From 266993408a2b926ffefcf536feb92b36b11e398e Mon Sep 17 00:00:00 2001 From: Diego H Date: Fri, 13 Dec 2019 15:43:24 -0600 Subject: [PATCH 1/4] Refactoring memory attribute matching based on IEEE 1364.1 and Tool specific --- passes/memory/memory_bram.cc | 77 +++++++++++++++++++++++++++++++ techlibs/xilinx/xc7_xcu_brams.txt | 19 ++++++++ 2 files changed, 96 insertions(+) diff --git a/passes/memory/memory_bram.cc b/passes/memory/memory_bram.cc index aa8f94149..35cd0647a 100644 --- a/passes/memory/memory_bram.cc +++ b/passes/memory/memory_bram.cc @@ -327,6 +327,20 @@ struct rules_t continue; } + if (GetSize(tokens) >= 2 && tokens[0] == "attribute") { + for (int idx=1; idx<= GetSize(tokens)-1; idx++) { + size_t val = tokens[idx].find_first_of("!="); + if (val != std::string::npos) { + if (val == 0) { + data.attr_unmatch[RTLIL::escape_id(tokens[idx].substr(val+1))]; + } + else { + data.attr_match[RTLIL::escape_id(tokens[idx].substr(0, val))] = tokens[idx].substr(val+1); + } + } + } + continue; + } syntax_error(); } } @@ -813,6 +827,27 @@ grow_read_ports:; return false; } + if (!match.attr_match.empty()) { + for (auto iter: match.attr_match) { + auto it = cell->attributes.find(iter.first); + + if (iter.second.empty()) { + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); + return false; + } + + if (it != cell->attributes.end()) { + if (it->second == iter.second) + continue; + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); + return false; + } + continue; + } + } + if (mode == 1) return true; } @@ -997,6 +1032,7 @@ void handle_cell(Cell *cell, const rules_t &rules) log("Processing %s.%s:\n", log_id(cell->module), log_id(cell)); bool cell_init = !SigSpec(cell->getParam("\\INIT")).is_fully_undef(); + int access = 0; dict match_properties; match_properties["words"] = cell->getParam("\\SIZE").as_int(); @@ -1100,6 +1136,42 @@ void handle_cell(Cell *cell, const rules_t &rules) goto next_match_rule; } + for (auto iter: match.attr_unmatch) { + auto it = cell->attributes.find(iter.first); + + if (it != cell->attributes.end()) { + log(" Rule for bram type %s is rejected: requirement 'attribute %s' is met.\n", + log_id(match.name), iter.first.c_str()); + goto next_match_rule; + } + continue; + } + + if (!match.attr_match.empty()) { + for (auto iter: match.attr_match) { + int len=std::tuple_size::value; + auto it = cell->attributes.find(iter.first); + + if (iter.second.empty()) { + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); + continue; + } + + if (it != cell->attributes.end()) { + if (it->second == iter.second) + continue; + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); + } + access ++; + if (access == len) { + access = 0; + goto next_match_rule; + } + } + } + log(" Rule #%d for bram type %s (variant %d) accepted.\n", i+1, log_id(bram.name), bram.variant); if (or_next_if_better || !best_rule_cache.empty()) @@ -1225,6 +1297,11 @@ struct MemoryBramPass : public Pass { log(" dcells ....... number of cells in 'data-direction'\n"); log(" cells ........ total number of cells (acells*dcells*dups)\n"); log("\n"); + log("A match containing the condition 'attribute' followed by a name and optional\n"); + log("value requires that the memory contains the given attribute name and value\n"); + log("(if specified) or that the attribute is not present (prepending a '!')\n"); + log("or the value is empty (if value is not specified\n)."); + log("\n"); log("The interface for the created bram instances is derived from the bram\n"); log("description. Use 'techmap' to convert the created bram instances into\n"); log("instances of the actual bram cells of your target architecture.\n"); diff --git a/techlibs/xilinx/xc7_xcu_brams.txt b/techlibs/xilinx/xc7_xcu_brams.txt index b7c893ff7..a52dd9352 100644 --- a/techlibs/xilinx/xc7_xcu_brams.txt +++ b/techlibs/xilinx/xc7_xcu_brams.txt @@ -81,6 +81,7 @@ match $__XILINX_RAMB36_SDP min efficiency 5 shuffle_enable B make_transp + attribute !ram_style !logic_block or_next_if_better endmatch @@ -89,6 +90,14 @@ match $__XILINX_RAMB18_SDP min efficiency 5 shuffle_enable B make_transp + attribute !ram_style !logic_block + or_next_if_better +endmatch + +match $__XILINX_RAMB18_SDP + shuffle_enable B + make_transp + attribute ram_block=1 ram_style=block or_next_if_better endmatch @@ -97,6 +106,7 @@ match $__XILINX_RAMB36_TDP min efficiency 5 shuffle_enable B make_transp + attribute !ram_style !logic_block or_next_if_better endmatch @@ -105,4 +115,13 @@ match $__XILINX_RAMB18_TDP min efficiency 5 shuffle_enable B make_transp + attribute !ram_style !logic_block + or_next_if_better +endmatch + +match $__XILINX_RAMB18_TDP + min efficiency 5 + shuffle_enable B + make_transp + attribute ram_block=1 ram_style=block endmatch From b35559fc335181d7c8f8046fa17bf05550c21ba7 Mon Sep 17 00:00:00 2001 From: Diego H Date: Sun, 15 Dec 2019 23:33:09 -0600 Subject: [PATCH 2/4] Merging attribute rules into a single match block; Adding tests --- passes/memory/memory_bram.cc | 148 +- techlibs/xilinx/xc7_xcu_brams.txt | 30 +- .../memory_attributes/attributes_test.v | 88 + .../memory_attributes/attributes_test.ys | 47 + tests/arch/common/memory_attributes/log | 3238 +++++++++++++++++ 5 files changed, 3465 insertions(+), 86 deletions(-) create mode 100644 tests/arch/common/memory_attributes/attributes_test.v create mode 100644 tests/arch/common/memory_attributes/attributes_test.ys create mode 100644 tests/arch/common/memory_attributes/log diff --git a/passes/memory/memory_bram.cc b/passes/memory/memory_bram.cc index 35cd0647a..10b48e321 100644 --- a/passes/memory/memory_bram.cc +++ b/passes/memory/memory_bram.cc @@ -134,6 +134,9 @@ struct rules_t dict min_limits, max_limits; bool or_next_if_better, make_transp, make_outreg; char shuffle_enable; + dict>> attr_match; + pair attr_val; + dict attr_unmatch; }; dict> brams; @@ -328,19 +331,31 @@ struct rules_t } if (GetSize(tokens) >= 2 && tokens[0] == "attribute") { - for (int idx=1; idx<= GetSize(tokens)-1; idx++) { - size_t val = tokens[idx].find_first_of("!="); - if (val != std::string::npos) { - if (val == 0) { - data.attr_unmatch[RTLIL::escape_id(tokens[idx].substr(val+1))]; - } - else { - data.attr_match[RTLIL::escape_id(tokens[idx].substr(0, val))] = tokens[idx].substr(val+1); + if (GetSize(tokens) <=2) { + size_t notval = tokens[1].find("!"); + size_t val = tokens[1].find("="); + + if (notval != std::string::npos) { + if (val != std::string::npos) + data.attr_unmatch[RTLIL::escape_id(tokens[1].substr(1, val-1))] = tokens[1].substr(val+1); + else + data.attr_unmatch[RTLIL::escape_id(tokens[1].substr(notval+1))] = RTLIL::Const('1'); + } + continue; + } + + else if (GetSize(tokens) > 2) { + for (int idx=1; idx<= GetSize(tokens)-1; idx++) { + size_t val = tokens[idx].find("="); + if (val != std::string::npos) { + data.attr_val = make_pair(RTLIL::escape_id(tokens[idx].substr(0, val)), tokens[idx].substr(val+1)); + data.attr_match[RTLIL::escape_id(tokens[0])].push_back(data.attr_val); } } + continue; } - continue; } + syntax_error(); } } @@ -738,7 +753,7 @@ grow_read_ports:; if (match.make_transp && wr_ports <= 1) { pi.make_transp = true; if (pi.clocks != 0) { - if (wr_ports == 1 && wr_clkdom != clkdom) { + if (wr_ports == 1 && wr_clkdom != clkdom) { log(" Bram port %c%d.%d cannot have soft transparency logic added as read and write clock domains differ.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1); goto skip_bram_rport; } @@ -806,6 +821,27 @@ grow_read_ports:; log(" Updated properties: dups=%d waste=%d efficiency=%d\n", match_properties["dups"], match_properties["waste"], match_properties["efficiency"]); + for (auto& iter: match.attr_match) { + for (auto& iter: iter.second) { + auto it = cell->attributes.find(iter.first); + + if (iter.second.empty()) { + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), log_id(iter.first), iter.second.decode_string().c_str()); + return false; + } + + if (it != cell->attributes.end()) { + if (it->second == iter.second) + continue; + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), log_id(iter.first), iter.second.decode_string().c_str()); + return false; + } + return true; + } + } + for (auto it : match.min_limits) { if (!match_properties.count(it.first)) log_error("Unknown property '%s' in match rule for bram type %s.\n", @@ -827,27 +863,6 @@ grow_read_ports:; return false; } - if (!match.attr_match.empty()) { - for (auto iter: match.attr_match) { - auto it = cell->attributes.find(iter.first); - - if (iter.second.empty()) { - log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", - log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); - return false; - } - - if (it != cell->attributes.end()) { - if (it->second == iter.second) - continue; - log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", - log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); - return false; - } - continue; - } - } - if (mode == 1) return true; } @@ -1032,7 +1047,6 @@ void handle_cell(Cell *cell, const rules_t &rules) log("Processing %s.%s:\n", log_id(cell->module), log_id(cell)); bool cell_init = !SigSpec(cell->getParam("\\INIT")).is_fully_undef(); - int access = 0; dict match_properties; match_properties["words"] = cell->getParam("\\SIZE").as_int(); @@ -1110,6 +1124,39 @@ void handle_cell(Cell *cell, const rules_t &rules) goto next_match_rule; } + for (auto& iter: match.attr_match) { + for (auto& iter: iter.second) { + auto it = cell->attributes.find(iter.first); + + if (it != cell->attributes.end()) { + if (!it->second.empty()) { + if (it->second.decode_string().length() == 1) + it->second = it->second.as_string().back(); + if (!it->second.decode_string().compare(iter.second.decode_string())) + goto attribute_matched; + else + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), log_id(iter.first), iter.second.decode_string().c_str()); + } + } + } + } + + for (auto& iter: match.attr_unmatch) { + auto it = cell->attributes.find(iter.first); + + if (it != cell->attributes.end()) { + if (!it->second.empty()) { + if (it->second.decode_string().length() == 1) + it->second = it->second.as_string().back(); + if (!it->second.decode_string().compare(iter.second.decode_string())) + goto next_match_rule; + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), log_id(iter.first), iter.second.decode_string().c_str()); + } + } + } + for (auto it : match.min_limits) { if (it.first == "waste" || it.first == "dups" || it.first == "acells" || it.first == "dcells" || it.first == "cells") continue; @@ -1136,42 +1183,7 @@ void handle_cell(Cell *cell, const rules_t &rules) goto next_match_rule; } - for (auto iter: match.attr_unmatch) { - auto it = cell->attributes.find(iter.first); - - if (it != cell->attributes.end()) { - log(" Rule for bram type %s is rejected: requirement 'attribute %s' is met.\n", - log_id(match.name), iter.first.c_str()); - goto next_match_rule; - } - continue; - } - - if (!match.attr_match.empty()) { - for (auto iter: match.attr_match) { - int len=std::tuple_size::value; - auto it = cell->attributes.find(iter.first); - - if (iter.second.empty()) { - log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", - log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); - continue; - } - - if (it != cell->attributes.end()) { - if (it->second == iter.second) - continue; - log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", - log_id(match.name), iter.first.c_str(), iter.second.decode_string().c_str()); - } - access ++; - if (access == len) { - access = 0; - goto next_match_rule; - } - } - } - + attribute_matched: log(" Rule #%d for bram type %s (variant %d) accepted.\n", i+1, log_id(bram.name), bram.variant); if (or_next_if_better || !best_rule_cache.empty()) diff --git a/techlibs/xilinx/xc7_xcu_brams.txt b/techlibs/xilinx/xc7_xcu_brams.txt index a52dd9352..2d94ac4a8 100644 --- a/techlibs/xilinx/xc7_xcu_brams.txt +++ b/techlibs/xilinx/xc7_xcu_brams.txt @@ -77,51 +77,45 @@ endbram # https://www.xilinx.com/support/documentation/user_guides/ug473_7Series_Memory_Resources.pdf match $__XILINX_RAMB36_SDP + attribute ram_style=block ram_block=1 + attribute !ram_style=distributed + attribute !logic_block min bits 1024 min efficiency 5 shuffle_enable B make_transp - attribute !ram_style !logic_block or_next_if_better endmatch match $__XILINX_RAMB18_SDP + attribute ram_style=block ram_block=1 + attribute !ram_style=distributed + attribute !logic_block min bits 1024 min efficiency 5 shuffle_enable B make_transp - attribute !ram_style !logic_block - or_next_if_better -endmatch - -match $__XILINX_RAMB18_SDP - shuffle_enable B - make_transp - attribute ram_block=1 ram_style=block or_next_if_better endmatch match $__XILINX_RAMB36_TDP + attribute ram_style=block ram_block=1 + attribute !ram_style=distributed + attribute !logic_block min bits 1024 min efficiency 5 shuffle_enable B make_transp - attribute !ram_style !logic_block or_next_if_better endmatch match $__XILINX_RAMB18_TDP + attribute ram_style=block ram_block=1 + attribute !ram_style=distributed + attribute !logic_block min bits 1024 min efficiency 5 shuffle_enable B make_transp - attribute !ram_style !logic_block - or_next_if_better endmatch -match $__XILINX_RAMB18_TDP - min efficiency 5 - shuffle_enable B - make_transp - attribute ram_block=1 ram_style=block -endmatch diff --git a/tests/arch/common/memory_attributes/attributes_test.v b/tests/arch/common/memory_attributes/attributes_test.v new file mode 100644 index 000000000..275800dd0 --- /dev/null +++ b/tests/arch/common/memory_attributes/attributes_test.v @@ -0,0 +1,88 @@ +`default_nettype none +module block_ram #(parameter DATA_WIDTH=4, ADDRESS_WIDTH=10) + (input wire write_enable, clk, + input wire [DATA_WIDTH-1:0] data_in, + input wire [ADDRESS_WIDTH-1:0] address_in, + output wire [DATA_WIDTH-1:0] data_out); + + localparam WORD = (DATA_WIDTH-1); + localparam DEPTH = (2**ADDRESS_WIDTH-1); + + reg [WORD:0] data_out_r; + reg [WORD:0] memory [0:DEPTH]; + + always @(posedge clk) begin + if (write_enable) + memory[address_in] <= data_in; + data_out_r <= memory[address_in]; + end + + assign data_out = data_out_r; +endmodule // block_ram + +`default_nettype none +module distributed_ram #(parameter DATA_WIDTH=8, ADDRESS_WIDTH=4) + (input wire write_enable, clk, + input wire [DATA_WIDTH-1:0] data_in, + input wire [ADDRESS_WIDTH-1:0] address_in, + output wire [DATA_WIDTH-1:0] data_out); + + localparam WORD = (DATA_WIDTH-1); + localparam DEPTH = (2**ADDRESS_WIDTH-1); + + reg [WORD:0] data_out_r; + reg [WORD:0] memory [0:DEPTH]; + + always @(posedge clk) begin + if (write_enable) + memory[address_in] <= data_in; + data_out_r <= memory[address_in]; + end + + assign data_out = data_out_r; +endmodule // distributed_ram + +`default_nettype none +module distributed_ram_manual #(parameter DATA_WIDTH=8, ADDRESS_WIDTH=4) + (input wire write_enable, clk, + input wire [DATA_WIDTH-1:0] data_in, + input wire [ADDRESS_WIDTH-1:0] address_in, + output wire [DATA_WIDTH-1:0] data_out); + + localparam WORD = (DATA_WIDTH-1); + localparam DEPTH = (2**ADDRESS_WIDTH-1); + + reg [WORD:0] data_out_r; + (* ram_style = "block" *) reg [WORD:0] memory [0:DEPTH]; + + always @(posedge clk) begin + if (write_enable) + memory[address_in] <= data_in; + data_out_r <= memory[address_in]; + end + + assign data_out = data_out_r; +endmodule // distributed_ram + +`default_nettype none +module distributed_ram_manual_syn #(parameter DATA_WIDTH=8, ADDRESS_WIDTH=4) + (input wire write_enable, clk, + input wire [DATA_WIDTH-1:0] data_in, + input wire [ADDRESS_WIDTH-1:0] address_in, + output wire [DATA_WIDTH-1:0] data_out); + + localparam WORD = (DATA_WIDTH-1); + localparam DEPTH = (2**ADDRESS_WIDTH-1); + + reg [WORD:0] data_out_r; + (* synthesis, ram_block *) reg [WORD:0] memory [0:DEPTH]; + + always @(posedge clk) begin + if (write_enable) + memory[address_in] <= data_in; + data_out_r <= memory[address_in]; + end + + assign data_out = data_out_r; +endmodule // distributed_ram + diff --git a/tests/arch/common/memory_attributes/attributes_test.ys b/tests/arch/common/memory_attributes/attributes_test.ys new file mode 100644 index 000000000..4e06a35e7 --- /dev/null +++ b/tests/arch/common/memory_attributes/attributes_test.ys @@ -0,0 +1,47 @@ +# Check that blockram memory without parameters is not modified +read_verilog attributes_test.v +hierarchy -top block_ram +synth_xilinx -top block_ram +cd block_ram # Constrain all select calls below inside the top module +select -assert-count 1 t:RAMB18E1 + +# Check that distributed memory without parameters is not modified +design -reset +read_verilog attributes_test.v +hierarchy -top distributed_ram +synth_xilinx -top distributed_ram +cd distributed_ram # Constrain all select calls below inside the top module +select -assert-count 8 t:RAM32X1D + +# Set ram_style distributed to blockram memory; will be implemented as distributed +design -reset +read_verilog attributes_test.v +prep +setattr -mod -set ram_style "distributed" block_ram +synth_xilinx -top block_ram +cd block_ram # Constrain all select calls below inside the top module +select -assert-count 32 t:RAM128X1D + +# Set synthesis, logic_block to blockram memory; will be implemented as distributed +design -reset +read_verilog attributes_test.v +prep +setattr -mod -set logic_block 1 block_ram +synth_xilinx -top block_ram +cd block_ram # Constrain all select calls below inside the top module +select -assert-count 0 t:RAMB18E1 +select -assert-count 32 t:RAM128X1D + +# Set ram_style block to a distributed memory; will be implemented as blockram +design -reset +read_verilog attributes_test.v +synth_xilinx -top distributed_ram_manual +cd distributed_ram_manual # Constrain all select calls below inside the top module +select -assert-count 1 t:RAMB18E1 + +# Set synthesis, ram_block block to a distributed memory; will be implemented as blockram +design -reset +read_verilog attributes_test.v +synth_xilinx -top distributed_ram_manual_syn +cd distributed_ram_manual_syn # Constrain all select calls below inside the top module +select -assert-count 1 t:RAMB18E1 diff --git a/tests/arch/common/memory_attributes/log b/tests/arch/common/memory_attributes/log new file mode 100644 index 000000000..5d526e661 --- /dev/null +++ b/tests/arch/common/memory_attributes/log @@ -0,0 +1,3238 @@ + + /----------------------------------------------------------------------------\ + | | + | yosys -- Yosys Open SYnthesis Suite | + | | + | Copyright (C) 2012 - 2019 Clifford Wolf | + | | + | Permission to use, copy, modify, and/or distribute this software for any | + | purpose with or without fee is hereby granted, provided that the above | + | copyright notice and this permission notice appear in all copies. | + | | + | THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES | + | WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF | + | MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR | + | ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES | + | WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN | + | ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF | + | OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. | + | | + \----------------------------------------------------------------------------/ + + Yosys 0.9+932 (git sha1 26699340, clang 6.0.0-1ubuntu2 -fPIC -Os) + + +-- Executing script file `attributes_test.ys' -- + +1. Executing Verilog-2005 frontend: attributes_test.v +Parsing Verilog input from `attributes_test.v' to AST representation. +Generating RTLIL representation for module `\block_ram'. +Generating RTLIL representation for module `\distributed_ram'. +Generating RTLIL representation for module `\distributed_ram_manual'. +Generating RTLIL representation for module `\distributed_ram_manual_syn'. +Successfully finished Verilog frontend. + +2. Executing HIERARCHY pass (managing design hierarchy). + +2.1. Analyzing design hierarchy.. +Top module: \block_ram + +2.2. Analyzing design hierarchy.. +Top module: \block_ram +Removing unused module `\distributed_ram_manual_syn'. +Removing unused module `\distributed_ram_manual'. +Removing unused module `\distributed_ram'. +Removed 3 unused modules. + +3. Executing SYNTH_XILINX pass. + +3.