template class xf::dsp::aie::fir::interpolate_asym::fir_interpolate_asym_graph - 2023.2 English

Vitis Libraries

Release Date
2023-12-20
Version
2023.2 English
#include "fir_interpolate_asym_graph.hpp"

Overview

fir_interpolate_asym is an Asymmetric Interpolation FIR filter

These are the templates to configure the Asymmetric Interpolation FIR class.

Parameters:

TT_DATA

describes the type of individual data samples input to and output from the filter function. This is a typename and must be one of the following:

int16, cint16, int32, cint32, float, cfloat.

TT_COEFF

describes the type of individual coefficients of the filter taps.

It must be one of the same set of types listed for TT_DATA and must also satisfy the following rules:

  • Complex types are only supported when TT_DATA is also complex.
  • TT_COEFF must be an integer type if TT_DATA is an integer type
  • TT_COEFF must be a float type if TT_DATA is a float type.
TP_FIR_LEN is an unsigned integer which describes the number of taps in the filter.
TP_INTERPOLATE_FACTOR is an unsigned integer which describes the interpolation factor of the filter. TP_INTERPOLATE_FACTOR must be in the range 1 to 16.
TP_SHIFT

describes power of 2 shift down applied to the accumulation of FIR terms before output.

TP_SHIFT must be in the range 0 to 61.

TP_RND

describes the selection of rounding to be applied during the shift down stage of processing. Although, TP_RND accepts unsigned integer values descriptive macros are recommended where

  • rnd_floor = Truncate LSB, always round down (towards negative infinity).

  • rnd_ceil = Always round up (towards positive infinity).

  • rnd_sym_floor = Truncate LSB, always round towards 0.

  • rnd_sym_ceil = Always round up towards infinity.

  • rnd_pos_inf = Round halfway towards positive infinity.

  • rnd_neg_inf = Round halfway towards negative infinity.

  • rnd_sym_inf = Round halfway towards infinity (away from zero).

  • rnd_sym_zero = Round halfway towards zero (away from infinity).

  • rnd_conv_even = Round halfway towards nearest even number.

  • rnd_conv_odd = Round halfway towards nearest odd number.

    No rounding is performed on ceil or floor mode variants.

    Other modes round to the nearest integer. They differ only in how they round for values of 0.5.

    Note: Rounding modes rnd_sym_floor and rnd_sym_ceil are only supported on AIE-ML device.

TP_INPUT_WINDOW_VSIZE

describes the number of samples processed by the graph in a single iteration run.

When TP_API is set to 0, samples are buffered and stored in a ping-pong window buffer mapped onto Memory Group banks.

As a results, maximum number of samples processed by the graph is limited by the size of Memory Group.

When TP_API is set to 1, samples are processed directly from the stream inputs and no buffering takes place.

In such case, maximum number of samples processed by the graph is limited to 32-bit value (4.294B samples per iteration).

Note: For SSR configurations (TP_SSR>1), the input data must be split over multiple ports, where each successive sample is sent to a different input port in a round-robin fashion.

As a results, each SSR input path will process a fraction of the frame defined by the TP_INPUT_WINDOW_VSIZE.

The number of values in the output window will be TP_INPUT_WINDOW_VSIZE multipled by TP_INTERPOLATE_FACTOR.

Note: Margin size should not be included in TP_INPUT_WINDOW_VSIZE.

TP_CASC_LEN

describes the number of AIE processors to split the operation over.

This allows resource to be traded for higher performance. TP_CASC_LEN must be in the range 1 (default) to 40.

TP_USE_COEFF_RELOAD

allows the user to select if runtime coefficient reloading should be used.

When defining the parameter:

  • 0 = static coefficients, defined in filter constructor,

  • 1 = reloadable coefficients, passed as argument to runtime function.

    Note: when used, async port: port_conditional_array<input, (TP_USE_COEFF_RELOAD == 1), TP_SSR * TP_PARA_INTERP_POLY> coeff; will be added to the FIR.

    Note: the size of the port array is equal to the total number of output paths (TP_SSR * TP_PARA_INTERP_POLY).

    Each port should contain the same taps array content, i.e. each additional port must be a duplicate of the coefficient array.

TP_NUM_OUTPUTS

sets the number of ports over which the output is sent.

This can be 1 or 2. It is set to 1 by default.

Depending on TP_API, additional output ports functionality differs. For Windows API, additional output provides flexibility in connecting FIR output with multiple destinations. Additional output out2 is an exact copy of the data of the output port out .

With Stream API, the additional output port increases the FIR’s throughput.

Data is sent in a 128-bit interleaved pattern, e.g. :

  • samples 0-3 is sent over stream0 for cint16 data type,

  • samples 4-7 is sent over stream1 for cint16 data type.

