482 lines
13 KiB
Plaintext
482 lines
13 KiB
Plaintext
/*************************************************************************
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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 - Madison Cotteret
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* Copyright (c) 2022 University of Groningen - Hugh Greatorex
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* Copyright (c) 2022 University of Groningen - Michele Mastella
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* Copyright (c) 2021 Rajit Manohar
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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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import "../../dataflow_neuro/cell_lib_async.act";
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import "../../dataflow_neuro/cell_lib_std.act";
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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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/*
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* Build an OR-gate tree (NOR/NAND/optional INV)
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*/
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export deftype power (bool?! vdd, vss) { }
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export template<pint N>
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defproc ortree (bool? in[N]; bool! out; power supply)
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{
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bool tout;
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{ N > 0 : "What?" };
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[N = 1 -> BUF_X1 b(.vss=supply.vss, .vdd = supply.vdd, .a = in[0], .y = out);
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[] N > 1 ->
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pint i, end, j;
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i = 0;
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end = N-1;
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pint lenTree2Count, lenTree3Count;
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lenTree2Count = 0;
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lenTree3Count = 0;
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/* Pre"calculate" the number of C cells required, look below if confused */
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*[ i != end ->
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j = 0;
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*[ i < end ->
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j = j + 1;
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[ i+1 >= end ->
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i = end;
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lenTree2Count = lenTree2Count +1;
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[] i+2 >= end ->
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i = end;
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lenTree3Count = lenTree3Count +1;
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[] else ->
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i = i + 2;
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lenTree2Count = lenTree2Count +1;
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]
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]
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/*-- update range that has to be combined --*/
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i = end+1;
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end = end+j;
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j = 0;
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]
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/* array that holds ALL the nodes in the completion tree */
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bool tmp[end+1];
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(k:N:tmp[k] = in[k];)
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/* array to hold the actual C-elments, either A2C or A3C */
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[lenTree2Count > 0 ->
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OR2_X1 or2s[lenTree2Count];
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]
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[lenTree3Count > 0 ->
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OR3_X1 or3s[lenTree3Count];
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]
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(h:lenTree2Count:or2s[h].vdd = supply.vdd;)
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(h:lenTree3Count:or3s[h].vdd = supply.vdd;)
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(h:lenTree2Count:or2s[h].vss = supply.vss;)
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(h:lenTree3Count:or3s[h].vss = supply.vss;)
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/* Reset the variables we just stole lol */
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i = 0;
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end = N-1;
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j = 0;
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pint tree2Index = 0;
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pint tree3Index = 0;
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/* Invariant: i <= end */
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*[ i != end ->
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/*
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* Invariant: tmp[i..end] has the current signals that need to be
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* combined together, and "isinv" specifies if they are the inverted
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* sense or not
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*/
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j = 0;
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*[ i < end ->
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/*-- there are still signals that need to be combined --*/
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j = j + 1;
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[ i+1 >= end ->
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/*-- last piece: use either a 2 input C-element --*/
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or2s[tree2Index].a = tmp[i];
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or2s[tree2Index].b = tmp[i+1];
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or2s[tree2Index].y = tmp[end+j];
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tree2Index = tree2Index +1;
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i = end;
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[] i+2 >= end ->
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/*-- last piece: use either a 3 input C-element --*/
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or3s[tree3Index].a = tmp[i];
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or3s[tree3Index].b = tmp[i+1];
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or3s[tree3Index].c = tmp[i+2];
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or3s[tree3Index].y = tmp[end+j];
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tree3Index = tree3Index +1;
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i = end;
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[] else ->
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/*-- more to come; so use a two input C-element --*/
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or2s[tree2Index].a = tmp[i];
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or2s[tree2Index].b = tmp[i+1];
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or2s[tree2Index].y = tmp[end+j];
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tree2Index = tree2Index +1;
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i = i + 2;
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]
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]
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/*-- update range that has to be combined --*/
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i = end+1;
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end = end+j;
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j = 0;
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]
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out = tmp[end];
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]
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}
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export template<pint N>
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defproc andtree (bool? in[N]; bool! out; power supply)
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{
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bool tout;
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{ N > 0 : "What?" };
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[N = 1 -> BUF_X1 b(.vss=supply.vss, .vdd = supply.vdd, .a = in[0], .y = out);
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[] N > 1 ->
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pint i, end, j;
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i = 0;
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end = N-1;
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pint lenTree2Count, lenTree3Count;
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lenTree2Count = 0;
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lenTree3Count = 0;
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/* Pre"calculate" the number of C cells required, look below if confused */
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*[ i != end ->
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j = 0;