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v' to AST representation. +Generating RTLIL representation for module `\VCC'. +Generating RTLIL representation for module `\GND'. +Generating RTLIL representation for module `\IBUF'. +Generating RTLIL representation for module `\IBUFG'. +Generating RTLIL representation for module `\OBUF'. +Generating RTLIL representation for module `\IOBUF'. +Generating RTLIL representation for module `\OBUFT'. +Generating RTLIL representation for module `\BUFG'. +Generating RTLIL representation for module `\BUFGCTRL'. +Generating RTLIL representation for module `\BUFHCE'. +Generating RTLIL representation for module `\INV'. +Generating RTLIL representation for module `\LUT1'. +Generating RTLIL representation for module `\LUT2'. +Generating RTLIL representation for module `\LUT3'. +Generating RTLIL representation for module `\LUT4'. +Generating RTLIL representation for module `\LUT5'. +Generating RTLIL representation for module `\LUT6'. +Generating RTLIL representation for module `\LUT6_2'. +Generating RTLIL representation for module `\MUXCY'. +Generating RTLIL representation for module `\MUXF7'. +Generating RTLIL representation for module `\MUXF8'. +Generating RTLIL representation for module `\XORCY'. +Generating RTLIL representation for module `\CARRY4'. +Generating RTLIL representation for module `\FDRE'. +Generating RTLIL representation for module `\FDSE'. +Generating RTLIL representation for module `\FDCE'. +Generating RTLIL representation for module `\FDPE'. +Generating RTLIL representation for module `\FDRE_1'. +Generating RTLIL representation for module `\FDSE_1'. +Generating RTLIL representation for module `\FDCE_1'. +Generating RTLIL representation for module `\FDPE_1'. +Generating RTLIL representation for module `\LDCE'. +Generating RTLIL representation for module `\LDPE'. +Generating RTLIL representation for module `\RAM16X1S'. +Generating RTLIL representation for module `\RAM16X1S_1'. +Generating RTLIL representation for module `\RAM32X1S'. +Generating RTLIL representation for module `\RAM32X1S_1'. +Generating RTLIL representation for module `\RAM64X1S'. +Generating RTLIL representation for module `\RAM64X1S_1'. +Generating RTLIL representation for module `\RAM128X1S'. +Generating RTLIL representation for module `\RAM128X1S_1'. +Generating RTLIL representation for module `\RAM256X1S'. +Generating RTLIL representation for module `\RAM512X1S'. +Generating RTLIL representation for module `\RAM16X2S'. +Generating RTLIL representation for module `\RAM32X2S'. +Generating RTLIL representation for module `\RAM64X2S'. +Generating RTLIL representation for module `\RAM16X4S'. +Generating RTLIL representation for module `\RAM32X4S'. +Generating RTLIL representation for module `\RAM16X8S'. +Generating RTLIL representation for module `\RAM32X8S'. +Generating RTLIL representation for module `\RAM16X1D'. +Generating RTLIL representation for module `\RAM16X1D_1'. +Generating RTLIL representation for module `\RAM32X1D'. +Generating RTLIL representation for module `\RAM32X1D_1'. +Generating RTLIL representation for module `\RAM64X1D'. +Generating RTLIL representation for module `\RAM64X1D_1'. +Generating RTLIL representation for module `\RAM128X1D'. +Generating RTLIL representation for module `\RAM256X1D'. +Generating RTLIL representation for module `\RAM32M'. +Generating RTLIL representation for module `\RAM32M16'. +Generating RTLIL representation for module `\RAM64M'. +Generating RTLIL representation for module `\RAM64M8'. +Generating RTLIL representation for module `\ROM16X1'. +Generating RTLIL representation for module `\ROM32X1'. +Generating RTLIL representation for module `\ROM64X1'. +Generating RTLIL representation for module `\ROM128X1'. +Generating RTLIL representation for module `\ROM256X1'. +Generating RTLIL representation for module `\SRL16E'. +Generating RTLIL representation for module `\SRLC16E'. +Generating RTLIL representation for module `\SRLC32E'. +Generating RTLIL representation for module `\MULT18X18'. +Generating RTLIL representation for module `\MULT18X18S'. +Generating RTLIL representation for module `\MULT18X18SIO'. +Generating RTLIL representation for module `\DSP48A'. +Generating RTLIL representation for module `\DSP48A1'. +Generating RTLIL representation for module `\DSP48E1'. +Successfully finished Verilog frontend. + +3.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v' to AST representation. +Generating RTLIL representation for module `\FDCPE'. +Generating RTLIL representation for module `\FDRSE'. +Generating RTLIL representation for module `\LDCPE'. +Generating RTLIL representation for module `\AND2B1L'. +Generating RTLIL representation for module `\OR2L'. +Generating RTLIL representation for module `\MUXF5'. +Generating RTLIL representation for module `\MUXF6'. +Generating RTLIL representation for module `\MUXF9'. +Generating RTLIL representation for module `\CARRY8'. +Generating RTLIL representation for module `\ORCY'. +Generating RTLIL representation for module `\MULT_AND'. +Generating RTLIL representation for module `\SRL16'. +Generating RTLIL representation for module `\SRLC16'. +Generating RTLIL representation for module `\CFGLUT5'. +Generating RTLIL representation for module `\RAMB16_S1'. +Generating RTLIL representation for module `\RAMB16_S2'. +Generating RTLIL representation for module `\RAMB16_S4'. +Generating RTLIL representation for module `\RAMB16_S9'. +Generating RTLIL representation for module `\RAMB16_S18'. +Generating RTLIL representation for module `\RAMB16_S36'. +Generating RTLIL representation for module `\RAMB16_S1_S1'. +Generating RTLIL representation for module `\RAMB16_S1_S2'. +Generating RTLIL representation for module `\RAMB16_S1_S4'. +Generating RTLIL representation for module `\RAMB16_S1_S9'. +Generating RTLIL representation for module `\RAMB16_S1_S18'. +Generating RTLIL representation for module `\RAMB16_S1_S36'. +Generating RTLIL representation for module `\RAMB16_S2_S2'. +Generating RTLIL representation for module `\RAMB16_S2_S4'. +Generating RTLIL representation for module `\RAMB16_S2_S9'. +Generating RTLIL representation for module `\RAMB16_S2_S18'. +Generating RTLIL representation for module `\RAMB16_S2_S36'. +Generating RTLIL representation for module `\RAMB16_S4_S4'. +Generating RTLIL representation for module `\RAMB16_S4_S9'. +Generating RTLIL representation for module `\RAMB16_S4_S18'. +Generating RTLIL representation for module `\RAMB16_S4_S36'. +Generating RTLIL representation for module `\RAMB16_S9_S9'. +Generating RTLIL representation for module `\RAMB16_S9_S18'. +Generating RTLIL representation for module `\RAMB16_S9_S36'. +Generating RTLIL representation for module `\RAMB16_S18_S18'. +Generating RTLIL representation for module `\RAMB16_S18_S36'. +Generating RTLIL representation for module `\RAMB16_S36_S36'. +Generating RTLIL representation for module `\RAMB16BWE_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36'. +Generating RTLIL representation for module `\RAMB16BWE_S18_S9'. +Generating RTLIL representation for module `\RAMB16BWE_S18_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S9'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S36'. +Generating RTLIL representation for module `\RAMB16BWER'. +Generating RTLIL representation for module `\RAMB8BWER'. +Generating RTLIL representation for module `\FIFO16'. +Generating RTLIL representation for module `\RAMB16'. +Generating RTLIL representation for module `\RAMB32_S64_ECC'. +Generating RTLIL representation for module `\FIFO18'. +Generating RTLIL representation for module `\FIFO18_36'. +Generating RTLIL representation for module `\FIFO36'. +Generating RTLIL representation for module `\FIFO36_72'. +Generating RTLIL representation for module `\RAMB18'. +Generating RTLIL representation for module `\RAMB36'. +Generating RTLIL representation for module `\RAMB18SDP'. +Generating RTLIL representation for module `\RAMB36SDP'. +Generating RTLIL representation for module `\FIFO18E1'. +Generating RTLIL representation for module `\FIFO36E1'. +Generating RTLIL representation for module `\RAMB18E1'. +Generating RTLIL representation for module `\RAMB36E1'. +Generating RTLIL representation for module `\FIFO18E2'. +Generating RTLIL representation for module `\FIFO36E2'. +Generating RTLIL representation for module `\RAMB18E2'. +Generating RTLIL representation for module `\RAMB36E2'. +Generating RTLIL representation for module `\URAM288'. +Generating RTLIL representation for module `\URAM288_BASE'. +Generating RTLIL representation for module `\DSP48'. +Generating RTLIL representation for module `\DSP48E'. +Generating RTLIL representation for module `\DSP48E2'. +Generating RTLIL representation for module `\IFDDRCPE'. +Generating RTLIL representation for module `\IFDDRRSE'. +Generating RTLIL representation for module `\OFDDRCPE'. +Generating RTLIL representation for module `\OFDDRRSE'. +Generating RTLIL representation for module `\OFDDRTCPE'. +Generating RTLIL representation for module `\OFDDRTRSE'. +Generating RTLIL representation for module `\IDDR2'. +Generating RTLIL representation for module `\ODDR2'. +Generating RTLIL representation for module `\IDDR'. +Generating RTLIL representation for module `\IDDR_2CLK'. +Generating RTLIL representation for module `\ODDR'. +Generating RTLIL representation for module `\IDELAYCTRL'. +Generating RTLIL representation for module `\IDELAY'. +Generating RTLIL representation for module `\ISERDES'. +Generating RTLIL representation for module `\OSERDES'. +Generating RTLIL representation for module `\IODELAY'. +Generating RTLIL representation for module `\ISERDES_NODELAY'. +Generating RTLIL representation for module `\IODELAYE1'. +Generating RTLIL representation for module `\ISERDESE1'. +Generating RTLIL representation for module `\OSERDESE1'. +Generating RTLIL representation for module `\IDELAYE2'. +Generating RTLIL representation for module `\ODELAYE2'. +Generating RTLIL representation for module `\ISERDESE2'. +Generating RTLIL representation for module `\OSERDESE2'. +Generating RTLIL representation for module `\PHASER_IN'. +Generating RTLIL representation for module `\PHASER_IN_PHY'. +Generating RTLIL representation for module `\PHASER_OUT'. +Generating RTLIL representation for module `\PHASER_OUT_PHY'. +Generating RTLIL representation for module `\PHASER_REF'. +Generating RTLIL representation for module `\PHY_CONTROL'. +Generating RTLIL representation for module `\IDDRE1'. +Generating RTLIL representation for module `\ODDRE1'. +Generating RTLIL representation for module `\IDELAYE3'. +Generating RTLIL representation for module `\ODELAYE3'. +Generating RTLIL representation for module `\ISERDESE3'. +Generating RTLIL representation for module `\OSERDESE3'. +Generating RTLIL representation for module `\BITSLICE_CONTROL'. +Generating RTLIL representation for module `\RIU_OR'. +Generating RTLIL representation for module `\RX_BITSLICE'. +Generating RTLIL representation for module `\RXTX_BITSLICE'. +Generating RTLIL representation for module `\TX_BITSLICE'. +Generating RTLIL representation for module `\TX_BITSLICE_TRI'. +Generating RTLIL representation for module `\IODELAY2'. +Generating RTLIL representation for module `\IODRP2'. +Generating RTLIL representation for module `\IODRP2_MCB'. +Generating RTLIL representation for module `\ISERDES2'. +Generating RTLIL representation for module `\OSERDES2'. +Generating RTLIL representation for module `\IBUF_DLY_ADJ'. +Generating RTLIL representation for module `\IBUF_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUF_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUF_ANALOG'. +Generating RTLIL representation for module `\IBUFE3'. +Generating RTLIL representation for module `\IBUFDS'. +Generating RTLIL representation for module `\IBUFDS_DLY_ADJ'. +Generating RTLIL representation for module `\IBUFDS_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUFDS_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUFDSE3'. +Generating RTLIL representation for module `\IBUFDS_DPHY'. +Generating RTLIL representation for module `\IBUFGDS'. +Generating RTLIL representation for module `\IBUFGDS_DIFF_OUT'. +Generating RTLIL representation for module `\IOBUF_DCIEN'. +Generating RTLIL representation for module `\IOBUF_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFE3'. +Generating RTLIL representation for module `\IOBUFDS'. +Generating RTLIL representation for module `\IOBUFDS_DCIEN'. +Generating RTLIL representation for module `\IOBUFDS_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_DCIEN'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFDSE3'. +Generating RTLIL representation for module `\OBUFDS'. +Generating RTLIL representation for module `\OBUFDS_DPHY'. +Generating RTLIL representation for module `\OBUFTDS'. +Generating RTLIL representation for module `\KEEPER'. +Generating RTLIL representation for module `\PULLDOWN'. +Generating RTLIL representation for module `\PULLUP'. +Generating RTLIL representation for module `\DCIRESET'. +Generating RTLIL representation for module `\HPIO_VREF'. +Generating RTLIL representation for module `\BUFGCE'. +Generating RTLIL representation for module `\BUFGCE_1'. +Generating RTLIL representation for module `\BUFGMUX'. +Generating RTLIL representation for module `\BUFGMUX_1'. +Generating RTLIL representation for module `\BUFGMUX_CTRL'. +Generating RTLIL representation for module `\BUFGMUX_VIRTEX4'. +Generating RTLIL representation for module `\BUFG_GT'. +Generating RTLIL representation for module `\BUFG_GT_SYNC'. +Generating RTLIL representation for module `\BUFG_PS'. +Generating RTLIL representation for module `\BUFGCE_DIV'. +Generating RTLIL representation for module `\BUFH'. +Generating RTLIL representation for module `\BUFIO2'. +Generating RTLIL representation for module `\BUFIO2_2CLK'. +Generating RTLIL representation for module `\BUFIO2FB'. +Generating RTLIL representation for module `\BUFPLL'. +Generating RTLIL representation for module `\BUFPLL_MCB'. +Generating RTLIL representation for module `\BUFIO'. +Generating RTLIL representation for module `\BUFIODQS'. +Generating RTLIL representation for module `\BUFR'. +Generating RTLIL representation for module `\BUFMR'. +Generating RTLIL representation for module `\BUFMRCE'. +Generating RTLIL representation for module `\DCM'. +Generating RTLIL representation for module `\DCM_SP'. +Generating RTLIL representation for module `\DCM_CLKGEN'. +Generating RTLIL representation for module `\DCM_ADV'. +Generating RTLIL representation for module `\DCM_BASE'. +Generating RTLIL representation for module `\DCM_PS'. +Generating RTLIL representation for module `\PMCD'. +Generating RTLIL representation for module `\PLL_ADV'. +Generating RTLIL representation for module `\PLL_BASE'. +Generating RTLIL representation for module `\MMCM_ADV'. +Generating RTLIL representation for module `\MMCM_BASE'. +Generating RTLIL representation for module `\MMCME2_ADV'. +Generating RTLIL representation for module `\MMCME2_BASE'. +Generating RTLIL representation for module `\PLLE2_ADV'. +Generating RTLIL representation for module `\PLLE2_BASE'. +Generating RTLIL representation for module `\MMCME3_ADV'. +Generating RTLIL representation for module `\MMCME3_BASE'. +Generating RTLIL representation for module `\PLLE3_ADV'. +Generating RTLIL representation for module `\PLLE3_BASE'. +Generating RTLIL representation for module `\MMCME4_ADV'. +Generating RTLIL representation for module `\MMCME4_BASE'. +Generating RTLIL representation for module `\PLLE4_ADV'. +Generating RTLIL representation for module `\PLLE4_BASE'. +Generating RTLIL representation for module `\BUFT'. +Generating RTLIL representation for module `\IN_FIFO'. +Generating RTLIL representation for module `\OUT_FIFO'. +Generating RTLIL representation for module `\HARD_SYNC'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3E'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3A'. +Generating RTLIL representation for module `\STARTUP_SPARTAN6'. +Generating RTLIL representation for module `\STARTUP_VIRTEX4'. +Generating RTLIL representation for module `\STARTUP_VIRTEX5'. +Generating RTLIL representation for module `\STARTUP_VIRTEX6'. +Generating RTLIL representation for module `\STARTUPE2'. +Generating RTLIL representation for module `\STARTUPE3'. +Generating RTLIL representation for module `\CAPTURE_SPARTAN3'. +Generating RTLIL representation for module `\CAPTURE_SPARTAN3A'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX4'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX5'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX6'. +Generating RTLIL representation for module `\CAPTUREE2'. +Generating RTLIL representation for module `\ICAP_SPARTAN3A'. +Generating RTLIL representation for module `\ICAP_SPARTAN6'. +Generating RTLIL representation for module `\ICAP_VIRTEX4'. +Generating RTLIL representation for module `\ICAP_VIRTEX5'. +Generating RTLIL representation for module `\ICAP_VIRTEX6'. +Generating RTLIL representation for module `\ICAPE2'. +Generating RTLIL representation for module `\ICAPE3'. +Generating RTLIL representation for module `\BSCAN_SPARTAN3'. +Generating RTLIL representation for module `\BSCAN_SPARTAN3A'. +Generating RTLIL representation for module `\BSCAN_SPARTAN6'. +Generating RTLIL representation for module `\BSCAN_VIRTEX4'. +Generating RTLIL representation for module `\BSCAN_VIRTEX5'. +Generating RTLIL representation for module `\BSCAN_VIRTEX6'. +Generating RTLIL representation for module `\BSCANE2'. +Generating RTLIL representation for module `\DNA_PORT'. +Generating RTLIL representation for module `\DNA_PORTE2'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX4'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX5'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX6'. +Generating RTLIL representation for module `\FRAME_ECCE2'. +Generating RTLIL representation for module `\FRAME_ECCE3'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX4'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX5'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX6'. +Generating RTLIL representation for module `\USR_ACCESSE2'. +Generating RTLIL representation for module `\POST_CRC_INTERNAL'. +Generating RTLIL representation for module `\SUSPEND_SYNC'. +Generating RTLIL representation for module `\KEY_CLEAR'. +Generating RTLIL representation for module `\MASTER_JTAG'. +Generating RTLIL representation for module `\SPI_ACCESS'. +Generating RTLIL representation for module `\EFUSE_USR'. +Generating RTLIL representation for module `\SYSMON'. +Generating RTLIL representation for module `\XADC'. +Generating RTLIL representation for module `\SYSMONE1'. +Generating RTLIL representation for module `\SYSMONE4'. +Generating RTLIL representation for module `\GTPA1_DUAL'. +Generating RTLIL representation for module `\GT11_CUSTOM'. +Generating RTLIL representation for module `\GT11_DUAL'. +Generating RTLIL representation for module `\GT11CLK'. +Generating RTLIL representation for module `\GT11CLK_MGT'. +Generating RTLIL representation for module `\GTP_DUAL'. +Generating RTLIL representation for module `\GTX_DUAL'. +Generating RTLIL representation for module `\CRC32'. +Generating RTLIL representation for module `\CRC64'. +Generating RTLIL representation for module `\GTHE1_QUAD'. +Generating RTLIL representation for module `\GTXE1'. +Generating RTLIL representation for module `\IBUFDS_GTXE1'. +Generating RTLIL representation for module `\IBUFDS_GTHE1'. +Generating RTLIL representation for module `\GTHE2_CHANNEL'. +Generating RTLIL representation for module `\GTHE2_COMMON'. +Generating RTLIL representation for module `\GTPE2_CHANNEL'. +Generating RTLIL representation for module `\GTPE2_COMMON'. +Generating RTLIL representation for module `\GTXE2_CHANNEL'. +Generating RTLIL representation for module `\GTXE2_COMMON'. +Generating RTLIL representation for module `\IBUFDS_GTE2'. +Generating RTLIL representation for module `\GTHE3_CHANNEL'. +Generating RTLIL representation for module `\GTHE3_COMMON'. +Generating RTLIL representation for module `\GTHE4_CHANNEL'. +Generating RTLIL representation for module `\GTHE4_COMMON'. +Generating RTLIL representation for module `\GTYE3_CHANNEL'. +Generating RTLIL representation for module `\GTYE3_COMMON'. +Generating RTLIL representation for module `\GTYE4_CHANNEL'. +Generating RTLIL representation for module `\GTYE4_COMMON'. +Generating RTLIL representation for module `\IBUFDS_GTE3'. +Generating RTLIL representation for module `\IBUFDS_GTE4'. +Generating RTLIL representation for module `\OBUFDS_GTE3'. +Generating RTLIL representation for module `\OBUFDS_GTE3_ADV'. +Generating RTLIL representation for module `\OBUFDS_GTE4'. +Generating RTLIL representation for module `\OBUFDS_GTE4_ADV'. +Generating RTLIL representation for module `\PCIE_A1'. +Generating RTLIL representation for module `\PCIE_EP'. +Generating RTLIL representation for module `\PCIE_2_0'. +Generating RTLIL representation for module `\PCIE_2_1'. +Generating RTLIL representation for module `\PCIE_3_0'. +Generating RTLIL representation for module `\PCIE_3_1'. +Generating RTLIL representation for module `\PCIE40E4'. +Generating RTLIL representation for module `\EMAC'. +Generating RTLIL representation for module `\TEMAC'. +Generating RTLIL representation for module `\TEMAC_SINGLE'. +Generating RTLIL representation for module `\CMAC'. +Generating RTLIL representation for module `\CMACE4'. +Generating RTLIL representation for module `\PPC405_ADV'. +Generating RTLIL representation for module `\PPC440'. +Generating RTLIL representation for module `\MCB'. +Generating RTLIL representation for module `\PS7'. +Generating RTLIL representation for module `\PS8'. +Generating RTLIL representation for module `\ILKN'. +Generating RTLIL representation for module `\ILKNE4'. +Successfully finished Verilog frontend. + +3.3. Executing HIERARCHY pass (managing design hierarchy). + +3.3.1. Analyzing design hierarchy.. +Top module: \block_ram + +3.3.2. Analyzing design hierarchy.. +Top module: \block_ram +Removed 0 unused modules. + +3.4. Executing PROC pass (convert processes to netlists). + +3.4.