    Note: when used, optional port: port<output> out2; will be added to the FIR.

TP_DUAL_IP

allows 2 stream inputs to be connected to FIR, increasing available throughput.

When set to 0, single stream will be connected as FIRs input.

When set to 1, two stream inputs will be connected.

In such case data should be organized in 128-bit interleaved pattern, e.g.:

  • samples 0-3 to be sent over stream0 for cint16 data type,
  • samples 4-7 to be sent over stream1 for cint16 data type.
TP_API

specifies if the input/output interface should be window-based or stream-based.

The values supported are 0 (window API) or 1 (stream API).

TP_SSR

specifies the number of parallel input paths where samples are interleaved between paths, giving an overall higher throughput.

An SSR of 1 means just one input path, and is the backwards compatible option.

TP_PARA_INTERP_POLY

sets the number of interpolator polyphases over which the coefficients will be split to enable parallel computation of the outputs.

The polyphases are executed in parallel, output data is produced by each polyphase directly.

TP_PARA_INTERP_POLY does not affect the number of input data paths.

There will be TP_SSR input phases irrespective of the value of TP_PARA_INTERP_POLY.

TP_PARA_INTERP_POLY = TP_INTERPOLATE_FACTOR will result in an interpolate factor of polyphases, where each kernel is a single rate filters.

TP_PARA_INTERP_POLY < TP_INTERPOLATE_FACTOR will result in the kernels in the polyphase branches operating as independent interpolators.

TP_SAT

describes the selection of saturation to be applied during the shift down stage of processing. TP_SAT accepts unsigned integer values, where:

  • 0: none = No saturation is performed and the value is truncated on the MSB side.

  • 1: saturate = Default. Saturation rounds an n-bit signed value in the range [- ( 2^(n-1) ) : +2^(n-1) - 1 ].

  • 3: symmetric = Controls symmetric saturation. Symmetric saturation rounds an n-bit signed value in the range [- ( 2^(n-1) -1 ) : +2^(n-1) - 1 ].

    TP_PARA_INTERP_POLY can be used in combination with TP_SSR. The number of AIEs used is given by TP_PARA_INTERP_POLY*TP_SSR^2 * TP_CASC_LEN.

template <
    typename TT_DATA,
    typename TT_COEFF,
    unsigned int TP_FIR_LEN,
    unsigned int TP_INTERPOLATE_FACTOR,
    unsigned int TP_SHIFT,
    unsigned int TP_RND,
    unsigned int TP_INPUT_WINDOW_VSIZE,
    unsigned int TP_CASC_LEN = 1,
    unsigned int TP_USE_COEFF_RELOAD = 0,
    unsigned int TP_DUAL_IP = 0,
    unsigned int TP_NUM_OUTPUTS = 1,
    unsigned int TP_API = 0,
    unsigned int TP_SSR = 1,
    unsigned int TP_PARA_INTERP_POLY = 1,
    unsigned int TP_SAT = 1
    >
class fir_interpolate_asym_graph: public graph

// structs

struct ssr_params

template <unsigned int CL>
struct tmp_ssr_params

// fields

static constexpr unsigned int OUT_SSR
port_array <input, TP_SSR> in
port_array <output, OUT_SSR> out
port_conditional_array <input, (TP_DUAL_IP==1), TP_SSR> in2
port_conditional_array <input, (TP_USE_COEFF_RELOAD==1), TP_SSR*TP_PARA_INTERP_POLY> coeff
port_conditional_array <output, (TP_NUM_OUTPUTS==2), OUT_SSR> out2
kernel m_firKernels[TP_CASC_LEN *TP_SSR *TP_SSR *TP_PARA_INTERP_POLY]

Fields

static constexpr unsigned int OUT_SSR

OUT_SSR defines the number of output paths, equal to TP_SSR * TP_PARA_INTERP_POLY .

port_array <input, TP_SSR> in

The input data to the function. This input is either a window API of samples of TT_DATA type or stream API (depending on TP_API). Note: Margin is added internally to the graph, when connecting input port with kernel port. Therefore, margin should not be added when connecting graph to a higher level design unit. Margin size (in Bytes) equals to TP_FIR_LEN rounded up to a nearest multiple of 32 bytes.

port_array <output, OUT_SSR> out

The output data from the function. This output is either a window API of samples of TT_DATA type or stream API (depending on TP_API). Number of output samples is determined by interpolation & decimation factors (if present).

port_conditional_array <input, (TP_DUAL_IP==1), TP_SSR> in2

The conditional input data to the function. This input is (generated when TP_DUAL_IP == 1) either a window API of samples of TT_DATA type or stream API (depending on TP_API).