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*[ i < end ->
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j = j + 1;
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[ i+1 >= end ->
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i = end;
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lenTree2Count = lenTree2Count +1;
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[] i+2 >= end ->
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i = end;
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lenTree3Count = lenTree3Count +1;
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[] else ->
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i = i + 2;
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lenTree2Count = lenTree2Count +1;
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]
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]
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/*-- update range that has to be combined --*/
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i = end+1;
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end = end+j;
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j = 0;
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]
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/* array that holds ALL the nodes in the completion tree */
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bool tmp[end+1];
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(k:N:tmp[k] = in[k];)
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/* array to hold the actual C-elments, either A2C or A3C */
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[lenTree2Count > 0 ->
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AND2_X1 and2s[lenTree2Count];
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]
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[lenTree3Count > 0 ->
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AND3_X1 and3s[lenTree3Count];
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]
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(h:lenTree2Count:and2s[h].vdd = supply.vdd;)
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(h:lenTree3Count:and3s[h].vdd = supply.vdd;)
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(h:lenTree2Count:and2s[h].vss = supply.vss;)
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(h:lenTree3Count:and3s[h].vss = supply.vss;)
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/* Reset the variables we just stole lol */
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i = 0;
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end = N-1;
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j = 0;
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pint tree2Index = 0;
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pint tree3Index = 0;
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/* Invariant: i <= end */
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*[ i != end ->
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/*
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* Invariant: tmp[i..end] has the current signals that need to be
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* combined together, and "isinv" specifies if they are the inverted
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* sense or not
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*/
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j = 0;
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*[ i < end ->
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/*-- there are still signals that need to be combined --*/
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j = j + 1;
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[ i+1 >= end ->
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/*-- last piece: use either a 2 input C-element --*/
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and2s[tree2Index].a = tmp[i];
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and2s[tree2Index].b = tmp[i+1];
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and2s[tree2Index].y = tmp[end+j];
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tree2Index = tree2Index +1;
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i = end;
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[] i+2 >= end ->
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/*-- last piece: use either a 3 input C-element --*/
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and3s[tree3Index].a = tmp[i];
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and3s[tree3Index].b = tmp[i+1];
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and3s[tree3Index].c = tmp[i+2];
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and3s[tree3Index].y = tmp[end+j];
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tree3Index = tree3Index +1;
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i = end;
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[] else ->
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/*-- more to come; so use a two input C-element --*/
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and2s[tree2Index].a = tmp[i];
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and2s[tree2Index].b = tmp[i+1];
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and2s[tree2Index].y = tmp[end+j];
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tree2Index = tree2Index +1;
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i = i + 2;
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]
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]
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/*-- update range that has to be combined --*/
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i = end+1;
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end = end+j;
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j = 0;
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]
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out = tmp[end];
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]
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}
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/*
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* Build a completion tree using a combination of 2-input and 3-input
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* C-elements
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*/
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export template<pint N>
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defproc ctree (bool? in[N]; bool! out; power supply)
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{
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bool tout;
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{ N > 0 : "What?" };
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bool meaningless_var;
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[N = 1 -> BUF_X1 b(.vss=supply.vss, .vdd = supply.vdd, .a = in[0], .y = out);
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[] N > 1 ->
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pint i, end, j;
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i = 0;
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end = N-1;
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pint lenTree2Count, lenTree3Count;
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lenTree2Count = 0;
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lenTree3Count = 0;
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/* Pre"calculate" the number of C cells required, look below if confused */
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*[ i != end ->
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j = 0;
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*[ i < end ->
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j = j + 1;
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[ i+1 >= end ->
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i = end;
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lenTree2Count = lenTree2Count +1;
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[] i+2 >= end ->
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i = end;
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lenTree3Count = lenTree3Count +1;
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[] else ->
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i = i + 2;
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lenTree2Count = lenTree2Count +1;
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]
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]
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/*-- update range that has to be combined --*/
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i = end+1;
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end = end+j;
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]
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/* array that holds ALL the nodes in the completion tree */
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bool tmp[end+1];
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// Connecting the first nodes to the input
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(l:N:
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tmp[l] = in[l];
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)
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/* array to hold the actual C-elments, either A2C or A3C */
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[lenTree2Count > 0 ->
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A_2C_B_X1 C2Els[lenTree2Count];
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]
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[lenTree3Count > 0 ->
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A_3C_B_X1 C3Els[lenTree3Count];