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Cleaned up 0 empty switches. + +3.4.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). +Removed a total of 0 dead cases. + +3.4.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). +Removed 0 redundant assignments. +Promoted 1 assignment to connection. + +3.4.4. Executing PROC_INIT pass (extract init attributes). + +3.4.5. Executing PROC_ARST pass (detect async resets in processes). + +3.4.6. Executing PROC_MUX pass (convert decision trees to multiplexers). +Creating decoders for process `\block_ram.$proc$attributes_test.v:14$2'. + 1/3: $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 + 2/3: $0$memwr$\memory$attributes_test.v:16$1_DATA[3:0]$4 + 3/3: $0$memwr$\memory$attributes_test.v:16$1_ADDR[9:0]$3 + +3.4.7. Executing PROC_DLATCH pass (convert process syncs to latches). + +3.4.8. Executing PROC_DFF pass (convert process syncs to FFs). +Creating register for signal `\block_ram.\data_out_r' using process `\block_ram.$proc$attributes_test.v:14$2'. + created $dff cell `$procdff$48' with positive edge clock. +Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$1_ADDR' using process `\block_ram.$proc$attributes_test.v:14$2'. + created $dff cell `$procdff$49' with positive edge clock. +Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$1_DATA' using process `\block_ram.$proc$attributes_test.v:14$2'. + created $dff cell `$procdff$50' with positive edge clock. +Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$1_EN' using process `\block_ram.$proc$attributes_test.v:14$2'. + created $dff cell `$procdff$51' with positive edge clock. + +3.4.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Found and cleaned up 1 empty switch in `\block_ram.$proc$attributes_test.v:14$2'. +Removing empty process `block_ram.$proc$attributes_test.v:14$2'. +Cleaned up 1 empty switch. + +3.5. Executing TRIBUF pass. + +3.6. Executing DEMINOUT pass (demote inout ports to input or output). + +3.7. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.8. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Removed 0 unused cells and 7 unused wires. + + +3.9. Executing CHECK pass (checking for obvious problems). +checking module block_ram.. +found and reported 0 problems. + +3.10. Executing OPT pass (performing simple optimizations). + +3.10.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.10.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.10.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +3.10.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. + Consolidated identical input bits for $mux cell $procmux$42: + Old ports: A=4'0000, B=4'1111, Y=$0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 + New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] + New connections: $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [3:1] = { $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] } + Optimizing cells in module \block_ram. +Performed a total of 1 changes. + +3.10.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.10.6. Executing OPT_RMDFF pass (remove dff with constant values). + +3.10.7. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.10.8. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.10.9. Rerunning OPT passes. (Maybe there is more to do..) + +3.10.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +3.10.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. +Performed a total of 0 changes. + +3.10.12. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.10.13. Executing OPT_RMDFF pass (remove dff with constant values). + +3.10.14. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.10.15. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.10.16. Finished OPT passes. (There is nothing left to do.) + +3.11. Executing WREDUCE pass (reducing word size of cells). +Removed cell block_ram.$procmux$44 ($mux). +Removed cell block_ram.$procmux$46 ($mux). +Removed top 3 bits (of 4) from FF cell block_ram.$procdff$51 ($dff). + +3.12. Executing PEEPOPT pass (run peephole optimizers). + +3.13. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Removed 0 unused cells and 2 unused wires. + + +3.14. Executing PMUX2SHIFTX pass. + +3.15. Executing TECHMAP pass (map to technology primitives). + +3.15.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v' to AST representation. +Generating RTLIL representation for module `\_90_lut_cmp_'. +Successfully finished Verilog frontend. + +3.15.2. Continuing TECHMAP pass. +No more expansions possible. + +3.16. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). +Checking cell `$memwr$\memory$attributes_test.v:16$7' in module `\block_ram': merged $dff to cell. +Checking cell `$memrd$\memory$attributes_test.v:17$6' in module `\block_ram': merged data $dff to cell. + +3.17. Executing TECHMAP pass (map to technology primitives). + +3.17.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v' to AST representation. +Generating RTLIL representation for module `\_80_mul'. +Generating RTLIL representation for module `\_90_soft_mul'. +Successfully finished Verilog frontend. + +3.17.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v' to AST representation. +Generating RTLIL representation for module `\$__MUL25X18'. +Successfully finished Verilog frontend. + +3.17.3. Continuing TECHMAP pass. +No more expansions possible. + +3.18. Executing OPT_EXPR pass (perform const folding). + +3.19. Executing WREDUCE pass (reducing word size of cells). + +3.20. Executing XILINX_DSP pass (pack resources into DSPs). + +3.21. Executing ALUMACC pass (create $alu and $macc cells). +Extracting $alu and $macc cells in module block_ram: + created 0 $alu and 0 $macc cells. + +3.22. Executing SHARE pass (SAT-based resource sharing). + +3.23. Executing OPT pass (performing simple optimizations). + +3.23.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.23.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.23.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +3.23.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. +Performed a total of 0 changes. + +3.23.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.23.6. Executing OPT_RMDFF pass (remove dff with constant values). + +3.23.7. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Removed 4 unused cells and 5 unused wires. + + +3.23.8. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.23.9. Rerunning OPT passes. (Maybe there is more to do..) + +3.23.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +3.23.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. +Performed a total of 0 changes. + +3.23.12. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.23.13. Executing OPT_RMDFF pass (remove dff with constant values). + +3.23.14. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.23.15. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.23.16. Finished OPT passes. (There is nothing left to do.) + +3.24. Executing FSM pass (extract and optimize FSM). + +3.24.1. Executing FSM_DETECT pass (finding FSMs in design). + +3.24.2. Executing FSM_EXTRACT pass (extracting FSM from design). + +3.24.3. Executing FSM_OPT pass (simple optimizations of FSMs). + +3.24.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.24.5. Executing FSM_OPT pass (simple optimizations of FSMs). + +3.24.6. Executing FSM_RECODE pass (re-assigning FSM state encoding). + +3.24.7. Executing FSM_INFO pass (dumping all available information on FSM cells). + +3.24.8. Executing FSM_MAP pass (mapping FSMs to basic logic). + +3.25. Executing OPT pass (performing simple optimizations). + +3.25.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.25.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.25.3. Executing OPT_RMDFF pass (remove dff with constant values). + +3.25.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.25.5. Finished fast OPT passes. + +3.26. Executing MEMORY pass. + +3.26.1. Executing OPT_MEM pass (optimize memories). +Performed a total of 0 transformations. + +3.26.2. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). + +3.26.3. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.26.4. Executing MEMORY_SHARE pass (consolidating $memrd/$memwr cells). + +3.26.5. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.26.6. Executing MEMORY_COLLECT pass (generating $mem cells). +Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\block_ram': + $memwr$\memory$attributes_test.v:16$7 ($memwr) + $memrd$\memory$attributes_test.v:17$6 ($memrd) + +3.27. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.28. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). +Processing block_ram.memory: + Properties: ports=2 bits=4096 rports=1 wports=1 dbits=4 abits=10 words=1024 + Checking rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1): + Bram geometry: abits=9 dbits=72 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_SDP: awaste=0 dwaste=68 bwaste=34816 waste=34816 efficiency=5 + Rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1) accepted. + Mapping to bram type $__XILINX_RAMB36_SDP (variant 1): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=34816 efficiency=5 + Storing for later selection. + Checking rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1): + Bram geometry: abits=9 dbits=36 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_SDP: awaste=0 dwaste=32 bwaste=16384 waste=16384 efficiency=11 + Rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1) accepted. + Mapping to bram type $__XILINX_RAMB18_SDP (variant 1): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=16384 efficiency=11 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1): + Bram geometry: abits=10 dbits=36 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=0 dwaste=32 bwaste=32768 waste=32768 efficiency=11 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1) accepted. + Mapping to bram type $__XILINX_RAMB36_TDP (variant 1): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=32768 efficiency=11 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2): + Bram geometry: abits=11 dbits=18 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=1024 dwaste=14 bwaste=32768 waste=32768 efficiency=11 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2) accepted. + Mapping to bram type $__XILINX_RAMB36_TDP (variant 2): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=32768 efficiency=11 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3): + Bram geometry: abits=12 dbits=9 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=3072 dwaste=5 bwaste=32768 waste=32768 efficiency=11 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3) accepted. + Mapping to bram type $__XILINX_RAMB36_TDP (variant 3): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=32768 efficiency=11 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4): + Bram geometry: abits=13 dbits=4 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=7168 dwaste=0 bwaste=28672 waste=28672 efficiency=12 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4) accepted. + Mapping to bram type $__XILINX_RAMB36_TDP (variant 4): + Shuffle bit order to accommodate enable buckets of size 4.. + Results of bit order shuffling: 0 1 2 3 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=28672 efficiency=12 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5): + Bram geometry: abits=14 dbits=2 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=15360 dwaste=0 bwaste=30720 waste=30720 efficiency=6 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5) accepted. + Mapping to bram type $__XILINX_RAMB36_TDP (variant 5): + Shuffle bit order to accommodate enable buckets of size 2.. + Results of bit order shuffling: 0 1 2 3 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=30720 efficiency=6 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6): + Bram geometry: abits=15 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=31744 dwaste=0 bwaste=31744 waste=31744 efficiency=3 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6) rejected: requirement 'min efficiency 5' not met. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1): + Bram geometry: abits=10 dbits=18 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=0 dwaste=14 bwaste=14336 waste=14336 efficiency=22 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1) accepted. + Mapping to bram type $__XILINX_RAMB18_TDP (variant 1): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=14336 efficiency=22 + Storing for later selection. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2): + Bram geometry: abits=11 dbits=9 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=1024 dwaste=5 bwaste=14336 waste=14336 efficiency=22 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2) accepted. + Mapping to bram type $__XILINX_RAMB18_TDP (variant 2): + Shuffle bit order to accommodate enable buckets of size 9.. + Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=14336 efficiency=22 + Storing for later selection. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3): + Bram geometry: abits=12 dbits=4 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=3072 dwaste=0 bwaste=12288 waste=12288 efficiency=25 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3) accepted. + Mapping to bram type $__XILINX_RAMB18_TDP (variant 3): + Shuffle bit order to accommodate enable buckets of size 4.. + Results of bit order shuffling: 0 1 2 3 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=12288 efficiency=25 + Storing for later selection. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4): + Bram geometry: abits=13 dbits=2 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=7168 dwaste=0 bwaste=14336 waste=14336 efficiency=12 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4) accepted. + Mapping to bram type $__XILINX_RAMB18_TDP (variant 4): + Shuffle bit order to accommodate enable buckets of size 2.. + Results of bit order shuffling: 0 1 2 3 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=14336 efficiency=12 + Storing for later selection. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5): + Bram geometry: abits=14 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=15360 dwaste=0 bwaste=15360 waste=15360 efficiency=6 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5) accepted. + Mapping to bram type $__XILINX_RAMB18_TDP (variant 5): + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=15360 efficiency=6 + Storing for later selection. + Selecting best of 12 rules: + Efficiency for rule 4.5: efficiency=6, cells=4, acells=1 + Efficiency for rule 4.4: efficiency=12, cells=2, acells=1 + Efficiency for rule 4.3: efficiency=25, cells=1, acells=1 + Efficiency for rule 4.2: efficiency=22, cells=1, acells=1 + Efficiency for rule 4.1: efficiency=22, cells=1, acells=1 + Efficiency for rule 3.5: efficiency=6, cells=2, acells=1 + Efficiency for rule 3.4: efficiency=12, cells=1, acells=1 + Efficiency for rule 3.3: efficiency=11, cells=1, acells=1 + Efficiency for rule 3.2: efficiency=11, cells=1, acells=1 + Efficiency for rule 3.1: efficiency=11, cells=1, acells=1 + Efficiency for rule 2.1: efficiency=11, cells=2, acells=2 + Efficiency for rule 1.1: efficiency=5, cells=2, acells=2 + Selected rule 4.3 with efficiency 25. + Mapping to bram type $__XILINX_RAMB18_TDP (variant 3): + Shuffle bit order to accommodate enable buckets of size 4.. + Results of bit order shuffling: 0 1 2 3 + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Creating $__XILINX_RAMB18_TDP cell at grid position <0 0 0>: memory.0.0.0 + +3.29. Executing TECHMAP pass (map to technology primitives). + +3.29.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v' to AST representation. +Generating RTLIL representation for module `\$__XILINX_RAMB36_SDP'. +Generating RTLIL representation for module `\$__XILINX_RAMB18_SDP'. +Generating RTLIL representation for module `\$__XILINX_RAMB36_TDP'. +Generating RTLIL representation for module `\$__XILINX_RAMB18_TDP'. +Successfully finished Verilog frontend. + +3.29.2. Continuing TECHMAP pass. +Using template $paramod\$__XILINX_RAMB18_TDP\CFG_ABITS=12\CFG_DBITS=4\CFG_ENABLE_B=1\CLKPOL2=1\CLKPOL3=1 for cells of type $__XILINX_RAMB18_TDP. +No more expansions possible. + + +3.30. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). + +3.31. Executing TECHMAP pass (map to technology primitives). + +3.31.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v' to AST representation. +Generating RTLIL representation for module `\$__XILINX_RAM32X1D'. +Generating RTLIL representation for module `\$__XILINX_RAM64X1D'. +Generating RTLIL representation for module `\$__XILINX_RAM128X1D'. +Successfully finished Verilog frontend. + +3.31.2. Continuing TECHMAP pass. +No more expansions possible. + +3.32. Executing OPT pass (performing simple optimizations). + +3.32.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + + +3.32.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.32.3. Executing OPT_RMDFF pass (remove dff with constant values). + +3.32.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Removed 0 unused cells and 17 unused wires. + + +3.32.5. Finished fast OPT passes. + +3.33. Executing MEMORY_MAP pass (converting $mem cells to logic and flip-flops). + +3.34. Executing DFFSR2DFF pass (mapping DFFSR cells to simpler FFs). + +3.35. Executing DFF2DFFE pass (transform $dff to $dffe where applicable). +Transforming FF to FF+Enable cells in module block_ram: + +3.36. Executing OPT pass (performing simple optimizations). + +3.36.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.36.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.36.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + No muxes found in this module. +Removed 0 multiplexer ports. + +3.36.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. +Performed a total of 0 changes. + +3.36.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.36.6. Executing OPT_SHARE pass. + +3.36.7. Executing OPT_RMDFF pass (remove dff with constant values). + +3.36.8. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.36.9. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.36.10. Finished OPT passes. (There is nothing left to do.) + +3.37. Executing XILINX_SRL pass (Xilinx shift register extraction). + +3.38. Executing TECHMAP pass (map to technology primitives). + +3.38.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. +Generating RTLIL representation for module `\_90_simplemap_bool_ops'. +Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. +Generating RTLIL representation for module `\_90_simplemap_logic_ops'. +Generating RTLIL representation for module `\_90_simplemap_compare_ops'. +Generating RTLIL representation for module `\_90_simplemap_various'. +Generating RTLIL representation for module `\_90_simplemap_registers'. +Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. +Generating RTLIL representation for module `\_90_shift_shiftx'. +Generating RTLIL representation for module `\_90_fa'. +Generating RTLIL representation for module `\_90_lcu'. +Generating RTLIL representation for module `\_90_alu'. +Generating RTLIL representation for module `\_90_macc'. +Generating RTLIL representation for module `\_90_alumacc'. +Generating RTLIL representation for module `\$__div_mod_u'. +Generating RTLIL representation for module `\$__div_mod'. +Generating RTLIL representation for module `\_90_div'. +Generating RTLIL representation for module `\_90_mod'. +Generating RTLIL representation for module `\_90_pow'. +Generating RTLIL representation for module `\_90_pmux'. +Generating RTLIL representation for module `\_90_lut'. +Successfully finished Verilog frontend. + +3.38.