2022-03-04 11:44:00 +01:00
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/*************************************************************************
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*
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* This file is part of ACT dataflow neuro library
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*
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* Copyright (c) 2022 University of Groningen - Ole Richter
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* Copyright (c) 2022 University of Groningen - Michele Mastella
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* Copyright (c) 2022 University of Groningen - Hugh Greatorex
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* Copyright (c) 2022 University of Groningen - Madison Cotteret
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*
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*
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* This source describes Open Hardware and is licensed under the CERN-OHL-W v2 or later
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*
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* You may redistribute and modify this documentation and make products
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* using it under the terms of the CERN-OHL-W v2 (https:/cern.ch/cern-ohl).
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* This documentation is distributed WITHOUT ANY EXPRESS OR IMPLIED
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* WARRANTY, INCLUDING OF MERCHANTABILITY, SATISFACTORY QUALITY
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* AND FITNESS FOR A PARTICULAR PURPOSE. Please see the CERN-OHL-W v2
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* for applicable conditions.
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*
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* Source location: https://git.web.rug.nl/bics/actlib_dataflow_neuro
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*
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* As per CERN-OHL-W v2 section 4.1, should You produce hardware based on
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* these sources, You must maintain the Source Location visible in its
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* documentation.
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*
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**************************************************************************
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*/
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2022-03-04 19:04:11 +01:00
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2022-03-04 11:44:00 +01:00
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import "../../dataflow_neuro/cell_lib_async.act";
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import "../../dataflow_neuro/cell_lib_std.act";
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import "../../dataflow_neuro/treegates.act";
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import "../../dataflow_neuro/primitives.act";
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import "../../dataflow_neuro/coders.act";
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// import tmpl::dataflow_neuro;
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// import tmpl::dataflow_neuro;
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import std::channel;
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open std::channel;
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namespace tmpl {
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namespace dataflow_neuro {
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2022-03-09 16:44:44 +01:00
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// Circuit for storing registers using AER
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2022-03-04 11:44:00 +01:00
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// The block has the parameters:
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2022-03-07 16:36:01 +01:00
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// lognw -> log2(number of words), parameters you can store
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// wl -> word length, length of each word
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// N_dly_cfg -> the number of config bits in the ACK delay line
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// The block has the pins:
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// in -> input data,
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// - the first bit is write/read_B
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// - the next lognw bits describe the location,
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// - the last wl the word to write
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// data -> the data saved in the flip flop, sized wl x nw
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export template<pint lognw,wl,N_dly_cfg>
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defproc register_w (avMx1of2<1+lognw+wl> in; d1of<wl> data[1<<lognw]; power supply; bool? reset_B,reset_mem_B,dly_cfg[N_dly_cfg]){
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2022-03-07 16:36:01 +01:00
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bool _in_v_temp,_in_a_temp,_clock_temp,_clock,_clock_temp_inv;
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pint nw = 1<<lognw;
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//Validation of the input
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vtree<1+lognw+wl> val_input(.in = in.d,.out = _in_v_temp, .supply = supply);
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sigbuf_1output<4> val_input_X(.in = _in_v_temp,.out = in.v,.supply = supply);
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// Generation of the fake clock pulse (inverted because the ff clocks are low_active)
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2022-03-05 09:19:19 +01:00
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delayprog<N_dly_cfg> clk_dly(.in = _in_v_temp, .out = _clock_temp,.s = dly_cfg, .supply = supply);
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INV_X1 inv_clk(.a = _clock_temp,.y = _clock_temp_inv,.vdd = supply.vdd,.vss = supply.vss);
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sigbuf_1output<4> clk_X(.in = _clock_temp,.out = _clock,.supply = supply);
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// Sending back to the ackowledge
