Getting Started

Overview

lib_xcore_math is a library containing efficient implementations of various mathematical operations that may be required in an embedded application. In particular, this library is geared towards operations which work on vectors or arrays of data, including vectorized arithmetic, linear filtering, and fast Fourier transforms.

This library comprises several sub-APIs. Grouping of operations into sub-APIs is a matter of conceptual convenience. In general, functions from a given API share a common prefix indicating which API the function comes from, or the type of object on which it acts. Additionally, there is some interdependence between these APIs.

These APIs are:

• Block floating-point (BFP) API – High-level API providing operations on BFP vectors. See Block Floating-Point Background for an introduction to block floating-point. These functions manage the exponents and headroom of input and output BFP vectors to avoid overflow and underflow conditions.

• Vector/Array API – Lower-level API which is used heavily by the BFP API. As such, the operations available in this API are similar to those in the BFP API, but the user will have to manage exponents and headroom on their own. Many of these routines are implemented directly in optimized assembly to use the hardware as efficiently as possible.

• Scalar API – Provides various operations on scalar objects. In particular, these operations focus on simple arithmetic operations applied to non-IEEE 754 floating-point objects, as well as optimized operations which are applied to IEEE 754 floats.

• Filtering API – Provides access to linear filtering operations, including 16- and 32-bit FIR filters and 32-bit biquad filters.

• Fast Fourier Transform (FFT) API – Provides both low-level and block floating-point FFT implementations. Optimized FFT implementations are provided for real signals, pairs of real signals, and for complex signals.

• Discrete Cosine Transform (DCT) API – Provides functions which implement the type-II (‘forward’) and type-III (‘inverse’) DCT for a variety of block lengths. Also provides a fast 8x8 two dimensional forward and inverse DCT.

All APIs are accessed by including the single header file:

#include "xmath/xmath.h"

Building

This library makes use of the CMake build system. See the GitHub page for instructions on obtaining this library’s source code and including it in your application’s build.

Usage

The following sections are intended to give the reader a general sense of how to use the API.

BFP API

In the BFP API the BFP vectors are C structures such as bfp_s16_t, bfp_s32_t, or bfp_complex_s32_t, backed by a memory buffer. These objects contain a pointer to the data carrying the content (mantissas) of the vector, as well as information about the length, headroom and exponent of the BFP vector.

Below is the definition of bfp_s32_t from xmath/types.h.

C_TYPE
typedef struct {
    /** Pointer to the underlying element buffer.*/
    int32_t* data;
    /** Exponent associated with the vector. */
    exponent_t exp;
    /** Current headroom in the ``data[]`` */
    headroom_t hr;
    /** Current size of ``data[]``, expressed in elements */
    unsigned length;
    /** BFP vector flags. Users should not normally modify these manually. */
    bfp_flags_e flags;
} bfp_s32_t;

The 32-bit BFP functions take bfp_s32_t pointers as input and output parameters.

Functions in the BFP API generally are prefixed with bfp_. More specifically, functions where the ‘main’ operands are 32-bit BFP vectors are prefixed with bfp_s32_, whereas functions where the ‘main’ operands are complex 16-bit BFP vectors are prefixed with bfp_complex_s16_, and so on for the other BFP vector types.

Initializing BFP Vectors

Before calling these functions, the BFP vectors represented by the arguments must be initialized. For bfp_s32_t this is accomplished with bfp_s32_init(). Initialization requires that a buffer of sufficient size be provided to store the mantissa vector, as well as an initial exponent. If the first usage of a BFP vector is as an output, then the exponent will not matter, but the object must still be initialized before use. Additionally, the headroom of the vector may be computed upon initialization; otherwise it is set to 0.

Here is an example of a 32-bit BFP vector being initialized.

#define LEN (20)

//The object representing the BFP vector
bfp_s32_t bfp_vect;

// buffer backing bfp_vect
int32_t data_buffer[LEN];
for(int i = 0; i < LEN; i++) data_buffer[i] = i;

// The initial exponent associated with bfp_vect
exponent_t initial_exponent = 0;

// If non-zero, `bfp_s32_init()` will compute headroom currently present in data_buffer.
// Otherwise, headroom is initialized to 0 (which is always safe but may not be optimal)
unsigned calculate_headroom = 1;

// Initialize the vector object
bfp_s32_init(&bfp_vec, data_buffer, initial_exponent, LEN, calculate_headroom);

// Go do stuff with bfp_vect
...