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v' to AST representation. +Generating RTLIL representation for module `\_80_xilinx_lcu'. +Generating RTLIL representation for module `\_80_xilinx_alu'. +Successfully finished Verilog frontend. + +3.38.3. Continuing TECHMAP pass. +No more expansions possible. + +3.39. Executing OPT pass (performing simple optimizations). + +3.39.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.39.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +3.39.3. Executing OPT_RMDFF pass (remove dff with constant values). + +3.39.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +3.39.5. Finished fast OPT passes. + +3.40. Executing TECHMAP pass (map to technology primitives). + +3.40.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. +Generating RTLIL representation for module `\_90_simplemap_bool_ops'. +Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. +Generating RTLIL representation for module `\_90_simplemap_logic_ops'. +Generating RTLIL representation for module `\_90_simplemap_compare_ops'. +Generating RTLIL representation for module `\_90_simplemap_various'. +Generating RTLIL representation for module `\_90_simplemap_registers'. +Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. +Generating RTLIL representation for module `\_90_shift_shiftx'. +Generating RTLIL representation for module `\_90_fa'. +Generating RTLIL representation for module `\_90_lcu'. +Generating RTLIL representation for module `\_90_alu'. +Generating RTLIL representation for module `\_90_macc'. +Generating RTLIL representation for module `\_90_alumacc'. +Generating RTLIL representation for module `\$__div_mod_u'. +Generating RTLIL representation for module `\$__div_mod'. +Generating RTLIL representation for module `\_90_div'. +Generating RTLIL representation for module `\_90_mod'. +Generating RTLIL representation for module `\_90_pow'. +Generating RTLIL representation for module `\_90_pmux'. +Generating RTLIL representation for module `\_90_lut'. +Successfully finished Verilog frontend. + +3.40.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. +Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. +Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. +Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. +Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. +Generating RTLIL representation for module `\$__SHREG_'. +Generating RTLIL representation for module `\$__XILINX_SHREG_'. +Generating RTLIL representation for module `\$__XILINX_MUXF78'. +Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. +Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. +Successfully finished Verilog frontend. + +3.40.3. Continuing TECHMAP pass. +No more expansions possible. + +3.41. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +3.42. Executing ABC pass (technology mapping using ABC). + +3.42.1. Extracting gate netlist of module `\block_ram' to `/input.blif'.. +Extracted 0 gates and 0 wires to a netlist network with 0 inputs and 0 outputs. +Don't call ABC as there is nothing to map. +Removing temp directory. + +3.43. Executing XILINX_SRL pass (Xilinx shift register extraction). + +3.44. Executing TECHMAP pass (map to technology primitives). + +3.44.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v' to AST representation. +Generating RTLIL representation for module `\$lut'. +Successfully finished Verilog frontend. + +3.44.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. +Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. +Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. +Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. +Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. +Generating RTLIL representation for module `\$__SHREG_'. +Generating RTLIL representation for module `\$__XILINX_SHREG_'. +Generating RTLIL representation for module `\$__XILINX_MUXF78'. +Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. +Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. +Successfully finished Verilog frontend. + +3.44.3. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v' to AST representation. +Generating RTLIL representation for module `\$_DFF_N_'. +Generating RTLIL representation for module `\$_DFF_P_'. +Generating RTLIL representation for module `\$_DFFE_NP_'. +Generating RTLIL representation for module `\$_DFFE_PP_'. +Generating RTLIL representation for module `\$_DFF_NN0_'. +Generating RTLIL representation for module `\$_DFF_NP0_'. +Generating RTLIL representation for module `\$_DFF_PN0_'. +Generating RTLIL representation for module `\$_DFF_PP0_'. +Generating RTLIL representation for module `\$_DFF_NN1_'. +Generating RTLIL representation for module `\$_DFF_NP1_'. +Generating RTLIL representation for module `\$_DFF_PN1_'. +Generating RTLIL representation for module `\$_DFF_PP1_'. +Generating RTLIL representation for module `\$_DLATCH_N_'. +Generating RTLIL representation for module `\$_DLATCH_P_'. +Successfully finished Verilog frontend. + +3.44.4. Continuing TECHMAP pass. +No more expansions possible. + +3.45. Executing CLKBUFMAP pass (inserting global clock buffers). +Inserting BUFG on block_ram.clk[0]. + +3.46. Executing HIERARCHY pass (managing design hierarchy). + +3.46.1. Analyzing design hierarchy.. +Top module: \block_ram + +3.46.2. Analyzing design hierarchy.. +Top module: \block_ram +Removed 0 unused modules. + +3.47. Printing statistics. + +=== block_ram === + + Number of wires: 12 + Number of wire bits: 62 + Number of public wires: 6 + Number of public wire bits: 24 + Number of memories: 0 + Number of memory bits: 0 + Number of processes: 0 + Number of cells: 2 + BUFG 1 + RAMB18E1 1 + + Estimated number of LCs: 0 + +3.48. Executing CHECK pass (checking for obvious problems). +checking module block_ram.. +found and reported 0 problems. + +4. Executing Verilog-2005 frontend: attributes_test.v +Parsing Verilog input from `attributes_test.v' to AST representation. +Generating RTLIL representation for module `\block_ram'. +Generating RTLIL representation for module `\distributed_ram'. +Generating RTLIL representation for module `\distributed_ram_manual'. +Generating RTLIL representation for module `\distributed_ram_manual_syn'. +Successfully finished Verilog frontend. + +5. Executing HIERARCHY pass (managing design hierarchy). + +5.1. Analyzing design hierarchy.. +Top module: \distributed_ram + +5.2. Analyzing design hierarchy.. +Top module: \distributed_ram +Removing unused module `\distributed_ram_manual_syn'. +Removing unused module `\distributed_ram_manual'. +Removing unused module `\block_ram'. +Removed 3 unused modules. + +6. Executing SYNTH_XILINX pass. + +6.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v' to AST representation. +Generating RTLIL representation for module `\VCC'. +Generating RTLIL representation for module `\GND'. +Generating RTLIL representation for module `\IBUF'. +Generating RTLIL representation for module `\IBUFG'. +Generating RTLIL representation for module `\OBUF'. +Generating RTLIL representation for module `\IOBUF'. +Generating RTLIL representation for module `\OBUFT'. +Generating RTLIL representation for module `\BUFG'. +Generating RTLIL representation for module `\BUFGCTRL'. +Generating RTLIL representation for module `\BUFHCE'. +Generating RTLIL representation for module `\INV'. +Generating RTLIL representation for module `\LUT1'. +Generating RTLIL representation for module `\LUT2'. +Generating RTLIL representation for module `\LUT3'. +Generating RTLIL representation for module `\LUT4'. +Generating RTLIL representation for module `\LUT5'. +Generating RTLIL representation for module `\LUT6'. +Generating RTLIL representation for module `\LUT6_2'. +Generating RTLIL representation for module `\MUXCY'. +Generating RTLIL representation for module `\MUXF7'. +Generating RTLIL representation for module `\MUXF8'. +Generating RTLIL representation for module `\XORCY'. +Generating RTLIL representation for module `\CARRY4'. +Generating RTLIL representation for module `\FDRE'. +Generating RTLIL representation for module `\FDSE'. +Generating RTLIL representation for module `\FDCE'. +Generating RTLIL representation for module `\FDPE'. +Generating RTLIL representation for module `\FDRE_1'. +Generating RTLIL representation for module `\FDSE_1'. +Generating RTLIL representation for module `\FDCE_1'. +Generating RTLIL representation for module `\FDPE_1'. +Generating RTLIL representation for module `\LDCE'. +Generating RTLIL representation for module `\LDPE'. +Generating RTLIL representation for module `\RAM16X1S'. +Generating RTLIL representation for module `\RAM16X1S_1'. +Generating RTLIL representation for module `\RAM32X1S'. +Generating RTLIL representation for module `\RAM32X1S_1'. +Generating RTLIL representation for module `\RAM64X1S'. +Generating RTLIL representation for module `\RAM64X1S_1'. +Generating RTLIL representation for module `\RAM128X1S'. +Generating RTLIL representation for module `\RAM128X1S_1'. +Generating RTLIL representation for module `\RAM256X1S'. +Generating RTLIL representation for module `\RAM512X1S'. +Generating RTLIL representation for module `\RAM16X2S'. +Generating RTLIL representation for module `\RAM32X2S'. +Generating RTLIL representation for module `\RAM64X2S'. +Generating RTLIL representation for module `\RAM16X4S'. +Generating RTLIL representation for module `\RAM32X4S'. +Generating RTLIL representation for module `\RAM16X8S'. +Generating RTLIL representation for module `\RAM32X8S'. +Generating RTLIL representation for module `\RAM16X1D'. +Generating RTLIL representation for module `\RAM16X1D_1'. +Generating RTLIL representation for module `\RAM32X1D'. +Generating RTLIL representation for module `\RAM32X1D_1'. +Generating RTLIL representation for module `\RAM64X1D'. +Generating RTLIL representation for module `\RAM64X1D_1'. +Generating RTLIL representation for module `\RAM128X1D'. +Generating RTLIL representation for module `\RAM256X1D'. +Generating RTLIL representation for module `\RAM32M'. +Generating RTLIL representation for module `\RAM32M16'. +Generating RTLIL representation for module `\RAM64M'. +Generating RTLIL representation for module `\RAM64M8'. +Generating RTLIL representation for module `\ROM16X1'. +Generating RTLIL representation for module `\ROM32X1'. +Generating RTLIL representation for module `\ROM64X1'. +Generating RTLIL representation for module `\ROM128X1'. +Generating RTLIL representation for module `\ROM256X1'. +Generating RTLIL representation for module `\SRL16E'. +Generating RTLIL representation for module `\SRLC16E'. +Generating RTLIL representation for module `\SRLC32E'. +Generating RTLIL representation for module `\MULT18X18'. +Generating RTLIL representation for module `\MULT18X18S'. +Generating RTLIL representation for module `\MULT18X18SIO'. +Generating RTLIL representation for module `\DSP48A'. +Generating RTLIL representation for module `\DSP48A1'. +Generating RTLIL representation for module `\DSP48E1'. +Successfully finished Verilog frontend. + +6.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v' to AST representation. +Generating RTLIL representation for module `\FDCPE'. +Generating RTLIL representation for module `\FDRSE'. +Generating RTLIL representation for module `\LDCPE'. +Generating RTLIL representation for module `\AND2B1L'. +Generating RTLIL representation for module `\OR2L'. +Generating RTLIL representation for module `\MUXF5'. +Generating RTLIL representation for module `\MUXF6'. +Generating RTLIL representation for module `\MUXF9'. +Generating RTLIL representation for module `\CARRY8'. +Generating RTLIL representation for module `\ORCY'. +Generating RTLIL representation for module `\MULT_AND'. +Generating RTLIL representation for module `\SRL16'. +Generating RTLIL representation for module `\SRLC16'. +Generating RTLIL representation for module `\CFGLUT5'. +Generating RTLIL representation for module `\RAMB16_S1'. +Generating RTLIL representation for module `\RAMB16_S2'. +Generating RTLIL representation for module `\RAMB16_S4'. +Generating RTLIL representation for module `\RAMB16_S9'. +Generating RTLIL representation for module `\RAMB16_S18'. +Generating RTLIL representation for module `\RAMB16_S36'. +Generating RTLIL representation for module `\RAMB16_S1_S1'. +Generating RTLIL representation for module `\RAMB16_S1_S2'. +Generating RTLIL representation for module `\RAMB16_S1_S4'. +Generating RTLIL representation for module `\RAMB16_S1_S9'. +Generating RTLIL representation for module `\RAMB16_S1_S18'. +Generating RTLIL representation for module `\RAMB16_S1_S36'. +Generating RTLIL representation for module `\RAMB16_S2_S2'. +Generating RTLIL representation for module `\RAMB16_S2_S4'. +Generating RTLIL representation for module `\RAMB16_S2_S9'. +Generating RTLIL representation for module `\RAMB16_S2_S18'. +Generating RTLIL representation for module `\RAMB16_S2_S36'. +Generating RTLIL representation for module `\RAMB16_S4_S4'. +Generating RTLIL representation for module `\RAMB16_S4_S9'. +Generating RTLIL representation for module `\RAMB16_S4_S18'. +Generating RTLIL representation for module `\RAMB16_S4_S36'. +Generating RTLIL representation for module `\RAMB16_S9_S9'. +Generating RTLIL representation for module `\RAMB16_S9_S18'. +Generating RTLIL representation for module `\RAMB16_S9_S36'. +Generating RTLIL representation for module `\RAMB16_S18_S18'. +Generating RTLIL representation for module `\RAMB16_S18_S36'. +Generating RTLIL representation for module `\RAMB16_S36_S36'. +Generating RTLIL representation for module `\RAMB16BWE_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36'. +Generating RTLIL representation for module `\RAMB16BWE_S18_S9'. +Generating RTLIL representation for module `\RAMB16BWE_S18_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S9'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S36'. +Generating RTLIL representation for module `\RAMB16BWER'. +Generating RTLIL representation for module `\RAMB8BWER'. +Generating RTLIL representation for module `\FIFO16'. +Generating RTLIL representation for module `\RAMB16'. +Generating RTLIL representation for module `\RAMB32_S64_ECC'. +Generating RTLIL representation for module `\FIFO18'. +Generating RTLIL representation for module `\FIFO18_36'. +Generating RTLIL representation for module `\FIFO36'. +Generating RTLIL representation for module `\FIFO36_72'. +Generating RTLIL representation for module `\RAMB18'. +Generating RTLIL representation for module `\RAMB36'. +Generating RTLIL representation for module `\RAMB18SDP'. +Generating RTLIL representation for module `\RAMB36SDP'. +Generating RTLIL representation for module `\FIFO18E1'. +Generating RTLIL representation for module `\FIFO36E1'. +Generating RTLIL representation for module `\RAMB18E1'. +Generating RTLIL representation for module `\RAMB36E1'. +Generating RTLIL representation for module `\FIFO18E2'. +Generating RTLIL representation for module `\FIFO36E2'. +Generating RTLIL representation for module `\RAMB18E2'. +Generating RTLIL representation for module `\RAMB36E2'. +Generating RTLIL representation for module `\URAM288'. +Generating RTLIL representation for module `\URAM288_BASE'. +Generating RTLIL representation for module `\DSP48'. +Generating RTLIL representation for module `\DSP48E'. +Generating RTLIL representation for module `\DSP48E2'. +Generating RTLIL representation for module `\IFDDRCPE'. +Generating RTLIL representation for module `\IFDDRRSE'. +Generating RTLIL representation for module `\OFDDRCPE'. +Generating RTLIL representation for module `\OFDDRRSE'. +Generating RTLIL representation for module `\OFDDRTCPE'. +Generating RTLIL representation for module `\OFDDRTRSE'. +Generating RTLIL representation for module `\IDDR2'. +Generating RTLIL representation for module `\ODDR2'. +Generating RTLIL representation for module `\IDDR'. +Generating RTLIL representation for module `\IDDR_2CLK'. +Generating RTLIL representation for module `\ODDR'. +Generating RTLIL representation for module `\IDELAYCTRL'. +Generating RTLIL representation for module `\IDELAY'. +Generating RTLIL representation for module `\ISERDES'. +Generating RTLIL representation for module `\OSERDES'. +Generating RTLIL representation for module `\IODELAY'. +Generating RTLIL representation for module `\ISERDES_NODELAY'. +Generating RTLIL representation for module `\IODELAYE1'. +Generating RTLIL representation for module `\ISERDESE1'. +Generating RTLIL representation for module `\OSERDESE1'. +Generating RTLIL representation for module `\IDELAYE2'. +Generating RTLIL representation for module `\ODELAYE2'. +Generating RTLIL representation for module `\ISERDESE2'. +Generating RTLIL representation for module `\OSERDESE2'. +Generating RTLIL representation for module `\PHASER_IN'. +Generating RTLIL representation for module `\PHASER_IN_PHY'. +Generating RTLIL representation for module `\PHASER_OUT'. +Generating RTLIL representation for module `\PHASER_OUT_PHY'. +Generating RTLIL representation for module `\PHASER_REF'. +Generating RTLIL representation for module `\PHY_CONTROL'. +Generating RTLIL representation for module `\IDDRE1'. +Generating RTLIL representation for module `\ODDRE1'. +Generating RTLIL representation for module `\IDELAYE3'. +Generating RTLIL representation for module `\ODELAYE3'. +Generating RTLIL representation for module `\ISERDESE3'. +Generating RTLIL representation for module `\OSERDESE3'. +Generating RTLIL representation for module `\BITSLICE_CONTROL'. +Generating RTLIL representation for module `\RIU_OR'. +Generating RTLIL representation for module `\RX_BITSLICE'. +Generating RTLIL representation for module `\RXTX_BITSLICE'. +Generating RTLIL representation for module `\TX_BITSLICE'. +Generating RTLIL representation for module `\TX_BITSLICE_TRI'. +Generating RTLIL representation for module `\IODELAY2'. +Generating RTLIL representation for module `\IODRP2'. +Generating RTLIL representation for module `\IODRP2_MCB'. +Generating RTLIL representation for module `\ISERDES2'. +Generating RTLIL representation for module `\OSERDES2'. +Generating RTLIL representation for module `\IBUF_DLY_ADJ'. +Generating RTLIL representation for module `\IBUF_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUF_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUF_ANALOG'. +Generating RTLIL representation for module `\IBUFE3'. +Generating RTLIL representation for module `\IBUFDS'. +Generating RTLIL representation for module `\IBUFDS_DLY_ADJ'. +Generating RTLIL representation for module `\IBUFDS_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUFDS_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUFDSE3'. +Generating RTLIL representation for module `\IBUFDS_DPHY'. +Generating RTLIL representation for module `\IBUFGDS'. +Generating RTLIL representation for module `\IBUFGDS_DIFF_OUT'. +Generating RTLIL representation for module `\IOBUF_DCIEN'. +Generating RTLIL representation for module `\IOBUF_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFE3'. +Generating RTLIL representation for module `\IOBUFDS'. +Generating RTLIL representation for module `\IOBUFDS_DCIEN'. +Generating RTLIL representation for module `\IOBUFDS_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_DCIEN'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFDSE3'. +Generating RTLIL representation for module `\OBUFDS'. +Generating RTLIL representation for module `\OBUFDS_DPHY'. +Generating RTLIL representation for module `\OBUFTDS'. +Generating RTLIL representation for module `\KEEPER'. +Generating RTLIL representation for module `\PULLDOWN'. +Generating RTLIL representation for module `\PULLUP'. +Generating RTLIL representation for module `\DCIRESET'. +Generating RTLIL representation for module `\HPIO_VREF'. +Generating RTLIL representation for module `\BUFGCE'. +Generating RTLIL representation for module `\BUFGCE_1'. +Generating RTLIL representation for module `\BUFGMUX'. +Generating RTLIL