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delayprog<N_dly_cfg> ack_dly(.in = _clock_temp_inv, .out = _in_a_temp,.s = dly_cfg, .supply = supply);
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2022-03-05 09:19:19 +01:00
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sigbuf_1output<4> ack_input_X(.in = _in_a_temp,.out = in.a,.supply = supply);
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//Reset Buffers
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bool _reset_BX,_reset_mem_BX,_reset_mem_BXX[nw*wl];
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BUF_X1 reset_buf_BX(.a=reset_B, .y=_reset_BX,.vdd=supply.vdd,.vss=supply.vss);
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BUF_X1 reset_buf_BXX(.a=reset_mem_B, .y=_reset_mem_BX,.vdd=supply.vdd,.vss=supply.vss);
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sigbuf<nw*wl> reset_bufarray(.in=_reset_mem_BX, .out=_reset_mem_BXX,.supply=supply);
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// Creating the different flip flop arrays
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bool _out_encoder[nw],_clock_word_temp[nw],_clock_word[nw],_clock_buffer_out[nw*wl];
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andtree<lognw> atree[nw];
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AND2_X1 and_encoder[nw];
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sigbuf<wl> clock_buffer[nw];
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DFFQ_R_X1 ff[nw*wl];
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pint bitval;
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(k:nw:atree[k].supply = supply;)
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(word_idx:nw:
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// Decoding the bit pattern to understand which word we are looking at
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(pin_idx:lognw:
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bitval = (word_idx & ( 1 << pin_idx )) >> pin_idx; // Get binary digit of integer i, column j
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[bitval = 1 ->
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atree[word_idx].in[pin_idx] = in.d.d[pin_idx+wl].t;
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[] bitval = 0 ->
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atree[word_idx].in[pin_idx] = in.d.d[pin_idx+wl].f;
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[]bitval >= 2 -> {false : "fuck"};
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]
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)
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// Activating the fake clock for the right word
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atree[word_idx].out = _out_encoder[word_idx];
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and_encoder[word_idx].a = _out_encoder[word_idx];
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and_encoder[word_idx].b = _clock;
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and_encoder[word_idx].y = _clock_word_temp[word_idx];
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and_encoder[word_idx].vdd = supply.vdd;
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and_encoder[word_idx].vss = supply.vss;
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clock_buffer[word_idx].in = _clock_word_temp[word_idx];
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clock_buffer[word_idx].supply = supply;
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// Describing all the FF and their connection
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(bit_idx:wl:
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ff[bit_idx+word_idx*(wl)].clk_B = clock_buffer[word_idx].out[bit_idx];
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ff[bit_idx+word_idx*(wl)].d = in.d.d[bit_idx].t;
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ff[bit_idx+word_idx*(wl)].q = data[word_idx].d[bit_idx];
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ff[bit_idx+word_idx*(wl)].reset_B = _reset_mem_BXX[bit_idx+word_idx*(wl)];
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ff[bit_idx+word_idx*(wl)].vdd = supply.vdd;
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ff[bit_idx+word_idx*(wl)].vss = supply.vss;
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2022-03-07 07:15:53 +01:00
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)
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)
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}
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2022-03-09 16:44:44 +01:00
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// Circuit for storing and reading registers using AER
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// The block has the parameters:
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// lognw -> log2(number of words), parameters you can store
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// wl -> word length, length of each word
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// N_dly_cfg -> the number of config bits in the ACK delay line
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// The block has the pins:
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// in -> input data,
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// - the MSB is write/read_B
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// - the next MSB bits (size lognw) are the location,
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// - the LSB (size wl) are the word to write
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// out -> in case a reading phase is required, the output is used to show the stored data
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// - the MSB bits (size lognw) tell the read register
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// - the LSB bits (size wl) tell the word read
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// data -> the data saved in the flip flop, sized wl x nw
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export template<pint lognw,wl,N_dly_cfg>
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defproc register_rw (avMx1of2<1+lognw+wl> in; avMx1of2<lognw+wl> out; d1of<wl> data[1<<lognw]; power supply; bool? reset_B,reset_mem_B,dly_cfg[N_dly_cfg]){
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pint nw = 1<<lognw;
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bool _in_v_temp,_in_a_temp,_clock_temp,_clock[nw],_clock_temp_inv, _in_a_write, _in_a_read;
