2021-03-04 11:19:35 +01:00
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#include "raven_spn.h"
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#include "spn_regs.h"
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#include "dma_regs.h"
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#include "init.h"
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2021-03-31 16:22:08 +02:00
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#include "spn_checker_regs.h"
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2021-03-04 11:19:35 +01:00
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using spn = spn_regs<0x90000000>;
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using dma = dma_regs<0xB0000000>;
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2021-03-31 16:22:08 +02:00
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using spn_checker = spn_checker_regs<0x10040000>;
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2021-03-04 11:19:35 +01:00
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void run_xspn(int in_addr, int out_addr, int num_samples, int in_beats, int out_beats) {
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spn::mode_reg() = 0;
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spn::input_length_reg() = num_samples; // each sample consists of 5 uint8 values
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spn::input_addr_reg() = in_addr;
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spn::output_addr_reg() = out_addr;
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spn::num_of_in_beats_reg() = in_beats; // Number of AXI4 burst beats needed to load all input data
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spn::num_of_out_beats_reg() = out_beats; // Number of AXI4 burst beats needed to store all result data
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printf("Starting XSPN\n");
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spn::start_reg() = 1;
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}
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void fpga_dma(int direction, int fpga_address, int sc_address, int num_bytes) {
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dma::write_reg() = direction;
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dma::fpga_address_reg() = fpga_address;
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dma::sc_address_reg() = sc_address;
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dma::bytes_reg() = num_bytes;
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dma::start_reg() = 1;
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wait_for_interrupt();
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dma::clear_interrupt_reg() = 1;
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}
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/*! \brief main function
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*
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*/
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int main() {
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platform_init();
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spn::mode_reg() = 1;
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spn::start_reg() = 1;
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wait_for_interrupt();
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spn::interrupt_reg() = 1;
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uint32_t readout = spn::readout_reg();
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printf("READOUT HW:0x%x\n", readout);
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uint32_t axi_bytes = readout;
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axi_bytes = axi_bytes & 0xff;
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axi_bytes = 1 << axi_bytes;
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printf("AXI Bytes: %d\n", axi_bytes);
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uint32_t sample_bytes = readout;
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sample_bytes = sample_bytes >> 16;
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sample_bytes = sample_bytes / 8;
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printf("Sample Bytes: %d\n", sample_bytes);
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uint32_t result_bytes = 8;
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printf("Result Bytes: %d\n", result_bytes);
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uint32_t step = 500;
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2021-03-19 11:56:13 +01:00
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uint32_t iterations = 5;
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2021-03-04 11:19:35 +01:00
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uint32_t in_beats = (step * sample_bytes) / axi_bytes;
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if (in_beats * axi_bytes < step * sample_bytes) in_beats++;
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uint32_t out_beats = (step * result_bytes) / axi_bytes;
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if (out_beats * axi_bytes < step * result_bytes) out_beats++;
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2021-03-31 16:22:08 +02:00
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int in_addr = 0x20010000; // place input samples in the SPI memory
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int out_addr = 0x20210000;
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2021-03-04 11:19:35 +01:00
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int fpga_address_in = 0x10000000;
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int fpga_address_out = 0x20000000;
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2021-03-31 16:22:08 +02:00
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// inject SPN input data
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spn_checker::input_addr_reg() = in_addr;
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spn_checker::num_input_samples_reg() = sample_bytes * step * iterations;
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spn_checker::start_data_trans_reg() = 1;
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spn_checker::output_addr_reg() = out_addr;
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2021-03-04 11:19:35 +01:00
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//run_xspn(in_addr, out_addr);
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for (int k = 0; k < iterations*step; k+=step) {
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fpga_dma(1, fpga_address_in, in_addr, step * sample_bytes);
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run_xspn(fpga_address_in, fpga_address_out, step, in_beats, out_beats);
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wait_for_interrupt();
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spn::interrupt_reg() = 1;
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2021-03-04 11:19:35 +01:00
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printf("XSPN finished\n");
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fpga_dma(0, fpga_address_out, out_addr, step * result_bytes);
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spn_checker::offset_reg() = k;
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spn_checker::length_reg() = step;
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spn_checker::start_result_check_reg() = 1;
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2021-03-04 11:19:35 +01:00
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2021-03-31 16:22:08 +02:00
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in_addr += step * sample_bytes; // 5 bytes in each sample
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2021-03-04 11:19:35 +01:00
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}
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return 0;
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}
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