representation for module `\BUFGMUX_1'. +Generating RTLIL representation for module `\BUFGMUX_CTRL'. +Generating RTLIL representation for module `\BUFGMUX_VIRTEX4'. +Generating RTLIL representation for module `\BUFG_GT'. +Generating RTLIL representation for module `\BUFG_GT_SYNC'. +Generating RTLIL representation for module `\BUFG_PS'. +Generating RTLIL representation for module `\BUFGCE_DIV'. +Generating RTLIL representation for module `\BUFH'. +Generating RTLIL representation for module `\BUFIO2'. +Generating RTLIL representation for module `\BUFIO2_2CLK'. +Generating RTLIL representation for module `\BUFIO2FB'. +Generating RTLIL representation for module `\BUFPLL'. +Generating RTLIL representation for module `\BUFPLL_MCB'. +Generating RTLIL representation for module `\BUFIO'. +Generating RTLIL representation for module `\BUFIODQS'. +Generating RTLIL representation for module `\BUFR'. +Generating RTLIL representation for module `\BUFMR'. +Generating RTLIL representation for module `\BUFMRCE'. +Generating RTLIL representation for module `\DCM'. +Generating RTLIL representation for module `\DCM_SP'. +Generating RTLIL representation for module `\DCM_CLKGEN'. +Generating RTLIL representation for module `\DCM_ADV'. +Generating RTLIL representation for module `\DCM_BASE'. +Generating RTLIL representation for module `\DCM_PS'. +Generating RTLIL representation for module `\PMCD'. +Generating RTLIL representation for module `\PLL_ADV'. +Generating RTLIL representation for module `\PLL_BASE'. +Generating RTLIL representation for module `\MMCM_ADV'. +Generating RTLIL representation for module `\MMCM_BASE'. +Generating RTLIL representation for module `\MMCME2_ADV'. +Generating RTLIL representation for module `\MMCME2_BASE'. +Generating RTLIL representation for module `\PLLE2_ADV'. +Generating RTLIL representation for module `\PLLE2_BASE'. +Generating RTLIL representation for module `\MMCME3_ADV'. +Generating RTLIL representation for module `\MMCME3_BASE'. +Generating RTLIL representation for module `\PLLE3_ADV'. +Generating RTLIL representation for module `\PLLE3_BASE'. +Generating RTLIL representation for module `\MMCME4_ADV'. +Generating RTLIL representation for module `\MMCME4_BASE'. +Generating RTLIL representation for module `\PLLE4_ADV'. +Generating RTLIL representation for module `\PLLE4_BASE'. +Generating RTLIL representation for module `\BUFT'. +Generating RTLIL representation for module `\IN_FIFO'. +Generating RTLIL representation for module `\OUT_FIFO'. +Generating RTLIL representation for module `\HARD_SYNC'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3E'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3A'. +Generating RTLIL representation for module `\STARTUP_SPARTAN6'. +Generating RTLIL representation for module `\STARTUP_VIRTEX4'. +Generating RTLIL representation for module `\STARTUP_VIRTEX5'. +Generating RTLIL representation for module `\STARTUP_VIRTEX6'. +Generating RTLIL representation for module `\STARTUPE2'. +Generating RTLIL representation for module `\STARTUPE3'. +Generating RTLIL representation for module `\CAPTURE_SPARTAN3'. +Generating RTLIL representation for module `\CAPTURE_SPARTAN3A'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX4'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX5'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX6'. +Generating RTLIL representation for module `\CAPTUREE2'. +Generating RTLIL representation for module `\ICAP_SPARTAN3A'. +Generating RTLIL representation for module `\ICAP_SPARTAN6'. +Generating RTLIL representation for module `\ICAP_VIRTEX4'. +Generating RTLIL representation for module `\ICAP_VIRTEX5'. +Generating RTLIL representation for module `\ICAP_VIRTEX6'. +Generating RTLIL representation for module `\ICAPE2'. +Generating RTLIL representation for module `\ICAPE3'. +Generating RTLIL representation for module `\BSCAN_SPARTAN3'. +Generating RTLIL representation for module `\BSCAN_SPARTAN3A'. +Generating RTLIL representation for module `\BSCAN_SPARTAN6'. +Generating RTLIL representation for module `\BSCAN_VIRTEX4'. +Generating RTLIL representation for module `\BSCAN_VIRTEX5'. +Generating RTLIL representation for module `\BSCAN_VIRTEX6'. +Generating RTLIL representation for module `\BSCANE2'. +Generating RTLIL representation for module `\DNA_PORT'. +Generating RTLIL representation for module `\DNA_PORTE2'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX4'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX5'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX6'. +Generating RTLIL representation for module `\FRAME_ECCE2'. +Generating RTLIL representation for module `\FRAME_ECCE3'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX4'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX5'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX6'. +Generating RTLIL representation for module `\USR_ACCESSE2'. +Generating RTLIL representation for module `\POST_CRC_INTERNAL'. +Generating RTLIL representation for module `\SUSPEND_SYNC'. +Generating RTLIL representation for module `\KEY_CLEAR'. +Generating RTLIL representation for module `\MASTER_JTAG'. +Generating RTLIL representation for module `\SPI_ACCESS'. +Generating RTLIL representation for module `\EFUSE_USR'. +Generating RTLIL representation for module `\SYSMON'. +Generating RTLIL representation for module `\XADC'. +Generating RTLIL representation for module `\SYSMONE1'. +Generating RTLIL representation for module `\SYSMONE4'. +Generating RTLIL representation for module `\GTPA1_DUAL'. +Generating RTLIL representation for module `\GT11_CUSTOM'. +Generating RTLIL representation for module `\GT11_DUAL'. +Generating RTLIL representation for module `\GT11CLK'. +Generating RTLIL representation for module `\GT11CLK_MGT'. +Generating RTLIL representation for module `\GTP_DUAL'. +Generating RTLIL representation for module `\GTX_DUAL'. +Generating RTLIL representation for module `\CRC32'. +Generating RTLIL representation for module `\CRC64'. +Generating RTLIL representation for module `\GTHE1_QUAD'. +Generating RTLIL representation for module `\GTXE1'. +Generating RTLIL representation for module `\IBUFDS_GTXE1'. +Generating RTLIL representation for module `\IBUFDS_GTHE1'. +Generating RTLIL representation for module `\GTHE2_CHANNEL'. +Generating RTLIL representation for module `\GTHE2_COMMON'. +Generating RTLIL representation for module `\GTPE2_CHANNEL'. +Generating RTLIL representation for module `\GTPE2_COMMON'. +Generating RTLIL representation for module `\GTXE2_CHANNEL'. +Generating RTLIL representation for module `\GTXE2_COMMON'. +Generating RTLIL representation for module `\IBUFDS_GTE2'. +Generating RTLIL representation for module `\GTHE3_CHANNEL'. +Generating RTLIL representation for module `\GTHE3_COMMON'. +Generating RTLIL representation for module `\GTHE4_CHANNEL'. +Generating RTLIL representation for module `\GTHE4_COMMON'. +Generating RTLIL representation for module `\GTYE3_CHANNEL'. +Generating RTLIL representation for module `\GTYE3_COMMON'. +Generating RTLIL representation for module `\GTYE4_CHANNEL'. +Generating RTLIL representation for module `\GTYE4_COMMON'. +Generating RTLIL representation for module `\IBUFDS_GTE3'. +Generating RTLIL representation for module `\IBUFDS_GTE4'. +Generating RTLIL representation for module `\OBUFDS_GTE3'. +Generating RTLIL representation for module `\OBUFDS_GTE3_ADV'. +Generating RTLIL representation for module `\OBUFDS_GTE4'. +Generating RTLIL representation for module `\OBUFDS_GTE4_ADV'. +Generating RTLIL representation for module `\PCIE_A1'. +Generating RTLIL representation for module `\PCIE_EP'. +Generating RTLIL representation for module `\PCIE_2_0'. +Generating RTLIL representation for module `\PCIE_2_1'. +Generating RTLIL representation for module `\PCIE_3_0'. +Generating RTLIL representation for module `\PCIE_3_1'. +Generating RTLIL representation for module `\PCIE40E4'. +Generating RTLIL representation for module `\EMAC'. +Generating RTLIL representation for module `\TEMAC'. +Generating RTLIL representation for module `\TEMAC_SINGLE'. +Generating RTLIL representation for module `\CMAC'. +Generating RTLIL representation for module `\CMACE4'. +Generating RTLIL representation for module `\PPC405_ADV'. +Generating RTLIL representation for module `\PPC440'. +Generating RTLIL representation for module `\MCB'. +Generating RTLIL representation for module `\PS7'. +Generating RTLIL representation for module `\PS8'. +Generating RTLIL representation for module `\ILKN'. +Generating RTLIL representation for module `\ILKNE4'. +Successfully finished Verilog frontend. + +6.3. Executing HIERARCHY pass (managing design hierarchy). + +6.3.1. Analyzing design hierarchy.. +Top module: \distributed_ram + +6.3.2. Analyzing design hierarchy.. +Top module: \distributed_ram +Removed 0 unused modules. + +6.4. Executing PROC pass (convert processes to netlists). + +6.4.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Cleaned up 0 empty switches. + +6.4.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). +Removed a total of 0 dead cases. + +6.4.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). +Removed 0 redundant assignments. +Promoted 1 assignment to connection. + +6.4.4. Executing PROC_INIT pass (extract init attributes). + +6.4.5. Executing PROC_ARST pass (detect async resets in processes). + +6.4.6. Executing PROC_MUX pass (convert decision trees to multiplexers). +Creating decoders for process `\distributed_ram.$proc$attributes_test.v:36$188'. + 1/3: $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 + 2/3: $0$memwr$\memory$attributes_test.v:38$187_DATA[7:0]$190 + 3/3: $0$memwr$\memory$attributes_test.v:38$187_ADDR[3:0]$189 + +6.4.7. Executing PROC_DLATCH pass (convert process syncs to latches). + +6.4.8. Executing PROC_DFF pass (convert process syncs to FFs). +Creating register for signal `\distributed_ram.\data_out_r' using process `\distributed_ram.$proc$attributes_test.v:36$188'. + created $dff cell `$procdff$227' with positive edge clock. +Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$187_ADDR' using process `\distributed_ram.$proc$attributes_test.v:36$188'. + created $dff cell `$procdff$228' with positive edge clock. +Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$187_DATA' using process `\distributed_ram.$proc$attributes_test.v:36$188'. + created $dff cell `$procdff$229' with positive edge clock. +Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$187_EN' using process `\distributed_ram.$proc$attributes_test.v:36$188'. + created $dff cell `$procdff$230' with positive edge clock. + +6.4.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Found and cleaned up 1 empty switch in `\distributed_ram.$proc$attributes_test.v:36$188'. +Removing empty process `distributed_ram.$proc$attributes_test.v:36$188'. +Cleaned up 1 empty switch. + +6.5. Executing TRIBUF pass. + +6.6. Executing DEMINOUT pass (demote inout ports to input or output). + +6.7. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.8. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. +Removed 0 unused cells and 7 unused wires. + + +6.9. Executing CHECK pass (checking for obvious problems). +checking module distributed_ram.. +found and reported 0 problems. + +6.10. Executing OPT pass (performing simple optimizations). + +6.10.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.10.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.10.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +6.10.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \distributed_ram. + Consolidated identical input bits for $mux cell $procmux$221: + Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 + New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] + New connections: $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [7:1] = { $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] } + Optimizing cells in module \distributed_ram. +Performed a total of 1 changes. + +6.10.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.10.6. Executing OPT_RMDFF pass (remove dff with constant values). + +6.10.7. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.10.8. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.10.9. Rerunning OPT passes. (Maybe there is more to do..) + +6.10.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +6.10.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \distributed_ram. +Performed a total of 0 changes. + +6.10.12. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.10.13. Executing OPT_RMDFF pass (remove dff with constant values). + +6.10.14. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.10.15. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.10.16. Finished OPT passes. (There is nothing left to do.) + +6.11. Executing WREDUCE pass (reducing word size of cells). +Removed cell distributed_ram.$procmux$223 ($mux). +Removed cell distributed_ram.$procmux$225 ($mux). +Removed top 7 bits (of 8) from FF cell distributed_ram.$procdff$230 ($dff). + +6.12. Executing PEEPOPT pass (run peephole optimizers). + +6.13. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. +Removed 0 unused cells and 2 unused wires. + + +6.14. Executing PMUX2SHIFTX pass. + +6.15. Executing TECHMAP pass (map to technology primitives). + +6.15.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v' to AST representation. +Generating RTLIL representation for module `\_90_lut_cmp_'. +Successfully finished Verilog frontend. + +6.15.2. Continuing TECHMAP pass. +No more expansions possible. + +6.16. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). +Checking cell `$memwr$\memory$attributes_test.v:38$193' in module `\distributed_ram': merged $dff to cell. +Checking cell `$memrd$\memory$attributes_test.v:39$192' in module `\distributed_ram': merged data $dff to cell. + +6.17. Executing TECHMAP pass (map to technology primitives). + +6.17.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v' to AST representation. +Generating RTLIL representation for module `\_80_mul'. +Generating RTLIL representation for module `\_90_soft_mul'. +Successfully finished Verilog frontend. + +6.17.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v' to AST representation. +Generating RTLIL representation for module `\$__MUL25X18'. +Successfully finished Verilog frontend. + +6.17.3. Continuing TECHMAP pass. +No more expansions possible. + +6.18. Executing OPT_EXPR pass (perform const folding). + +6.19. Executing WREDUCE pass (reducing word size of cells). + +6.20. Executing XILINX_DSP pass (pack resources into DSPs). + +6.21. Executing ALUMACC pass (create $alu and $macc cells). +Extracting $alu and $macc cells in module distributed_ram: + created 0 $alu and 0 $macc cells. + +6.22. Executing SHARE pass (SAT-based resource sharing). + +6.23. Executing OPT pass (performing simple optimizations). + +6.23.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.23.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.23.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +6.23.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \distributed_ram. +Performed a total of 0 changes. + +6.23.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.23.6. Executing OPT_RMDFF pass (remove dff with constant values). + +6.23.7. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. +Removed 4 unused cells and 5 unused wires. + + +6.23.8. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.23.9. Rerunning OPT passes. (Maybe there is more to do..) + +6.23.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +6.23.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \distributed_ram. +Performed a total of 0 changes. + +6.23.12. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.23.13. Executing OPT_RMDFF pass (remove dff with constant values). + +6.23.14. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.23.15. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.23.16. Finished OPT passes. (There is nothing left to do.) + +6.24. Executing FSM pass (extract and optimize FSM). + +6.24.1. Executing FSM_DETECT pass (finding FSMs in design). + +6.24.2. Executing FSM_EXTRACT pass (extracting FSM from design). + +6.24.3. Executing FSM_OPT pass (simple optimizations of FSMs). + +6.24.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.24.5. Executing FSM_OPT pass (simple optimizations of FSMs). + +6.24.6. Executing FSM_RECODE pass (re-assigning FSM state encoding). + +6.24.7. Executing FSM_INFO pass (dumping all available information on FSM cells). + +6.24.8. Executing FSM_MAP pass (mapping FSMs to basic logic). + +6.25. Executing OPT pass (performing simple optimizations). + +6.25.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.25.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.25.3. Executing OPT_RMDFF pass (remove dff with constant values). + +6.25.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.25.5. Finished fast OPT passes. + +6.26. Executing MEMORY pass. + +6.26.1. Executing OPT_MEM pass (optimize memories). +Performed a total of 0 transformations. + +6.26.2. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). + +6.26.3. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.26.4. Executing MEMORY_SHARE pass (consolidating $memrd/$memwr cells). + +6.26.5. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.26.6. Executing MEMORY_COLLECT pass (generating $mem cells). +Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram': + $memwr$\memory$attributes_test.v:38$193 ($memwr) + $memrd$\memory$attributes_test.v:39$192 ($memrd) + +6.27. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.28. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). +Processing distributed_ram.memory: + Properties: ports=2 bits=128 rports=1 wports=1 dbits=8 abits=4 words=16 + Checking rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1): + Bram geometry: abits=9 dbits=72 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_SDP: awaste=496 dwaste=64 bwaste=36736 waste=36736 efficiency=0 + Rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1) rejected: requirement 'min efficiency 5' not met. + Checking rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1): + Bram geometry: abits=9 dbits=36 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_SDP: awaste=496 dwaste=28 bwaste=18304 waste=18304 efficiency=0 + Rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1) rejected: requirement 'min efficiency 5' not met. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1): + Bram geometry: abits=10 dbits=36 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=1008 dwaste=28 bwaste=36736 waste=36736 efficiency=0 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1) rejected: requirement 'min efficiency 5' not met. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2): + Bram geometry: abits=11 dbits=18 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=2032 dwaste=10 bwaste=36736 waste=36736 efficiency=0 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2) rejected: requirement 'min efficiency 5' not met. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3): + Bram geometry: abits=12 dbits=9 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=4080 dwaste=1 bwaste=36736 waste=36736 efficiency=0 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3) rejected: requirement 'min efficiency 5' not met. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4): + Bram geometry: abits=13 dbits=4 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=8176 dwaste=0 bwaste=32704 waste=32704 efficiency=0 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4) rejected: requirement 'min efficiency 5' not met. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5): + Bram geometry: abits=14 dbits=2 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=16368 dwaste=0 bwaste=32736 waste=32736 efficiency=0 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5) rejected: requirement 'min efficiency 5' not met. + Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6): + Bram geometry: abits=15 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB36_TDP: awaste=32752 dwaste=0 bwaste=32752 waste=32752 efficiency=0 + Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6) rejected: requirement 'min efficiency 5' not met. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1): + Bram geometry: abits=10 dbits=18 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=1008 dwaste=10 bwaste=18304 waste=18304 efficiency=0 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1) rejected: requirement 'min efficiency 5' not met. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2): + Bram geometry: abits=11 dbits=9 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=2032 dwaste=1 bwaste=18304 waste=18304 efficiency=0 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2) rejected: requirement 'min efficiency 5' not met. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3): + Bram geometry: abits=12 dbits=4 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=4080 dwaste=0 bwaste=16320 waste=16320 efficiency=0 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3) rejected: requirement 'min efficiency 5' not met. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4): + Bram geometry: abits=13 dbits=2 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=8176 dwaste=0 bwaste=16352 waste=16352 efficiency=0 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4) rejected: requirement 'min efficiency 5' not met. + Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5): + Bram geometry: abits=14 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAMB18_TDP: awaste=16368 dwaste=0 bwaste=16368 waste=16368 efficiency=0 + Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5) rejected: requirement 'min efficiency 5' not met. + No acceptable bram resources found. + +6.29. Executing TECHMAP pass (map to technology primitives). + +6.29.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v' to AST representation. +Generating RTLIL representation for module `\$__XILINX_RAMB36_SDP'. +Generating RTLIL representation for module `\$__XILINX_RAMB18_SDP'. +Generating RTLIL representation for module `\$__XILINX_RAMB36_TDP'. +Generating RTLIL representation for module `\$__XILINX_RAMB18_TDP'. +Successfully finished Verilog frontend. + +6.29.2. Continuing TECHMAP pass. +No more expansions possible. + +6.30. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). +Processing distributed_ram.memory: + Properties: ports=2 bits=128 rports=1 wports=1 dbits=8 abits=4 words=16 + Checking rule #1 for bram type $__XILINX_RAM32X1D (variant 1): + Bram geometry: abits=5 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAM32X1D: awaste=16 dwaste=0 bwaste=16 waste=16 efficiency=50 + Rule #1 for bram type $__XILINX_RAM32X1D (variant 1) accepted. + Mapping to bram type $__XILINX_RAM32X1D (variant 1): + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=16 efficiency=50 + Storing for later selection. + Checking rule #2 for bram type $__XILINX_RAM64X1D (variant 1): + Bram geometry: abits=6 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAM64X1D: awaste=48 dwaste=0 bwaste=48 waste=48 efficiency=25 + Rule #2 for bram type $__XILINX_RAM64X1D (variant 1) accepted. + Mapping to bram type $__XILINX_RAM64X1D (variant 1): + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=48 efficiency=25 + Storing for later selection. + Checking rule #3 for bram type $__XILINX_RAM128X1D (variant 1): + Bram geometry: abits=7 dbits=1 wports=0 rports=0 + Estimated number of duplicates for more read ports: dups=1 + Metrics for $__XILINX_RAM128X1D: awaste=112 dwaste=0 bwaste=112 waste=112 efficiency=12 + Rule #3 for bram type $__XILINX_RAM128X1D (variant 1) accepted. + Mapping to bram type $__XILINX_RAM128X1D (variant 1): + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Updated properties: dups=1 waste=112 efficiency=12 + Storing for later selection. + Selecting best of 3 rules: + Efficiency for rule 3.1: efficiency=12, cells=8, acells=1 + Efficiency for rule 2.1: efficiency=25, cells=8, acells=1 + Efficiency for rule 1.1: efficiency=50, cells=8, acells=1 + Selected rule 1.1 with efficiency 50. + Mapping to bram type $__XILINX_RAM32X1D (variant 1): + Write port #0 is in clock domain \clk. + Mapped to bram port B1. + Read port #0 is in clock domain \clk. + Mapped to bram port A1.1. + Creating $__XILINX_RAM32X1D cell at grid position <0 0 0>: memory.0.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <1 0 0>: memory.1.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <2 0 0>: memory.2.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <3 0 0>: memory.3.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <4 0 0>: memory.4.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <5 0 0>: memory.5.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <6 0 0>: memory.6.0.0 + Creating $__XILINX_RAM32X1D cell at grid position <7 0 0>: memory.7.0.0 + +6.31. Executing TECHMAP pass (map to technology primitives). + +6.31.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v' to AST representation. +Generating RTLIL representation for module `\$__XILINX_RAM32X1D'. +Generating RTLIL representation for module `\$__XILINX_RAM64X1D'. +Generating RTLIL representation for module `\$__XILINX_RAM128X1D'. +Successfully finished Verilog frontend. + +6.31.2. Continuing TECHMAP pass. +Using template $paramod\$__XILINX_RAM32X1D\CLKPOL2=1 for cells of type $__XILINX_RAM32X1D. +No more expansions possible. + + +6.32. Executing OPT pass (performing simple optimizations). + +6.32.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + + +6.32.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.32.3. Executing OPT_RMDFF pass (remove dff with constant values). + +6.32.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. +Removed 0 unused cells and 65 unused wires. + + +6.32.5. Finished fast OPT passes. + +6.33. Executing MEMORY_MAP pass (converting $mem cells to logic and flip-flops). + +6.34. Executing DFFSR2DFF pass (mapping DFFSR cells to simpler FFs). + +6.35. Executing DFF2DFFE pass (transform $dff to $dffe where applicable). +Transforming FF to FF+Enable cells in module distributed_ram: + +6.36. Executing OPT pass (performing simple optimizations). + +6.36.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.36.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.36.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + No muxes found in this module. +Removed 0 multiplexer ports. + +6.36.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \distributed_ram. +Performed a total of 0 changes. + +6.36.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.36.6. Executing OPT_SHARE pass. + +6.36.7. Executing OPT_RMDFF pass (remove dff with constant values). + +6.36.8. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.36.9. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.36.10. Finished OPT passes. (There is nothing left to do.) + +6.37. Executing XILINX_SRL pass (Xilinx shift register extraction). + +6.38. Executing TECHMAP pass (map to technology primitives). + +6.38.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. +Generating RTLIL representation for module `\_90_simplemap_bool_ops'. +Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. +Generating RTLIL representation for module `\_90_simplemap_logic_ops'. +Generating RTLIL representation for module `\_90_simplemap_compare_ops'. +Generating RTLIL representation for module `\_90_simplemap_various'. +Generating RTLIL representation for module `\_90_simplemap_registers'. +Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. +Generating RTLIL representation for module `\_90_shift_shiftx'. +Generating RTLIL representation for module `\_90_fa'. +Generating RTLIL representation for module `\_90_lcu'. +Generating RTLIL representation for module `\_90_alu'. +Generating RTLIL representation for module `\_90_macc'. +Generating RTLIL representation for module `\_90_alumacc'. +Generating RTLIL representation for module `\$__div_mod_u'. +Generating RTLIL representation for module `\$__div_mod'. +Generating RTLIL representation for module `\_90_div'. +Generating RTLIL representation for module `\_90_mod'. +Generating RTLIL representation for module `\_90_pow'. +Generating RTLIL representation for module `\_90_pmux'. +Generating RTLIL representation for module `\_90_lut'. +Successfully finished Verilog frontend. + +6.38.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v' to AST representation. +Generating RTLIL representation for module `\_80_xilinx_lcu'. +Generating RTLIL representation for module `\_80_xilinx_alu'. +Successfully finished Verilog frontend. + +6.38.3. Continuing TECHMAP pass. +Using extmapper simplemap for cells of type $dff. +No more expansions possible. + + +6.39. Executing OPT pass (performing simple optimizations). + +6.39.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.39.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\distributed_ram'. +Removed a total of 0 cells. + +6.39.3. Executing OPT_RMDFF pass (remove dff with constant values). + +6.39.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram.. + +6.39.5. Finished fast OPT passes. + +6.40. Executing TECHMAP pass (map to technology primitives). + +6.40.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. +Generating RTLIL representation for module `\_90_simplemap_bool_ops'. +Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. +Generating RTLIL representation for module `\_90_simplemap_logic_ops'. +Generating RTLIL representation for module `\_90_simplemap_compare_ops'. +Generating RTLIL representation for module `\_90_simplemap_various'. +Generating RTLIL representation for module `\_90_simplemap_registers'. +Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. +Generating RTLIL representation for module `\_90_shift_shiftx'. +Generating RTLIL representation for module `\_90_fa'. +Generating RTLIL representation for module `\_90_lcu'. +Generating RTLIL representation for module `\_90_alu'. +Generating RTLIL representation for module `\_90_macc'. +Generating RTLIL representation for module `\_90_alumacc'. +Generating RTLIL representation for module `\$__div_mod_u'. +Generating RTLIL representation for module `\$__div_mod'. +Generating RTLIL representation for module `\_90_div'. +Generating RTLIL representation for module `\_90_mod'. +Generating RTLIL representation for module `\_90_pow'. +Generating RTLIL representation for module `\_90_pmux'. +Generating RTLIL representation for module `\_90_lut'. +Successfully finished Verilog frontend. + +6.40.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. +Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. +Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. +Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. +Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. +Generating RTLIL representation for module `\$__SHREG_'. +Generating RTLIL representation for module `\$__XILINX_SHREG_'. +Generating RTLIL representation for module `\$__XILINX_MUXF78'. +Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. +Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. +Successfully finished Verilog frontend. + +6.40.3. Continuing TECHMAP pass. +No more expansions possible. + +6.41. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram. + +6.42. Executing ABC pass (technology mapping using ABC). + +6.42.1. Extracting gate netlist of module `\distributed_ram' to `/input.blif'.. +Extracted 0 gates and 0 wires to a netlist network with 0 inputs and 0 outputs. +Don't call ABC as there is nothing to map. +Removing temp directory. + +6.43. Executing XILINX_SRL pass (Xilinx shift register extraction). + +6.44. Executing TECHMAP pass (map to technology primitives). + +6.44.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v' to AST representation. +Generating RTLIL representation for module `\$lut'. +Successfully finished Verilog frontend. + +6.44.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. +Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. +Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. +Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. +Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. +Generating RTLIL representation for module `\$__SHREG_'. +Generating RTLIL representation for module `\$__XILINX_SHREG_'. +Generating RTLIL representation for module `\$__XILINX_MUXF78'. +Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. +Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. +Successfully finished Verilog frontend. + +6.44.3. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v' to AST representation. +Generating RTLIL representation for module `\$_DFF_N_'. +Generating RTLIL representation for module `\$_DFF_P_'. +Generating RTLIL representation for module `\$_DFFE_NP_'. +Generating RTLIL representation for module `\$_DFFE_PP_'. +Generating RTLIL representation for module `\$_DFF_NN0_'. +Generating RTLIL representation for module `\$_DFF_NP0_'. +Generating RTLIL representation for module `\$_DFF_PN0_'. +Generating RTLIL representation for module `\$_DFF_PP0_'. +Generating RTLIL representation for module `\$_DFF_NN1_'. +Generating RTLIL representation for module `\$_DFF_NP1_'. +Generating RTLIL representation for module `\$_DFF_PN1_'. +Generating RTLIL representation for module `\$_DFF_PP1_'. +Generating RTLIL representation for module `\$_DLATCH_N_'. +Generating RTLIL representation for module `\$_DLATCH_P_'. +Successfully finished Verilog frontend. + +6.44.4. Continuing TECHMAP pass. +Using template $paramod\$_DFF_P_\_TECHMAP_WIREINIT_Q_=1'x for cells of type $_DFF_P_. +No more expansions possible. + +Removed 0 unused cells and 32 unused wires. + +6.45. Executing CLKBUFMAP pass (inserting global clock buffers). +Inserting BUFG on distributed_ram.clk[0]. + +6.46. Executing HIERARCHY pass (managing design hierarchy). + +6.46.1. Analyzing design hierarchy.. +Top module: \distributed_ram + +6.46.2. Analyzing design hierarchy.. +Top module: \distributed_ram +Removed 0 unused modules. + +6.47. Printing statistics. + +=== distributed_ram === + + Number of wires: 16 + Number of wire bits: 40 + Number of public wires: 6 + Number of public wire bits: 30 + Number of memories: 0 + Number of memory bits: 0 + Number of processes: 0 + Number of cells: 17 + BUFG 1 + FDRE 8 + RAM32X1D 8 + + Estimated number of LCs: 0 + +6.48. Executing CHECK pass (checking for obvious problems). +checking module distributed_ram.. +found and reported 0 problems. + +7. Executing Verilog-2005 frontend: attributes_test.v +Parsing Verilog input from `attributes_test.v' to AST representation. +Generating RTLIL representation for module `\block_ram'. +Generating RTLIL representation for module `\distributed_ram'. +Generating RTLIL representation for module `\distributed_ram_manual'. +Generating RTLIL representation for module `\distributed_ram_manual_syn'. +Successfully finished Verilog frontend. + +8. Executing PREP pass. + +8.1. Executing HIERARCHY pass (managing design hierarchy). + +8.2. Executing PROC pass (convert processes to netlists). + +8.2.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Cleaned up 0 empty switches. + +8.2.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). +Removed a total of 0 dead cases. + +8.2.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). +Removed 0 redundant assignments. +Promoted 4 assignments to connections. + +8.2.4. Executing PROC_INIT pass (extract init attributes). + +8.2.5. Executing PROC_ARST pass (detect async resets in processes). + +8.2.6. Executing PROC_MUX pass (convert decision trees to multiplexers). +Creating decoders for process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. + 1/3: $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 + 2/3: $0$memwr$\memory$attributes_test.v:82$440_DATA[7:0]$444 + 3/3: $0$memwr$\memory$attributes_test.v:82$440_ADDR[3:0]$442 +Creating decoders for process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. + 1/3: $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 + 2/3: $0$memwr$\memory$attributes_test.v:60$433_DATA[7:0]$437 + 3/3: $0$memwr$\memory$attributes_test.v:60$433_ADDR[3:0]$436 +Creating decoders for process `\distributed_ram.$proc$attributes_test.v:36$427'. + 1/3: $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 + 2/3: $0$memwr$\memory$attributes_test.v:38$426_DATA[7:0]$429 + 3/3: $0$memwr$\memory$attributes_test.v:38$426_ADDR[3:0]$428 +Creating decoders for process `\block_ram.$proc$attributes_test.v:14$420'. + 1/3: $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 + 2/3: $0$memwr$\memory$attributes_test.v:16$419_DATA[3:0]$422 + 3/3: $0$memwr$\memory$attributes_test.v:16$419_ADDR[9:0]$421 + +8.2.7. Executing PROC_DLATCH pass (convert process syncs to latches). + +8.2.8. Executing PROC_DFF pass (convert process syncs to FFs). +Creating register for signal `\distributed_ram_manual_syn.$memwr$\memory$attributes_test.v:82$440_ADDR' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. + created $dff cell `$procdff$471' with positive edge clock. +Creating register for signal `\distributed_ram_manual_syn.\data_out_r' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. + created $dff cell `$procdff$472' with positive edge clock. +Creating register for signal `\distributed_ram_manual_syn.$memwr$\memory$attributes_test.v:82$440_EN' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. + created $dff cell `$procdff$473' with positive edge clock. +Creating register for signal `\distributed_ram_manual_syn.$memwr$\memory$attributes_test.v:82$440_DATA' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. + created $dff cell `$procdff$474' with positive edge clock. +Creating register for signal `\distributed_ram_manual.$memwr$\memory$attributes_test.v:60$433_EN' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. + created $dff cell `$procdff$475' with positive edge clock. +Creating register for signal `\distributed_ram_manual.$memwr$\memory$attributes_test.v:60$433_ADDR' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. + created $dff cell `$procdff$476' with positive edge clock. +Creating register for signal `\distributed_ram_manual.$memwr$\memory$attributes_test.v:60$433_DATA' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. + created $dff cell `$procdff$477' with positive edge clock. +Creating register for signal `\distributed_ram_manual.\data_out_r' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. + created $dff cell `$procdff$478' with positive edge clock. +Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$426_ADDR' using process `\distributed_ram.$proc$attributes_test.v:36$427'. + created $dff cell `$procdff$479' with positive edge clock. +Creating register for signal `\distributed_ram.\data_out_r' using process `\distributed_ram.$proc$attributes_test.v:36$427'. + created $dff cell `$procdff$480' with positive edge clock. +Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$426_DATA' using process `\distributed_ram.$proc$attributes_test.v:36$427'. + created $dff cell `$procdff$481' with positive edge clock. +Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$426_EN' using process `\distributed_ram.$proc$attributes_test.v:36$427'. + created $dff cell `$procdff$482' with positive edge clock. +Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$419_ADDR' using process `\block_ram.$proc$attributes_test.v:14$420'. + created $dff cell `$procdff$483' with positive edge clock. +Creating register for signal `\block_ram.\data_out_r' using process `\block_ram.$proc$attributes_test.v:14$420'. + created $dff cell `$procdff$484' with positive edge clock. +Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$419_DATA' using process `\block_ram.$proc$attributes_test.v:14$420'. + created $dff cell `$procdff$485' with positive edge clock. +Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$419_EN' using process `\block_ram.$proc$attributes_test.v:14$420'. + created $dff cell `$procdff$486' with positive edge clock. + +8.2.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Found and cleaned up 1 empty switch in `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. +Removing empty process `distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. +Found and cleaned up 1 empty switch in `\distributed_ram_manual.$proc$attributes_test.v:58$434'. +Removing empty process `distributed_ram_manual.$proc$attributes_test.v:58$434'. +Found and cleaned up 1 empty switch in `\distributed_ram.$proc$attributes_test.v:36$427'. +Removing empty process `distributed_ram.$proc$attributes_test.v:36$427'. +Found and cleaned up 1 empty switch in `\block_ram.$proc$attributes_test.v:14$420'. +Removing empty process `block_ram.$proc$attributes_test.v:14$420'. +Cleaned up 4 empty switches. + +8.3. Executing OPT_EXPR pass (perform const folding). +Optimizing module distributed_ram_manual_syn. +Optimizing module distributed_ram_manual. +Optimizing module distributed_ram. +Optimizing module block_ram. + +8.