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//Validation of the input
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vtree<1+lognw+wl> val_input(.in = in.d,.out = _in_v_temp, .supply = supply);
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sigbuf_1output<12> val_input_X(.in = _in_v_temp,.out = in.v,.supply = supply);
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// Acknowledgment
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OR2_X1 ack_readwrite(.a = _in_a_write,.b = _in_a_read,.y = _in_a_temp,.vdd = supply.vdd,.vss = supply.vss);
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sigbuf_1output<12> ack_input_X(.in = _in_a_temp,.out = in.a,.supply = supply);
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// WRITE
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// Generation of the fake clock pulse if write is HIGH (inverted because the ff clocks are low_active)
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bool _in_v_temp_write;
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AND2_X1 clk_switch(.a = _in_v_temp,.b = in.d.d[lognw+wl].f, .y = _in_v_temp_write,.vdd = supply.vdd,.vss = supply.vss);
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delayprog<N_dly_cfg> clk_dly(.in = _in_v_temp_write, .out = _clock_temp,.s = dly_cfg, .supply = supply);
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2022-03-09 13:05:08 +01:00
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INV_X1 inv_clk(.a = _clock_temp,.y = _clock_temp_inv,.vdd = supply.vdd,.vss = supply.vss);
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2022-03-14 17:15:27 +01:00
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sigbuf<nw> clk_X(.in = _clock_temp_inv,.out = _clock,.supply = supply);
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sigbuf<wl> clock_buffer[nw];
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bool _clock_word_temp[nw],_clock_word[nw],_clock_buffer_out[nw*wl];
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// Sending back to the ackowledge
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bool _in_a_write_temp;
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delayprog<N_dly_cfg> ack_dly(.in = _clock_temp, .out = _in_a_write_temp,.s = dly_cfg, .supply = supply);
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AND2_X1 ack_write_and(.a = in.d.d[lognw+wl].f,.b = _in_a_write_temp,.y = _in_a_write,.vdd = supply.vdd, .vss = supply.vss);
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// READ
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//Outputing the word to read
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AND2_X1 word_to_read[nw];
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sigbuf<wl*2> word_to_read_X[nw];
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ortree<nw> bitselector_t[wl];
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ortree<nw> bitselector_f[wl];
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AND2_X1 word_selector_t[nw*wl];
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AND2_X1 word_selector_f[nw*wl];
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bool _out_word_to_read[2*nw*wl];
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buffer_s<lognw+wl> output_buf(.out = out,.supply = supply, .reset_B = reset_B);
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AND2_X1 address_propagator_f[lognw],address_propagator_t[lognw];
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// Outputting the address if the read is true
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(i:lognw:
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address_propagator_t[i].a = in.d.d[lognw+wl].t;
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address_propagator_t[i].b = in.d.d[i+wl].t;
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address_propagator_t[i].y = output_buf.in.d.d[i+wl].t;
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address_propagator_t[i].vdd = supply.vdd;
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address_propagator_t[i].vss = supply.vss;
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address_propagator_f[i].a = in.d.d[lognw+wl].t;
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address_propagator_f[i].b = in.d.d[i+wl].f;
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address_propagator_f[i].y = output_buf.in.d.d[i+wl].f;
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address_propagator_f[i].vdd = supply.vdd;
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address_propagator_f[i].vss = supply.vss;
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)
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AND2_X1 ack_read_and(.a = in.d.d[lognw+wl].t,.b = output_buf.in.a,.y = _in_a_read,.vdd = supply.vdd, .vss = supply.vss);
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2022-03-09 13:05:08 +01:00
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//Reset Buffers
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2022-03-15 08:16:59 +01:00
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bool _reset_BX, _reset_BXX[nw],_reset_mem_BX,_reset_mem_BXX[nw*wl];
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2022-03-09 13:05:08 +01:00
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BUF_X1 reset_buf_BX(.a=reset_B, .y=_reset_BX,.vdd=supply.vdd,.vss=supply.vss);
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BUF_X1 reset_buf_BXX(.a=reset_mem_B, .y=_reset_mem_BX,.vdd=supply.vdd,.vss=supply.vss);
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2022-03-15 08:16:59 +01:00
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sigbuf<nw*wl> reset_mem_bufarray(.in=_reset_mem_BX, .out=_reset_mem_BXX,.supply=supply);
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sigbuf<nw> reset_bufarray(.in=_reset_BX, .out=_reset_BXX,.supply=supply);
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2022-03-14 17:15:27 +01:00
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//Creating the encoder
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2022-03-09 13:05:08 +01:00
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andtree<lognw> atree[nw];
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2022-03-15 08:16:59 +01:00
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OR2_X1 or_encoder[nw];
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INV_X1 inv_encoder[nw];
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2022-03-14 17:15:27 +01:00
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// Creating the different flip flop arrays