port_conditional_array <input, (TP_USE_COEFF_RELOAD==1), TP_SSR*TP_PARA_INTERP_POLY> coeff

The conditional array of input async ports used to pass run-time programmable (RTP) coeficients. This port_conditional_array is (generated when TP_USE_COEFF_RELOAD == 1) an array of input ports, which size is defined by TP_SSR. Each port in the array holds a duplicate of the coefficient array, required to connect to each SSR input path.

port_conditional_array <output, (TP_NUM_OUTPUTS==2), OUT_SSR> out2

The output data from the function. This output is (generated when TP_NUM_OUTPUTS == 2) either a window API of samples of TT_DATA type or stream API (depending on TP_API). Number of output samples is determined by interpolation & decimation factors (if present).

kernel m_firKernels [TP_CASC_LEN *TP_SSR *TP_SSR *TP_PARA_INTERP_POLY]

The array of kernels that will be created and mapped onto AIE tiles. Number of kernels ( TP_CASC_LEN * TP_SSR ) will be connected with each other by cascade interface.

Methods

getKernels

getKernels overload (1)

kernel* getKernels ()

Access function to get pointer to kernel (or first kernel in a chained configuration).

getKernels overload (2)

kernel* getKernels (int cascadePosition)

Access function to get pointer to an indexed kernel.

Parameters:

cascadePosition an index to the kernel’s position in the cascade.

getInNet

connect <stream, stream>* getInNet (
    int cascadePosition,
    int ssrOutPathIndex = 0,
    int ssrInPhaseIndex = 0,
    int paraPolyphaseOutIdx = 0
    )

Access function to get pointer to net of the in port. Nets only get assigned when streaming interface is being broadcast, i.e. nets only get used when TP_API == 1 and TP_CASC_LEN > 1

Parameters:

cascadePosition an index to the kernel’s position in the cascade.
ssrOutPathIndex an index to the output data Path.
ssrInPhaseIndex an index to the input data Phase
paraPolyphaseOutIdx an index to the parallel output polyphase

getIn2Net

connect <stream, stream>* getIn2Net (
    int cascadePosition,
    int ssrOutPathIndex = 0,
    int ssrInPhaseIndex = 0,
    int paraPolyphaseOutIdx = 0
    )

Access function to get pointer to net of the in2 port, when port is being generated, i.e. when TP_DUAL_IP == 1. Nets only get assigned when streaming interface is being broadcast, i.e. nets only get used when TP_API == 1 and TP_CASC_LEN > 1

Parameters:

cascadePosition an index to the kernel’s position in the cascade.
ssrOutPathIndex an index to the output data Path.
ssrInPhaseIndex an index to the input data Phase
paraPolyphaseOutIdx an index to the parallel output polyphase

getKernelArchs

unsigned int getKernelArchs ()

Access function to get kernel’s architecture (or first kernel’s architecture in a chained configuration).

fir_interpolate_asym_graph

fir_interpolate_asym_graph overload (1)

fir_interpolate_asym_graph (const std::vector <TT_COEFF>& taps)

This is the constructor function for the Asymmetric Interpolation FIR graph.

Parameters:

taps a reference to the std::vector array of taps values of type TT_COEFF.

fir_interpolate_asym_graph overload (2)

fir_interpolate_asym_graph ()

This is the constructor function for the FIR graph with reloadable coefficients.

getMinCascLen

template <
    int T_FIR_LEN,
    int T_API,
    typename T_D,
    typename T_C,
    unsigned int T_IF,
    unsigned int SSR,
    unsigned int IP_PORTS
    >
static constexpr unsigned int getMinCascLen ()

Access function to get Graphs minimum cascade length for a given configuration.

Parameters:

T_FIR_LEN tap length of the fir filter
T_API interface type : 0 - window, 1 - stream
T_D data type
T_C coeff type
T_IF interpolation factor
SSR parallelism factor set for super sample rate operation
IP_PORTS single/dual input ports : 0 - single, 1 - dual

getOptCascLen

template <
    int T_FIR_LEN,
    typename T_D,
    typename T_C,
    int T_API,
    unsigned int T_IF,
    unsigned int SSR,
    unsigned int INT_POLY
    >
static constexpr unsigned int getOptCascLen ()

Access function to get graph’s cascade length to obtain maximum performance for streaming configurations.

Parameters:

T_FIR_LEN tap length of the fir filter
T_D data type
T_C coeff type
T_API interface type : 0 - window, 1 - stream
T_IF interpolation factor
SSR parallelism factor set for super sample rate operation
INT_POLY number of polyphases set for super sample rate operation