex<double> fc64_t;
typedef std::complex<float> fc32_t;
typedef std::complex<int32_t> sc32_t;
typedef std::complex<int16_t> sc16_t;
typedef std::complex<int8_t> sc8_t;
typedef double f64_t;
typedef float f32_t;
typedef int32_t s32_t;
typedef int16_t s16_t;
typedef int8_t s8_t;
typedef uint8_t u8_t;
typedef uint32_t item32_t;
typedef item32_t (*xtox_t)(item32_t);
/***********************************************************************
* Convert xx to items32 sc16 buffer
**********************************************************************/
template <typename T>
UHD_INLINE item32_t xx_to_item32_sc16_x1(
const std::complex<T>& num, const double scale_factor)
{
uint16_t real = int16_t(num.real() * float(scale_factor));
uint16_t imag = int16_t(num.imag() * float(scale_factor));
return (item32_t(real) << 16) | (item32_t(imag) << 0);
}
template <>
UHD_INLINE item32_t xx_to_item32_sc16_x1(const sc16_t& num, const double)
{
uint16_t real = int16_t(num.real());
uint16_t imag = int16_t(num.imag());
return (item32_t(real) << 16) | (item32_t(imag) << 0);
}
template <xtox_t to_wire, typename T>
UHD_INLINE void xx_to_item32_sc16(const std::complex<T>* input,
item32_t* output,
const size_t nsamps,
const double scale_factor)
{
for (size_t i = 0; i < nsamps; i++) {
const item32_t item = xx_to_item32_sc16_x1(input[i], scale_factor);
output[i] = to_wire(item);
}
}
template <typename T>
UHD_FORCE_INLINE sc16_t xx_to_sc16_x1(
const std::complex<T>& num, const double scale_factor)
{
uint16_t real = int16_t(num.real() * T(scale_factor));
uint16_t imag = int16_t(num.imag() * T(scale_factor));
return sc16_t(real, imag);
}
template <typename T>
UHD_FORCE_INLINE void xx_to_chdr_sc16(const std::complex<T>* input,
sc16_t* output,
const size_t nsamps,
const double scale_factor)
{
for (size_t i = 0; i < nsamps; i++) {
output[i] = xx_to_sc16_x1(input[i], scale_factor);
}
}
/***********************************************************************
* Convert items32 sc16 buffer to xx
**********************************************************************/
template <typename T>
UHD_INLINE std::complex<T> item32_sc16_x1_to_xx(
const item32_t item, const double scale_factor)
{
return std::complex<T>(T(int16_t(item >> 16) * float(scale_factor)),
T(int16_t(item >> 0) * float(scale_factor)));
}
template <>
UHD_INLINE sc16_t item32_sc16_x1_to_xx(const item32_t item, const double)
{
return sc16_t(int16_t(item >> 16), int16_t(item >> 0));
}
template <xtox_t to_host, typename T>
UHD_INLINE void item32_sc16_to_xx(const item32_t* input,
std::complex<T>* output,
const size_t nsamps,
const double scale_factor)
{
for (size_t i = 0; i < nsamps; i++) {
const item32_t item_i = to_host(input[i]);
output[i] = item32_sc16_x1_to_xx<T>(item_i, scale_factor);
}
}
template <typename T>
UHD_FORCE_INLINE std::complex<T> chdr_sc16_x1_to_xx(
const sc16_t item, const double scale_factor)
{
return std::complex<T>(
T(item.real()) * T(scale_factor), T(item.imag()) * T(scale_factor));
}
template <typename T>
UHD_FORCE_INLINE void chdr_sc16_to_xx(const sc16_t* input,
std::complex<T>* output,
const size_t nsamps,
const double scale_factor)
{
for (size_t i = 0; i < nsamps; i++) {
output[i] = chdr_sc16_x1_to_xx<T>(input[i], scale_factor);
}
}
/***********************************************************************
* Convert xx to items32 sc8 buffer
**********************************************************************/
template <typename T>
UHD_INLINE item32_t xx_to_item32_sc8_x1(
const std::complex<T>& in0, const std::complex<T>& in1, const double scale_factor)
{
