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[/] [artificial_neural_network/] [trunk/] [ANN_kernel/] [API_header_files/] [ann.h] - Rev 10
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/* * ann.h * * Description: This header file helps programmers to access correctly to ANN IP core weight and bias memories. * User must edit ANN_BASEADDRESS, NLAYER, and definitions of layer inputs and neurons. * MAX_MUL macro can be calculated manually, or relay on automated calculation if NLAYER<=4. * A Wyb(x) macro must be declared on the code per layer of the ANN IP core. * Those macro declare the 2D weight arrays and 1D bias arrays needed to access ANN IP core memories. * * Created on: 17/05/2016 * Author: David A */ #ifndef ANN_H #define ANN_H /* Base address of weight and bias memories of the ANN IP core */ // Example for Xilinx's SDK using the example wrapper for Vivado. Correct user base address must be defined here: #define ANN_BASEADDRESS XPAR_ANN_0_WYB_S_AXI_BASEADDR /* Number of layers */ #define NLAYER 4 /* Number of inputs and neurons of each layer */ // Add or remove as many layers as needed: #define NumIn0 16 #define NumN0 13 #define NumIn1 NumN0 #define NumN1 6 #define NumIn2 NumN1 #define NumN2 13 #define NumIn3 NumN2 #define NumN3 16 /* (optional) Redefine number of neurons in the last layer as number of outputs */ #define NumOut NumN3 /* Next-power-of-two of inputs and neurons of each layer */ // Define a next-power-of-two macro per parameter in the number of inputs and neurons of each layer list: // NOTE: next_2power(x) macro function calculates the next-power-of-two of x for x<=256. If x>256 it still returns 256. #define NumN0_b2 next_2power(NumN0) #define NumIn0_b2 next_2power(NumIn0) #define NumN1_b2 next_2power(NumN1) #define NumIn1_b2 next_2power(NumIn1) #define NumN2_b2 next_2power(NumN2) #define NumIn2_b2 next_2power(NumIn2) #define NumN3_b2 next_2power(NumN3) #define NumIn3_b2 next_2power(NumIn3) /* Maximum multiplication of the next-power-of-two of inputs by the next-power-of-two of neurons */ // MAX_MUL macro can be defined manually, or automatically if NLAYER<=4. // To define it manually user must determine which layer has the maximum of these products, and edit MAX_MUL definition: // In the example is layer 0 (or layer 3 with same MAX_MUL), 256 > 128 // NumIn0 = 16 ==> NumIn0_b2 = 16 // NumN0 = 13 ==> NumN0_b2 = 16 // NumN0_b2*NumIn0_b2=16*16=256 // NumIn1 = 13 ==> NumIn1_b2 = 16 // NumN1 = 6 ==> NumN1_b2 = 8 // NumN1_b2*NumIn1_b2=16*8=128 // NumIn2 = 6 ==> NumIn2_b2 = 8 // NumN2 = 13 ==> NumN2_b2 = 16 // NumN2_b2*NumIn2_b2=8*16=128 // NumIn3 = 13 ==> NumIn3_b2 = 16 // NumN3 = 16 ==> NumN3_b2 = 16 // NumN3_b2*NumIn3_b2=16*16=256 //#define MAX_MUL (NumN0_b2*NumIn0_b2) //Uncomment and edit this manual definition of MAX_MUL for manual definition of MAX_MUL // Automated calculation of MAX_MUL for NLAYER<=4: #ifndef MAX_MUL #if NLAYER > 4 #error MAX_MUL cannot be automatically calculated if NLAYER>4. Define MAX_MUL manually or complete the automaed calculation of MAX_MUL preprocessor code. #endif #define max2(x,y) ( ((x) < (y)) ? y : x ) #define MAX_0 (NumN0_b2*NumIn0_b2) #if NLAYER > 1 #define MAX_1 max2((NumN1_b2*NumIn1_b2),MAX_0) #if NLAYER > 2 #define MAX_2 max2((NumN2_b2*NumIn2_b2),MAX_1) #if NLAYER == 4 #define MAX_MUL max2((NumN3_b2*NumIn3_b2),MAX_2) #elif NLAYER == 3 #define MAX_MUL MAX_2 #endif //NLAYER == 4 #elif NLAYER == 2 #define MAX_MUL MAX_1 #endif //NLAYER > 2 #else //NLAYER == 1 #define MAX_MUL MAX_0 #endif //NLAYER > 1 #endif /* Definition of the macro function next_2power(x) */ // It calculates the next-power-of-two of x for x<=256. If x>256 it still returns 256. #define next_2power(x) ( ((x) > 128) ? 256 : ((x) > 64) ? 128 : ((x) > 32) ? 64 : ((x) > 16) ? 32 : ((x) > 8) ? 16 : ((x) > 4) ? 8 : ((x) > 2) ? 4 : ((x) > 1) ? 2 : 1 ) /* When this macro is expanded for a particular layer x, it declares pointers to the weight 2D array, bias 1D array, and unused spaces; and initializes them with a proper address */ // Declare a Wvb(x) macro per layer on the user's ANN, each time with a different layer number x, from 0 to NLAYER-1. // Example: For a two layer ANN (NLAYER 2) // Wvb(0) // declares and initializes int (*W0)[NumN0][NumIn0_b2], (*b0)[NumN0]; // Wyb(1) // declares and initializes int (*W1)[NumN1][NumIn1_b2], (*b1)[NumN1]; // The unused spaces (*NOT_EXISTx0) and (*NOT_EXISTx1) are declared in order to prevent the use of these space address for other proposes. Although it does not assure it will not be used. #define Wyb(x) volatile int (*W##x)[NumN##x][NumIn##x##_b2] = (void *) ANN_BASEADDRESS + MAX_MUL*2*x*sizeof(int), \ (*NOT_EXIST##x##0)[MAX_MUL-NumN##x*NumIn##x##_b2] = (void *) ANN_BASEADDRESS + (NumN##x*NumIn##x##_b2 + MAX_MUL*2*x)*sizeof(int), \ (*b##x)[NumN##x] = (void *) ANN_BASEADDRESS + MAX_MUL*(2*x+1)*sizeof(int), \ (*NOT_EXIST##x##1)[MAX_MUL-NumN##x] = (void *) ANN_BASEADDRESS + (NumN##x + MAX_MUL*(2*x+1))*sizeof(int); #endif // ANN_H
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