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]
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(h:lenTree2Count:C2Els[h].vdd = supply.vdd;)
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(h:lenTree3Count:C3Els[h].vdd = supply.vdd;)
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(h:lenTree2Count:C2Els[h].vss = supply.vss;)
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(h:lenTree3Count:C3Els[h].vss = supply.vss;)
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/* Reset the variables we just stole lol */
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i = 0;
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end = N-1;
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j = 0;
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pint tree2Index = 0;
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pint tree3Index = 0;
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/* Invariant: i <= end */
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*[ i != end ->
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/*
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* Invariant: tmp[i..end] has the current signals that need to be
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* combined together, and "isinv" specifies if they are the inverted
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* sense or not
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*/
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j = 0;
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*[ i < end ->
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/*-- there are still signals that need to be combined --*/
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j = j + 1;
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[ i+1 >= end ->
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/*-- last piece: use either a 2 input C-element --*/
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C2Els[tree2Index].c1 = tmp[i];
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C2Els[tree2Index].c2 = tmp[i+1];
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C2Els[tree2Index].y = tmp[end+j];
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tree2Index = tree2Index +1;
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i = end;
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[] i+2 >= end ->
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/*-- last piece: use either a 3 input C-element --*/
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C3Els[tree3Index].c1 = tmp[i];
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C3Els[tree3Index].c2 = tmp[i+1];
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C3Els[tree3Index].c3 = tmp[i+2];
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C3Els[tree3Index].y = tmp[end+j];
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tree3Index = tree3Index +1;
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i = end;
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[] else ->
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/*-- more to come; so use a two input C-element --*/
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C2Els[tree2Index].c1 = tmp[i];
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C2Els[tree2Index].c2 = tmp[i+1];
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C2Els[tree2Index].y = tmp[end+j];
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tree2Index = tree2Index +1;
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i = i + 2;
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]
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]
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/*-- update range that has to be combined --*/
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i = end+1;
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end = end+j;
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j = 0;
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]
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out = tmp[end];
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]
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}
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export template<pint N>
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defproc vtree (std::data::Mx1of2?<N> in; bool! out; power supply)
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{
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// OR layer for making OR between true and false of in (they are then sent to Ctree)
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OR2_X1 OR2_tf[N];
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ctree<N> ct;
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(l:N:
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OR2_tf[l].a = in.d[l].t;
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OR2_tf[l].b = in.d[l].f;
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OR2_tf[l].y = ct.in[l];
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OR2_tf[l].vdd = supply.vdd;
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OR2_tf[l].vss = supply.vss;
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)
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ct.supply = supply;
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out = ct.out;
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}
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export template<pint N>
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defproc sigbuf (bool? in; bool! out[N]; power supply)
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{
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{ N >= 0 : "sigbuf: parameter error" };
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// { N <= 43 : "sigbuf: parameter error, N too big" };
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/* -- just use in sized driver here -- */
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[ N <= 4 ->
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BUF_X1 buf1 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 5 & N <= 7 ->
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BUF_X2 buf2 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 8 & N <= 10 ->
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BUF_X3 buf3 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 11 & N <= 14 ->
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BUF_X4 buf4 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 15 & N <= 18 ->
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BUF_X6 buf6 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 19 & N <= 29 ->
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BUF_X8 buf8 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 30 & N<= 48->
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BUF_X12 buf12 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 49 & N <= 64 ->
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BUF_X16 buf16 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 65 & N <= 96 ->
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BUF_X24 buf24 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 97 ->
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BUF_X32 buf32 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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// [] N >= 129 & N <=192 ->
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// BUF_X48 buf48 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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// [] N >= 193 & N <= 256->
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// BUF_X64 buf64 (.a = in, .y = out[0], .vdd = supply.vdd, .vss = supply.vss);
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]
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(i:1..N-1:out[i]=out[0];)
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}
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//Sigbuf in which there is only 1 output. Made for outputs that cannot have multiple wires.
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export template<pint N>
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defproc sigbuf_1output (bool? in; bool! out; power supply)
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{
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{ N >= 0 : "sigbuf: parameter error" };
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{ N <= 43 : "sigbuf: parameter error, N too big" };
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/* -- just use in sized driver here -- */
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[ N <= 4 ->
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BUF_X1 buf1 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 5 & N <= 7 ->
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BUF_X2 buf2 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 8 & N <= 10 ->
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BUF_X3 buf3 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 11 & N <= 14 ->
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BUF_X4 buf4 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 15 & N <= 18 ->
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BUF_X6 buf6 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 19 & N <= 29 ->
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BUF_X8 buf8 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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[] N >= 30 & N <= 42 ->
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BUF_X12 buf12 (.a = in, .y = out, .vdd = supply.vdd, .vss = supply.vss);
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]
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}
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}}
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