uint8_t real1 = int8_t(in0.real() * float(scale_factor));
uint8_t imag1 = int8_t(in0.imag() * float(scale_factor));
uint8_t real0 = int8_t(in1.real() * float(scale_factor));
uint8_t imag0 = int8_t(in1.imag() * float(scale_factor));
return (item32_t(real0) << 8) | (item32_t(imag0) << 0) | (item32_t(real1) << 24)
| (item32_t(imag1) << 16);
}
template <>
UHD_INLINE item32_t xx_to_item32_sc8_x1(
const sc16_t& in0, const sc16_t& in1, const double)
{
uint8_t real1 = int8_t(in0.real());
uint8_t imag1 = int8_t(in0.imag());
uint8_t real0 = int8_t(in1.real());
uint8_t imag0 = int8_t(in1.imag());
return (item32_t(real0) << 8) | (item32_t(imag0) << 0) | (item32_t(real1) << 24)
| (item32_t(imag1) << 16);
}
template <>
UHD_INLINE item32_t xx_to_item32_sc8_x1(const sc8_t& in0, const sc8_t& in1, const double)
{
uint8_t real1 = int8_t(in0.real());
uint8_t imag1 = int8_t(in0.imag());
uint8_t real0 = int8_t(in1.real());
uint8_t imag0 = int8_t(in1.imag());
return (item32_t(real0) << 8) | (item32_t(imag0) << 0) | (item32_t(real1) << 24)
| (item32_t(imag1) << 16);
}
template <xtox_t to_wire, typename T>
UHD_INLINE void xx_to_item32_sc8(const std::complex<T>* input,
item32_t* output,
const size_t nsamps,
const double scale_factor)
{
const size_t num_pairs = nsamps / 2;
for (size_t i = 0, j = 0; i < num_pairs; i++, j += 2) {
const item32_t item = xx_to_item32_sc8_x1(input[j], input[j + 1], scale_factor);
output[i] = to_wire(item);
}
if (nsamps != num_pairs * 2) {
const item32_t item =
xx_to_item32_sc8_x1(input[nsamps - 1], std::complex<T>(0), scale_factor);
output[num_pairs] = to_wire(item);
}
}
/***********************************************************************
* Convert items32 sc8 buffer to xx
**********************************************************************/
template <typename T>
UHD_INLINE void item32_sc8_x1_to_xx(const item32_t item,
std::complex<T>& out0,
std::complex<T>& out1,
const double scale_factor)
{
out1 = std::complex<T>(T(int8_t(item >> 8) * float(scale_factor)),
T(int8_t(item >> 0) * float(scale_factor)));
out0 = std::complex<T>(T(int8_t(item >> 24) * float(scale_factor)),
T(int8_t(item >> 16) * float(scale_factor)));
}
template <>
UHD_INLINE void item32_sc8_x1_to_xx(
const item32_t item, sc16_t& out0, sc16_t& out1, const double)
{
out1 = sc16_t(int16_t(int8_t(item >> 8)), int16_t(int8_t(item >> 0)));
out0 = sc16_t(int16_t(int8_t(item >> 24)), int16_t(int8_t(item >> 16)));
}
template <>
UHD_INLINE void item32_sc8_x1_to_xx(
const item32_t item, sc8_t& out0, sc8_t& out1, const double)
{
out1 = sc8_t(int8_t(int8_t(item >> 8)), int8_t(int8_t(item >> 0)));
out0 = sc8_t(int8_t(int8_t(item >> 24)), int8_t(int8_t(item >> 16)));
}
template <xtox_t to_host, typename T>
UHD_INLINE void item32_sc8_to_xx(const item32_t* input,
std::complex<T>* output,
const size_t nsamps,
const double scale_factor)
{
input = reinterpret_cast<const item32_t*>(size_t(input) & ~0x3);
std::complex<T> dummy;
size_t num_samps = nsamps;
if ((size_t(input) & 0x3) != 0) {
const item32_t item0 = to_host(*input++);
item32_sc8_x1_to_xx(item0, dummy, *output++, scale_factor);
num_samps--;
}
const size_t num_pairs = num_samps / 2;
for (size_t i = 0, j = 0; i < num_pairs; i++, j += 2) {
const item32_t item_i = to_host(input[i]);
item32_sc8_x1_to_xx(item_i, output[j], output[j + 1], scale_factor);
}
if (num_samps != num_pairs * 2) {
const item32_t item_n = to_host(input[num_pairs]);
item32_sc8_x1_to_xx(item_n, output[num_samps - 1], dummy, scale_factor);
}
}
#endif /* INCLUDED_LIBUHD_CONVERT_COMMON_HPP */
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