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \distributed_ram_manual_syn.. +Finding unused cells or wires in module \distributed_ram_manual.. +Finding unused cells or wires in module \distributed_ram.. +Finding unused cells or wires in module \block_ram.. +Removed 0 unused cells and 28 unused wires. + + +8.5. Executing CHECK pass (checking for obvious problems). +checking module block_ram.. +checking module distributed_ram.. +checking module distributed_ram_manual.. +checking module distributed_ram_manual_syn.. +found and reported 0 problems. + +8.6. Executing OPT pass (performing simple optimizations). + +8.6.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. +Optimizing module distributed_ram. +Optimizing module distributed_ram_manual. +Optimizing module distributed_ram_manual_syn. + +8.6.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Finding identical cells in module `\distributed_ram'. +Finding identical cells in module `\distributed_ram_manual'. +Finding identical cells in module `\distributed_ram_manual_syn'. +Removed a total of 0 cells. + +8.6.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Running muxtree optimizer on module \distributed_ram_manual.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Running muxtree optimizer on module \distributed_ram_manual_syn.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +8.6.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. + Consolidated identical input bits for $mux cell $procmux$465: + Old ports: A=4'0000, B=4'1111, Y=$0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 + New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] + New connections: $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [3:1] = { $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] } + Optimizing cells in module \block_ram. + Optimizing cells in module \distributed_ram. + Consolidated identical input bits for $mux cell $procmux$459: + Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 + New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] + New connections: $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [7:1] = { $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] } + Optimizing cells in module \distributed_ram. + Optimizing cells in module \distributed_ram_manual. + Consolidated identical input bits for $mux cell $procmux$453: + Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 + New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] + New connections: $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [7:1] = { $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] } + Optimizing cells in module \distributed_ram_manual. + Optimizing cells in module \distributed_ram_manual_syn. + Consolidated identical input bits for $mux cell $procmux$447: + Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 + New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] + New connections: $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [7:1] = { $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] } + Optimizing cells in module \distributed_ram_manual_syn. +Performed a total of 4 changes. + +8.6.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Finding identical cells in module `\distributed_ram'. +Finding identical cells in module `\distributed_ram_manual'. +Finding identical cells in module `\distributed_ram_manual_syn'. +Removed a total of 0 cells. + +8.6.6. Executing OPT_RMDFF pass (remove dff with constant values). + +8.6.7. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Finding unused cells or wires in module \distributed_ram.. +Finding unused cells or wires in module \distributed_ram_manual.. +Finding unused cells or wires in module \distributed_ram_manual_syn.. + +8.6.8. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. +Optimizing module distributed_ram. +Optimizing module distributed_ram_manual. +Optimizing module distributed_ram_manual_syn. + +8.6.9. Rerunning OPT passes. (Maybe there is more to do..) + +8.6.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Running muxtree optimizer on module \distributed_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Running muxtree optimizer on module \distributed_ram_manual.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Running muxtree optimizer on module \distributed_ram_manual_syn.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +8.6.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. + Optimizing cells in module \distributed_ram. + Optimizing cells in module \distributed_ram_manual. + Optimizing cells in module \distributed_ram_manual_syn. +Performed a total of 0 changes. + +8.6.12. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Finding identical cells in module `\distributed_ram'. +Finding identical cells in module `\distributed_ram_manual'. +Finding identical cells in module `\distributed_ram_manual_syn'. +Removed a total of 0 cells. + +8.6.13. Executing OPT_RMDFF pass (remove dff with constant values). + +8.6.14. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Finding unused cells or wires in module \distributed_ram.. +Finding unused cells or wires in module \distributed_ram_manual.. +Finding unused cells or wires in module \distributed_ram_manual_syn.. + +8.6.15. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. +Optimizing module distributed_ram. +Optimizing module distributed_ram_manual. +Optimizing module distributed_ram_manual_syn. + +8.6.16. Finished OPT passes. (There is nothing left to do.) + +8.7. Executing WREDUCE pass (reducing word size of cells). +Removed top 3 bits (of 4) from FF cell block_ram.$procdff$486 ($dff). +Removed top 7 bits (of 8) from FF cell distributed_ram.$procdff$482 ($dff). +Removed top 7 bits (of 8) from FF cell distributed_ram_manual.$procdff$475 ($dff). +Removed top 7 bits (of 8) from FF cell distributed_ram_manual_syn.$procdff$473 ($dff). + +8.8. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). +Checking cell `$memwr$\memory$attributes_test.v:16$425' in module `\block_ram': merged $dff to cell. +Checking cell `$memwr$\memory$attributes_test.v:38$432' in module `\distributed_ram': merged $dff to cell. +Checking cell `$memwr$\memory$attributes_test.v:60$439' in module `\distributed_ram_manual': merged $dff to cell. +Checking cell `$memwr$\memory$attributes_test.v:82$446' in module `\distributed_ram_manual_syn': merged $dff to cell. + +8.9. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Finding unused cells or wires in module \distributed_ram.. +Finding unused cells or wires in module \distributed_ram_manual.. +Finding unused cells or wires in module \distributed_ram_manual_syn.. +Removed 12 unused cells and 12 unused wires. + + +8.10. Executing MEMORY_COLLECT pass (generating $mem cells). +Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\block_ram': + $memwr$\memory$attributes_test.v:16$425 ($memwr) + $memrd$\memory$attributes_test.v:17$424 ($memrd) +Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram': + $memwr$\memory$attributes_test.v:38$432 ($memwr) + $memrd$\memory$attributes_test.v:39$431 ($memrd) +Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram_manual': + $memwr$\memory$attributes_test.v:60$439 ($memwr) + $memrd$\memory$attributes_test.v:61$438 ($memrd) +Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram_manual_syn': + $memwr$\memory$attributes_test.v:82$446 ($memwr) + $memrd$\memory$attributes_test.v:83$445 ($memrd) + +8.11. Executing OPT pass (performing simple optimizations). + +8.11.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. +Optimizing module distributed_ram. +Optimizing module distributed_ram_manual. +Optimizing module distributed_ram_manual_syn. + +8.11.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Finding identical cells in module `\distributed_ram'. +Finding identical cells in module `\distributed_ram_manual'. +Finding identical cells in module `\distributed_ram_manual_syn'. +Removed a total of 0 cells. + +8.11.3. Executing OPT_RMDFF pass (remove dff with constant values). + +8.11.4. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Finding unused cells or wires in module \distributed_ram.. +Finding unused cells or wires in module \distributed_ram_manual.. +Finding unused cells or wires in module \distributed_ram_manual_syn.. + +8.11.5. Finished fast OPT passes. + +8.12. Printing statistics. + +=== block_ram === + + Number of wires: 10 + Number of wire bits: 46 + Number of public wires: 6 + Number of public wire bits: 24 + Number of memories: 0 + Number of memory bits: 0 + Number of processes: 0 + Number of cells: 5 + $dff 1 + $mem 1 + $mux 3 + +=== distributed_ram === + + Number of wires: 10 + Number of wire bits: 58 + Number of public wires: 6 + Number of public wire bits: 30 + Number of memories: 0 + Number of memory bits: 0 + Number of processes: 0 + Number of cells: 5 + $dff 1 + $mem 1 + $mux 3 + +=== distributed_ram_manual === + + Number of wires: 10 + Number of wire bits: 58 + Number of public wires: 6 + Number of public wire bits: 30 + Number of memories: 0 + Number of memory bits: 0 + Number of processes: 0 + Number of cells: 5 + $dff 1 + $mem 1 + $mux 3 + +=== distributed_ram_manual_syn === + + Number of wires: 10 + Number of wire bits: 58 + Number of public wires: 6 + Number of public wire bits: 30 + Number of memories: 0 + Number of memory bits: 0 + Number of processes: 0 + Number of cells: 5 + $dff 1 + $mem 1 + $mux 3 + +8.13. Executing CHECK pass (checking for obvious problems). +checking module block_ram.. +checking module distributed_ram.. +checking module distributed_ram_manual.. +checking module distributed_ram_manual_syn.. +found and reported 0 problems. + +9. Executing SYNTH_XILINX pass. + +9.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v' to AST representation. +Generating RTLIL representation for module `\VCC'. +Generating RTLIL representation for module `\GND'. +Generating RTLIL representation for module `\IBUF'. +Generating RTLIL representation for module `\IBUFG'. +Generating RTLIL representation for module `\OBUF'. +Generating RTLIL representation for module `\IOBUF'. +Generating RTLIL representation for module `\OBUFT'. +Generating RTLIL representation for module `\BUFG'. +Generating RTLIL representation for module `\BUFGCTRL'. +Generating RTLIL representation for module `\BUFHCE'. +Generating RTLIL representation for module `\INV'. +Generating RTLIL representation for module `\LUT1'. +Generating RTLIL representation for module `\LUT2'. +Generating RTLIL representation for module `\LUT3'. +Generating RTLIL representation for module `\LUT4'. +Generating RTLIL representation for module `\LUT5'. +Generating RTLIL representation for module `\LUT6'. +Generating RTLIL representation for module `\LUT6_2'. +Generating RTLIL representation for module `\MUXCY'. +Generating RTLIL representation for module `\MUXF7'. +Generating RTLIL representation for module `\MUXF8'. +Generating RTLIL representation for module `\XORCY'. +Generating RTLIL representation for module `\CARRY4'. +Generating RTLIL representation for module `\FDRE'. +Generating RTLIL representation for module `\FDSE'. +Generating RTLIL representation for module `\FDCE'. +Generating RTLIL representation for module `\FDPE'. +Generating RTLIL representation for module `\FDRE_1'. +Generating RTLIL representation for module `\FDSE_1'. +Generating RTLIL representation for module `\FDCE_1'. +Generating RTLIL representation for module `\FDPE_1'. +Generating RTLIL representation for module `\LDCE'. +Generating RTLIL representation for module `\LDPE'. +Generating RTLIL representation for module `\RAM16X1S'. +Generating RTLIL representation for module `\RAM16X1S_1'. +Generating RTLIL representation for module `\RAM32X1S'. +Generating RTLIL representation for module `\RAM32X1S_1'. +Generating RTLIL representation for module `\RAM64X1S'. +Generating RTLIL representation for module `\RAM64X1S_1'. +Generating RTLIL representation for module `\RAM128X1S'. +Generating RTLIL representation for module `\RAM128X1S_1'. +Generating RTLIL representation for module `\RAM256X1S'. +Generating RTLIL representation for module `\RAM512X1S'. +Generating RTLIL representation for module `\RAM16X2S'. +Generating RTLIL representation for module `\RAM32X2S'. +Generating RTLIL representation for module `\RAM64X2S'. +Generating RTLIL representation for module `\RAM16X4S'. +Generating RTLIL representation for module `\RAM32X4S'. +Generating RTLIL representation for module `\RAM16X8S'. +Generating RTLIL representation for module `\RAM32X8S'. +Generating RTLIL representation for module `\RAM16X1D'. +Generating RTLIL representation for module `\RAM16X1D_1'. +Generating RTLIL representation for module `\RAM32X1D'. +Generating RTLIL representation for module `\RAM32X1D_1'. +Generating RTLIL representation for module `\RAM64X1D'. +Generating RTLIL representation for module `\RAM64X1D_1'. +Generating RTLIL representation for module `\RAM128X1D'. +Generating RTLIL representation for module `\RAM256X1D'. +Generating RTLIL representation for module `\RAM32M'. +Generating RTLIL representation for module `\RAM32M16'. +Generating RTLIL representation for module `\RAM64M'. +Generating RTLIL representation for module `\RAM64M8'. +Generating RTLIL representation for module `\ROM16X1'. +Generating RTLIL representation for module `\ROM32X1'. +Generating RTLIL representation for module `\ROM64X1'. +Generating RTLIL representation for module `\ROM128X1'. +Generating RTLIL representation for module `\ROM256X1'. +Generating RTLIL representation for module `\SRL16E'. +Generating RTLIL representation for module `\SRLC16E'. +Generating RTLIL representation for module `\SRLC32E'. +Generating RTLIL representation for module `\MULT18X18'. +Generating RTLIL representation for module `\MULT18X18S'. +Generating RTLIL representation for module `\MULT18X18SIO'. +Generating RTLIL representation for module `\DSP48A'. +Generating RTLIL representation for module `\DSP48A1'. +Generating RTLIL representation for module `\DSP48E1'. +Successfully finished Verilog frontend. + +9.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v' to AST representation. +Generating RTLIL representation for module `\FDCPE'. +Generating RTLIL representation for module `\FDRSE'. +Generating RTLIL representation for module `\LDCPE'. +Generating RTLIL representation for module `\AND2B1L'. +Generating RTLIL representation for module `\OR2L'. +Generating RTLIL representation for module `\MUXF5'. +Generating RTLIL representation for module `\MUXF6'. +Generating RTLIL representation for module `\MUXF9'. +Generating RTLIL representation for module `\CARRY8'. +Generating RTLIL representation for module `\ORCY'. +Generating RTLIL representation for module `\MULT_AND'. +Generating RTLIL representation for module `\SRL16'. +Generating RTLIL representation for module `\SRLC16'. +Generating RTLIL representation for module `\CFGLUT5'. +Generating RTLIL representation for module `\RAMB16_S1'. +Generating RTLIL representation for module `\RAMB16_S2'. +Generating RTLIL representation for module `\RAMB16_S4'. +Generating RTLIL representation for module `\RAMB16_S9'. +Generating RTLIL representation for module `\RAMB16_S18'. +Generating RTLIL representation for module `\RAMB16_S36'. +Generating RTLIL representation for module `\RAMB16_S1_S1'. +Generating RTLIL representation for module `\RAMB16_S1_S2'. +Generating RTLIL representation for module `\RAMB16_S1_S4'. +Generating RTLIL representation for module `\RAMB16_S1_S9'. +Generating RTLIL representation for module `\RAMB16_S1_S18'. +Generating RTLIL representation for module `\RAMB16_S1_S36'. +Generating RTLIL representation for module `\RAMB16_S2_S2'. +Generating RTLIL representation for module `\RAMB16_S2_S4'. +Generating RTLIL representation for module `\RAMB16_S2_S9'. +Generating RTLIL representation for module `\RAMB16_S2_S18'. +Generating RTLIL representation for module `\RAMB16_S2_S36'. +Generating RTLIL representation for module `\RAMB16_S4_S4'. +Generating RTLIL representation for module `\RAMB16_S4_S9'. +Generating RTLIL representation for module `\RAMB16_S4_S18'. +Generating RTLIL representation for module `\RAMB16_S4_S36'. +Generating RTLIL representation for module `\RAMB16_S9_S9'. +Generating RTLIL representation for module `\RAMB16_S9_S18'. +Generating RTLIL representation for module `\RAMB16_S9_S36'. +Generating RTLIL representation for module `\RAMB16_S18_S18'. +Generating RTLIL representation for module `\RAMB16_S18_S36'. +Generating RTLIL representation for module `\RAMB16_S36_S36'. +Generating RTLIL representation for module `\RAMB16BWE_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36'. +Generating RTLIL representation for module `\RAMB16BWE_S18_S9'. +Generating RTLIL representation for module `\RAMB16BWE_S18_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S9'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S18'. +Generating RTLIL representation for module `\RAMB16BWE_S36_S36'. +Generating RTLIL representation for module `\RAMB16BWER'. +Generating RTLIL representation for module `\RAMB8BWER'. +Generating RTLIL representation for module `\FIFO16'. +Generating RTLIL representation for module `\RAMB16'. +Generating RTLIL representation for module `\RAMB32_S64_ECC'. +Generating RTLIL representation for module `\FIFO18'. +Generating RTLIL representation for module `\FIFO18_36'. +Generating RTLIL representation for module `\FIFO36'. +Generating RTLIL representation for module `\FIFO36_72'. +Generating RTLIL representation for module `\RAMB18'. +Generating RTLIL representation for module `\RAMB36'. +Generating RTLIL representation for module `\RAMB18SDP'. +Generating RTLIL representation for module `\RAMB36SDP'. +Generating RTLIL representation for module `\FIFO18E1'. +Generating RTLIL representation for module `\FIFO36E1'. +Generating RTLIL representation for module `\RAMB18E1'. +Generating RTLIL representation for module `\RAMB36E1'. +Generating RTLIL representation for module `\FIFO18E2'. +Generating RTLIL representation for module `\FIFO36E2'. +Generating RTLIL representation for module `\RAMB18E2'. +Generating RTLIL representation for module `\RAMB36E2'. +Generating RTLIL representation for module `\URAM288'. +Generating RTLIL representation for module `\URAM288_BASE'. +Generating RTLIL representation for module `\DSP48'. +Generating RTLIL representation for module `\DSP48E'. +Generating RTLIL representation for module `\DSP48E2'. +Generating RTLIL representation for module `\IFDDRCPE'. +Generating RTLIL representation for module `\IFDDRRSE'. +Generating RTLIL representation for module `\OFDDRCPE'. +Generating RTLIL representation for module `\OFDDRRSE'. +Generating RTLIL representation for module `\OFDDRTCPE'. +Generating RTLIL representation for module `\OFDDRTRSE'. +Generating RTLIL representation for module `\IDDR2'. +Generating RTLIL representation for module `\ODDR2'. +Generating RTLIL representation for module `\IDDR'. +Generating RTLIL representation for module `\IDDR_2CLK'. +Generating RTLIL representation for module `\ODDR'. +Generating RTLIL representation for module `\IDELAYCTRL'. +Generating RTLIL representation for module `\IDELAY'. +Generating RTLIL representation for module `\ISERDES'. +Generating RTLIL representation for module `\OSERDES'. +Generating RTLIL representation for module `\IODELAY'. +Generating RTLIL representation for module `\ISERDES_NODELAY'. +Generating RTLIL representation for module `\IODELAYE1'. +Generating RTLIL representation for module `\ISERDESE1'. +Generating RTLIL representation for module `\OSERDESE1'. +Generating RTLIL representation for module `\IDELAYE2'. +Generating RTLIL representation for module `\ODELAYE2'. +Generating RTLIL representation for module `\ISERDESE2'. +Generating RTLIL representation for module `\OSERDESE2'. +Generating RTLIL representation for module `\PHASER_IN'. +Generating RTLIL representation for module `\PHASER_IN_PHY'. +Generating RTLIL representation for module `\PHASER_OUT'. +Generating RTLIL representation for module `\PHASER_OUT_PHY'. +Generating RTLIL representation for module `\PHASER_REF'. +Generating RTLIL representation for module `\PHY_CONTROL'. +Generating RTLIL representation for module `\IDDRE1'. +Generating RTLIL representation for module `\ODDRE1'. +Generating RTLIL representation for module `\IDELAYE3'. +Generating RTLIL representation for module `\ODELAYE3'. +Generating