Once initialized, the exponent and mantissas of the vector can be accessed by bfp_vect.exp and bfp_vect.data[] respectively, with the logical (floating-point) value of element k being given by \(\mathtt{bfp\_vect.data[k]}\cdot2^{\mathtt{bfp\_vect.exp}}\).

BFP Arithmetic Functions

The following snippet shows a function foo() which takes 3 BFP vectors, a, b and c, as arguments. It multiplies together a and b element-wise, and then subtracts c from the product. In this example both operations are performed in-place on a. (See bfp_s32_mul() and bfp_s32_sub() for more information about those functions)

void foo(bfp_s32_t* a, const bfp_s32_t* b, const bfp_s32_t* c)
{
    // Multiply together a and b, updating a with the result.
    bfp_s32_mul(a, a, b);

    // Subtract c from the product, again updating a with the result.
    bfp_s32_sub(a, a, c);
}

The caller of foo() can then access the results through a. Note that the pointer a->data was not modified during this call.

Vector API

The functions in the lower-level vector API are optimized for performance. They do very little to protect the user from mangling their data by arithmetic saturation/overflows or underflows (although they do provide the means to prevent this).

Functions in the vector API are generally prefixed with vect_. For example, functions which operate primarily on 16-bit vectors are prefixed with vect_s16_.

Some functions are prefixed with chunk_ instead of vect_. A “chunk” is just a vector with a fixed memory footprint (currently 32 bytes, or 8 32-bit elements) meant to match the width of the architecture’s vector registers.

As an example of a function from the vector API, see vect_s32_mul() (from vect_s32.h)), which multiplies together two int32_t vectors element by element.

C_API
headroom_t vect_s32_mul(
    int32_t a[],
    const int32_t b[],
    const int32_t c[],
    const unsigned length,
    const right_shift_t b_shr,
    const right_shift_t c_shr);

This function takes two int32_t arrays, b and c, as inputs and one int32_t array, a, as output (in the case of vect_s32_mul(), it is safe to have a point to the same buffer as b or c, computing the result in-place). length indicates the number of elements in each array. The final two parameters, b_shr and c_shr, are the arithmetic right-shifts applied to each element of b and c before they are multiplied together.

Why the right-shifts? In the case of 32-bit multiplication, the largest possible product is \(2^{62}\), which will not fit in the 32-bit output vector. Applying positive arithmetic right-shifts to the input vectors reduces the largest possible product. So, the shifts are there to manage the headroom/size of the resulting product in order to maximize precision while avoiding overflow or saturation.

Contrast this with vect_s16_mul():

C_API
headroom_t vect_s16_mul(
    int16_t a[],
    const int16_t b[],
    const int16_t c[],
    const unsigned length,
    const right_shift_t a_shr);

The parameters are similar here, but instead of b_shr and c_shr, there’s only an a_shr. In this case, the arithmetic right-shift a_shr is applied to the products of b and c. In this case the right-shift is also unsigned – it can only be used to reduce the size of the product.

Shifts like those in these two examples are very common in the vector API, as they are the main mechanism for managing exponents and headroom. Whether the shifts are applied to inputs, outputs, both, or only one input will depend on a number of factors. In the case of vect_s32_mul() they are applied to inputs because the XS3 VPU includes a compulsory (hardware) right-shift of 30 bits on all products of 32-bit numbers, and so often inputs may need to be left-shifted (negative shift) in order to avoid underflows. In the case of vect_s16_mul(), this is unnecessary because no compulsory shift is included in 16-bit multiply-accumulates.

Both vect_s32_mul() and vect_s16_mul() return the headroom of the output vector a.

Functions in the vector API are in many cases closely tied to the instruction set architecture for XS3. As such, if more efficient algorithms are found to perform an operation these low-level API functions are more likely to change in future versions.