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bool _out_encoder[nw];
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DFFQ_R_X1 ff[nw*wl];
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// For loop for assigning the different components
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2022-03-09 13:05:08 +01:00
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pint bitval;
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(k:nw:atree[k].supply = supply;)
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(word_idx:nw:
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// Decoding the bit pattern to understand which word we are looking at
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(pin_idx:lognw:
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bitval = (word_idx & ( 1 << pin_idx )) >> pin_idx; // Get binary digit of integer i, column j
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[bitval = 1 ->
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atree[word_idx].in[pin_idx] = in.d.d[pin_idx+wl].t;
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[] bitval = 0 ->
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atree[word_idx].in[pin_idx] = in.d.d[pin_idx+wl].f;
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[]bitval >= 2 -> {false : "fuck"};
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]
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)
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2022-03-09 16:44:44 +01:00
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// WRITE: Activating the fake clock for the right word
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2022-03-14 17:15:27 +01:00
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atree[word_idx].out = _out_encoder[word_idx];
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2022-03-15 08:16:59 +01:00
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inv_encoder[word_idx].a = _out_encoder[word_idx];
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inv_encoder[word_idx].y = or_encoder[word_idx].a;
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inv_encoder[word_idx].vdd = supply.vdd;
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inv_encoder[word_idx].vss = supply.vss;
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or_encoder[word_idx].b = _clock[word_idx];
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or_encoder[word_idx].y = _clock_word_temp[word_idx];
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or_encoder[word_idx].vdd = supply.vdd;
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or_encoder[word_idx].vss = supply.vss;
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2022-03-09 13:05:08 +01:00
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clock_buffer[word_idx].in = _clock_word_temp[word_idx];
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clock_buffer[word_idx].supply = supply;
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2022-03-14 17:15:27 +01:00
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// READ: Selecting the right word to read if read is high
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word_to_read[word_idx].a = in.d.d[lognw+wl].t;
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word_to_read[word_idx].b = _out_encoder[word_idx];
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word_to_read[word_idx].y = word_to_read_X[word_idx].in;
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word_to_read[word_idx].vdd = supply.vdd;
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word_to_read[word_idx].vss = supply.vss;
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word_to_read_X[word_idx].supply = supply;
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2022-03-09 16:44:44 +01:00
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2022-03-14 17:15:27 +01:00
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(bit_idx:wl:
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// Describing all the FF and their connection
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ff[bit_idx+word_idx*(wl)].clk_B = clock_buffer[word_idx].out[bit_idx];
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ff[bit_idx+word_idx*(wl)].d = in.d.d[bit_idx].t;
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ff[bit_idx+word_idx*(wl)].q = data[word_idx].d[bit_idx];
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ff[bit_idx+word_idx*(wl)].reset_B = _reset_mem_BXX[bit_idx+word_idx*(wl)];
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ff[bit_idx+word_idx*(wl)].vdd = supply.vdd;
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ff[bit_idx+word_idx*(wl)].vss = supply.vss;
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// READ: creating the selectors for propagating the right word
|
|
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word_to_read_X[word_idx].out[bit_idx] = word_selector_t[bit_idx+word_idx*(wl)].a;
|
|
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word_to_read_X[word_idx].out[bit_idx+wl] = word_selector_f[bit_idx+word_idx*(wl)].a;
|
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word_selector_t[bit_idx+word_idx*(wl)].b = ff[bit_idx+word_idx*(wl)].q;
|
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|
word_selector_t[bit_idx+word_idx*(wl)].y = bitselector_t[bit_idx].in[word_idx];
|
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word_selector_f[bit_idx+word_idx*(wl)].b = ff[bit_idx+word_idx*(wl)].q_B;
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word_selector_f[bit_idx+word_idx*(wl)].y = bitselector_f[bit_idx].in[word_idx];
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bitselector_t[bit_idx].out = output_buf.in.d.d[bit_idx].t;
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bitselector_f[bit_idx].out = output_buf.in.d.d[bit_idx].f;
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bitselector_t[bit_idx].supply = supply;
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|
|
bitselector_f[bit_idx].supply = supply;
|
2022-03-09 13:05:08 +01:00
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)
|
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|
|
)
|
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|
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}
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2022-03-14 17:15:27 +01:00
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|
|
|
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2022-03-04 11:44:00 +01:00
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}}
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