RTLIL representation for module `\ISERDESE3'. +Generating RTLIL representation for module `\OSERDESE3'. +Generating RTLIL representation for module `\BITSLICE_CONTROL'. +Generating RTLIL representation for module `\RIU_OR'. +Generating RTLIL representation for module `\RX_BITSLICE'. +Generating RTLIL representation for module `\RXTX_BITSLICE'. +Generating RTLIL representation for module `\TX_BITSLICE'. +Generating RTLIL representation for module `\TX_BITSLICE_TRI'. +Generating RTLIL representation for module `\IODELAY2'. +Generating RTLIL representation for module `\IODRP2'. +Generating RTLIL representation for module `\IODRP2_MCB'. +Generating RTLIL representation for module `\ISERDES2'. +Generating RTLIL representation for module `\OSERDES2'. +Generating RTLIL representation for module `\IBUF_DLY_ADJ'. +Generating RTLIL representation for module `\IBUF_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUF_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUF_ANALOG'. +Generating RTLIL representation for module `\IBUFE3'. +Generating RTLIL representation for module `\IBUFDS'. +Generating RTLIL representation for module `\IBUFDS_DLY_ADJ'. +Generating RTLIL representation for module `\IBUFDS_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUFDS_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_IBUFDISABLE'. +Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_INTERMDISABLE'. +Generating RTLIL representation for module `\IBUFDSE3'. +Generating RTLIL representation for module `\IBUFDS_DPHY'. +Generating RTLIL representation for module `\IBUFGDS'. +Generating RTLIL representation for module `\IBUFGDS_DIFF_OUT'. +Generating RTLIL representation for module `\IOBUF_DCIEN'. +Generating RTLIL representation for module `\IOBUF_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFE3'. +Generating RTLIL representation for module `\IOBUFDS'. +Generating RTLIL representation for module `\IOBUFDS_DCIEN'. +Generating RTLIL representation for module `\IOBUFDS_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_DCIEN'. +Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_INTERMDISABLE'. +Generating RTLIL representation for module `\IOBUFDSE3'. +Generating RTLIL representation for module `\OBUFDS'. +Generating RTLIL representation for module `\OBUFDS_DPHY'. +Generating RTLIL representation for module `\OBUFTDS'. +Generating RTLIL representation for module `\KEEPER'. +Generating RTLIL representation for module `\PULLDOWN'. +Generating RTLIL representation for module `\PULLUP'. +Generating RTLIL representation for module `\DCIRESET'. +Generating RTLIL representation for module `\HPIO_VREF'. +Generating RTLIL representation for module `\BUFGCE'. +Generating RTLIL representation for module `\BUFGCE_1'. +Generating RTLIL representation for module `\BUFGMUX'. +Generating RTLIL representation for module `\BUFGMUX_1'. +Generating RTLIL representation for module `\BUFGMUX_CTRL'. +Generating RTLIL representation for module `\BUFGMUX_VIRTEX4'. +Generating RTLIL representation for module `\BUFG_GT'. +Generating RTLIL representation for module `\BUFG_GT_SYNC'. +Generating RTLIL representation for module `\BUFG_PS'. +Generating RTLIL representation for module `\BUFGCE_DIV'. +Generating RTLIL representation for module `\BUFH'. +Generating RTLIL representation for module `\BUFIO2'. +Generating RTLIL representation for module `\BUFIO2_2CLK'. +Generating RTLIL representation for module `\BUFIO2FB'. +Generating RTLIL representation for module `\BUFPLL'. +Generating RTLIL representation for module `\BUFPLL_MCB'. +Generating RTLIL representation for module `\BUFIO'. +Generating RTLIL representation for module `\BUFIODQS'. +Generating RTLIL representation for module `\BUFR'. +Generating RTLIL representation for module `\BUFMR'. +Generating RTLIL representation for module `\BUFMRCE'. +Generating RTLIL representation for module `\DCM'. +Generating RTLIL representation for module `\DCM_SP'. +Generating RTLIL representation for module `\DCM_CLKGEN'. +Generating RTLIL representation for module `\DCM_ADV'. +Generating RTLIL representation for module `\DCM_BASE'. +Generating RTLIL representation for module `\DCM_PS'. +Generating RTLIL representation for module `\PMCD'. +Generating RTLIL representation for module `\PLL_ADV'. +Generating RTLIL representation for module `\PLL_BASE'. +Generating RTLIL representation for module `\MMCM_ADV'. +Generating RTLIL representation for module `\MMCM_BASE'. +Generating RTLIL representation for module `\MMCME2_ADV'. +Generating RTLIL representation for module `\MMCME2_BASE'. +Generating RTLIL representation for module `\PLLE2_ADV'. +Generating RTLIL representation for module `\PLLE2_BASE'. +Generating RTLIL representation for module `\MMCME3_ADV'. +Generating RTLIL representation for module `\MMCME3_BASE'. +Generating RTLIL representation for module `\PLLE3_ADV'. +Generating RTLIL representation for module `\PLLE3_BASE'. +Generating RTLIL representation for module `\MMCME4_ADV'. +Generating RTLIL representation for module `\MMCME4_BASE'. +Generating RTLIL representation for module `\PLLE4_ADV'. +Generating RTLIL representation for module `\PLLE4_BASE'. +Generating RTLIL representation for module `\BUFT'. +Generating RTLIL representation for module `\IN_FIFO'. +Generating RTLIL representation for module `\OUT_FIFO'. +Generating RTLIL representation for module `\HARD_SYNC'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3E'. +Generating RTLIL representation for module `\STARTUP_SPARTAN3A'. +Generating RTLIL representation for module `\STARTUP_SPARTAN6'. +Generating RTLIL representation for module `\STARTUP_VIRTEX4'. +Generating RTLIL representation for module `\STARTUP_VIRTEX5'. +Generating RTLIL representation for module `\STARTUP_VIRTEX6'. +Generating RTLIL representation for module `\STARTUPE2'. +Generating RTLIL representation for module `\STARTUPE3'. +Generating RTLIL representation for module `\CAPTURE_SPARTAN3'. +Generating RTLIL representation for module `\CAPTURE_SPARTAN3A'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX4'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX5'. +Generating RTLIL representation for module `\CAPTURE_VIRTEX6'. +Generating RTLIL representation for module `\CAPTUREE2'. +Generating RTLIL representation for module `\ICAP_SPARTAN3A'. +Generating RTLIL representation for module `\ICAP_SPARTAN6'. +Generating RTLIL representation for module `\ICAP_VIRTEX4'. +Generating RTLIL representation for module `\ICAP_VIRTEX5'. +Generating RTLIL representation for module `\ICAP_VIRTEX6'. +Generating RTLIL representation for module `\ICAPE2'. +Generating RTLIL representation for module `\ICAPE3'. +Generating RTLIL representation for module `\BSCAN_SPARTAN3'. +Generating RTLIL representation for module `\BSCAN_SPARTAN3A'. +Generating RTLIL representation for module `\BSCAN_SPARTAN6'. +Generating RTLIL representation for module `\BSCAN_VIRTEX4'. +Generating RTLIL representation for module `\BSCAN_VIRTEX5'. +Generating RTLIL representation for module `\BSCAN_VIRTEX6'. +Generating RTLIL representation for module `\BSCANE2'. +Generating RTLIL representation for module `\DNA_PORT'. +Generating RTLIL representation for module `\DNA_PORTE2'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX4'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX5'. +Generating RTLIL representation for module `\FRAME_ECC_VIRTEX6'. +Generating RTLIL representation for module `\FRAME_ECCE2'. +Generating RTLIL representation for module `\FRAME_ECCE3'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX4'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX5'. +Generating RTLIL representation for module `\USR_ACCESS_VIRTEX6'. +Generating RTLIL representation for module `\USR_ACCESSE2'. +Generating RTLIL representation for module `\POST_CRC_INTERNAL'. +Generating RTLIL representation for module `\SUSPEND_SYNC'. +Generating RTLIL representation for module `\KEY_CLEAR'. +Generating RTLIL representation for module `\MASTER_JTAG'. +Generating RTLIL representation for module `\SPI_ACCESS'. +Generating RTLIL representation for module `\EFUSE_USR'. +Generating RTLIL representation for module `\SYSMON'. +Generating RTLIL representation for module `\XADC'. +Generating RTLIL representation for module `\SYSMONE1'. +Generating RTLIL representation for module `\SYSMONE4'. +Generating RTLIL representation for module `\GTPA1_DUAL'. +Generating RTLIL representation for module `\GT11_CUSTOM'. +Generating RTLIL representation for module `\GT11_DUAL'. +Generating RTLIL representation for module `\GT11CLK'. +Generating RTLIL representation for module `\GT11CLK_MGT'. +Generating RTLIL representation for module `\GTP_DUAL'. +Generating RTLIL representation for module `\GTX_DUAL'. +Generating RTLIL representation for module `\CRC32'. +Generating RTLIL representation for module `\CRC64'. +Generating RTLIL representation for module `\GTHE1_QUAD'. +Generating RTLIL representation for module `\GTXE1'. +Generating RTLIL representation for module `\IBUFDS_GTXE1'. +Generating RTLIL representation for module `\IBUFDS_GTHE1'. +Generating RTLIL representation for module `\GTHE2_CHANNEL'. +Generating RTLIL representation for module `\GTHE2_COMMON'. +Generating RTLIL representation for module `\GTPE2_CHANNEL'. +Generating RTLIL representation for module `\GTPE2_COMMON'. +Generating RTLIL representation for module `\GTXE2_CHANNEL'. +Generating RTLIL representation for module `\GTXE2_COMMON'. +Generating RTLIL representation for module `\IBUFDS_GTE2'. +Generating RTLIL representation for module `\GTHE3_CHANNEL'. +Generating RTLIL representation for module `\GTHE3_COMMON'. +Generating RTLIL representation for module `\GTHE4_CHANNEL'. +Generating RTLIL representation for module `\GTHE4_COMMON'. +Generating RTLIL representation for module `\GTYE3_CHANNEL'. +Generating RTLIL representation for module `\GTYE3_COMMON'. +Generating RTLIL representation for module `\GTYE4_CHANNEL'. +Generating RTLIL representation for module `\GTYE4_COMMON'. +Generating RTLIL representation for module `\IBUFDS_GTE3'. +Generating RTLIL representation for module `\IBUFDS_GTE4'. +Generating RTLIL representation for module `\OBUFDS_GTE3'. +Generating RTLIL representation for module `\OBUFDS_GTE3_ADV'. +Generating RTLIL representation for module `\OBUFDS_GTE4'. +Generating RTLIL representation for module `\OBUFDS_GTE4_ADV'. +Generating RTLIL representation for module `\PCIE_A1'. +Generating RTLIL representation for module `\PCIE_EP'. +Generating RTLIL representation for module `\PCIE_2_0'. +Generating RTLIL representation for module `\PCIE_2_1'. +Generating RTLIL representation for module `\PCIE_3_0'. +Generating RTLIL representation for module `\PCIE_3_1'. +Generating RTLIL representation for module `\PCIE40E4'. +Generating RTLIL representation for module `\EMAC'. +Generating RTLIL representation for module `\TEMAC'. +Generating RTLIL representation for module `\TEMAC_SINGLE'. +Generating RTLIL representation for module `\CMAC'. +Generating RTLIL representation for module `\CMACE4'. +Generating RTLIL representation for module `\PPC405_ADV'. +Generating RTLIL representation for module `\PPC440'. +Generating RTLIL representation for module `\MCB'. +Generating RTLIL representation for module `\PS7'. +Generating RTLIL representation for module `\PS8'. +Generating RTLIL representation for module `\ILKN'. +Generating RTLIL representation for module `\ILKNE4'. +Successfully finished Verilog frontend. + +9.3. Executing HIERARCHY pass (managing design hierarchy). + +9.3.1. Analyzing design hierarchy.. +Top module: \block_ram + +9.3.2. Analyzing design hierarchy.. +Top module: \block_ram +Removing unused module `\distributed_ram'. +Removing unused module `\distributed_ram_manual'. +Removing unused module `\distributed_ram_manual_syn'. +Removed 3 unused modules. + +9.4. Executing PROC pass (convert processes to netlists). + +9.4.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Cleaned up 0 empty switches. + +9.4.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). +Removed a total of 0 dead cases. + +9.4.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). +Removed 0 redundant assignments. +Promoted 0 assignments to connections. + +9.4.4. Executing PROC_INIT pass (extract init attributes). + +9.4.5. Executing PROC_ARST pass (detect async resets in processes). + +9.4.6. Executing PROC_MUX pass (convert decision trees to multiplexers). + +9.4.7. Executing PROC_DLATCH pass (convert process syncs to latches). + +9.4.8. Executing PROC_DFF pass (convert process syncs to FFs). + +9.4.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). +Cleaned up 0 empty switches. + +9.5. Executing TRIBUF pass. + +9.6. Executing DEMINOUT pass (demote inout ports to input or output). + +9.7. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +9.8. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +9.9. Executing CHECK pass (checking for obvious problems). +checking module block_ram.. +found and reported 0 problems. + +9.10. Executing OPT pass (performing simple optimizations). + +9.10.1. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +9.10.2. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +9.10.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). +Running muxtree optimizer on module \block_ram.. + Creating internal representation of mux trees. + Evaluating internal representation of mux trees. + Analyzing evaluation results. +Removed 0 multiplexer ports. + + +9.10.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). + Optimizing cells in module \block_ram. +Performed a total of 0 changes. + +9.10.5. Executing OPT_MERGE pass (detect identical cells). +Finding identical cells in module `\block_ram'. +Removed a total of 0 cells. + +9.10.6. Executing OPT_RMDFF pass (remove dff with constant values). + +9.10.7. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. + +9.10.8. Executing OPT_EXPR pass (perform const folding). +Optimizing module block_ram. + +9.10.9. Finished OPT passes. (There is nothing left to do.) + +9.11. Executing WREDUCE pass (reducing word size of cells). +Removed cell block_ram.$procmux$469 ($mux). +Removed cell block_ram.$procmux$467 ($mux). + +9.12. Executing PEEPOPT pass (run peephole optimizers). + +9.13. Executing OPT_CLEAN pass (remove unused cells and wires). +Finding unused cells or wires in module \block_ram.. +Removed 0 unused cells and 2 unused wires. + + +9.14. Executing PMUX2SHIFTX pass. + +9.15. Executing TECHMAP pass (map to technology primitives). + +9.15.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v' to AST representation. +Generating RTLIL representation for module `\_90_lut_cmp_'. +Successfully finished Verilog frontend. + +9.15.2. Continuing TECHMAP pass. +No more expansions possible. + +9.16. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). + +9.17. Executing TECHMAP pass (map to technology primitives). + +9.17.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v' to AST representation. +Generating RTLIL representation for module `\_80_mul'. +Generating RTLIL representation for module `\_90_soft_mul'. +Successfully finished Verilog frontend. + +9.17.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v +Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v' to AST representation. +Generating RTLIL representation for module `\$__MUL25X18'. +Successfully finished Verilog frontend. + +9.17.3. Continuing TECHMAP pass. +No more expansions possible. + +9.18. Executing OPT_EXPR pass (perform const folding). + +9.19. Executing WREDUCE pass (reducing word size of cells). + +9.20. Executing XILINX_DSP pass (pack resources into DSPs). + +9.21. Executing ALUMACC pass (create $alu and $macc cells). +Extracting $alu and $macc cells in module block_ram: + created 0 $alu and 0 $macc cells. + +9.22. Executing SHARE pass (SAT-based resource sharing). From f3f59910eb06bf74a2a4b8157797a327dd097451 Mon Sep 17 00:00:00 2001 From: Diego H Date: Sun, 15 Dec 2019 23:51:58 -0600 Subject: [PATCH 3/4] Removing fixed attribute value to !ramstyle rules --- techlibs/xilinx/xc7_xcu_brams.txt | 8 +- tests/arch/common/memory_attributes/log | 3238 ----------------------- 2 files changed, 4 insertions(+), 3242 deletions(-) delete mode 100644 tests/arch/common/memory_attributes/log diff --git a/techlibs/xilinx/xc7_xcu_brams.txt b/techlibs/xilinx/xc7_xcu_brams.txt index 2d94ac4a8..1374a0a36 100644 --- a/techlibs/xilinx/xc7_xcu_brams.txt +++ b/techlibs/xilinx/xc7_xcu_brams.txt @@ -78,7 +78,7 @@ endbram match $__XILINX_RAMB36_SDP attribute ram_style=block ram_block=1 - attribute !ram_style=distributed + attribute !ram_style attribute !logic_block min bits 1024 min efficiency 5 @@ -89,7 +89,7 @@ endmatch match $__XILINX_RAMB18_SDP attribute ram_style=block ram_block=1 - attribute !ram_style=distributed + attribute !ram_style attribute !logic_block min bits 1024 min efficiency 5 @@ -100,7 +100,7 @@ endmatch match $__XILINX_RAMB36_TDP attribute ram_style=block ram_block=1 - attribute !ram_style=distributed + attribute !ram_style attribute !logic_block min bits 1024 min efficiency 5 @@ -111,7 +111,7 @@ endmatch match $__XILINX_RAMB18_TDP attribute ram_style=block ram_block=1 - attribute !ram_style=distributed + attribute !ram_style attribute !logic_block min bits 1024 min efficiency 5 diff --git a/tests/arch/common/memory_attributes/log b/tests/arch/common/memory_attributes/log deleted file mode 100644 index 5d526e661..000000000 --- a/tests/arch/common/memory_attributes/log +++ /dev/null @@ -1,3238 +0,0 @@ - - /----------------------------------------------------------------------------\ - | | - | yosys -- Yosys Open SYnthesis Suite | - | | - | Copyright (C) 2012 - 2019 Clifford Wolf | - | | - | Permission to use, copy, modify, and/or distribute this software for any | - | purpose with or without fee is hereby granted, provided that the above | - | copyright notice and this permission notice appear in all copies. | - | | - | THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES | - | WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF | - | MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR | - | ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES | - | WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN | - | ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF | - | OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. | - | | - \----------------------------------------------------------------------------/ - - Yosys 0.9+932 (git sha1 26699340, clang 6.0.0-1ubuntu2 -fPIC -Os) - - --- Executing script file `attributes_test.ys' -- - -1. Executing Verilog-2005 frontend: attributes_test.v -Parsing Verilog input from `attributes_test.v' to AST representation. -Generating RTLIL representation for module `\block_ram'. -Generating RTLIL representation for module `\distributed_ram'. -Generating RTLIL representation for module `\distributed_ram_manual'. -Generating RTLIL representation for module `\distributed_ram_manual_syn'. -Successfully finished Verilog frontend. - -2. Executing HIERARCHY pass (managing design hierarchy). - -2.1. Analyzing design hierarchy.. -Top module: \block_ram - -2.2. Analyzing design hierarchy.. -Top module: \block_ram -Removing unused module `\distributed_ram_manual_syn'. -Removing unused module `\distributed_ram_manual'. -Removing unused module `\distributed_ram'. -Removed 3 unused modules. - -3. Executing SYNTH_XILINX pass. - -3.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v' to AST representation. -Generating RTLIL representation for module `\VCC'. -Generating RTLIL representation for module `\GND'. -Generating RTLIL representation for module `\IBUF'. -Generating RTLIL representation for module `\IBUFG'. -Generating RTLIL representation for module `\OBUF'. -Generating RTLIL representation for module `\IOBUF'. -Generating RTLIL representation for module `\OBUFT'. -Generating RTLIL representation for module `\BUFG'. -Generating RTLIL representation for module `\BUFGCTRL'. -Generating RTLIL representation for module `\BUFHCE'. -Generating RTLIL representation for module `\INV'. -Generating RTLIL representation for module `\LUT1'. -Generating RTLIL representation for module `\LUT2'. -Generating RTLIL representation for module `\LUT3'. -Generating RTLIL representation for module `\LUT4'. -Generating RTLIL representation for module `\LUT5'. -Generating RTLIL representation for module `\LUT6'. -Generating RTLIL representation for module `\LUT6_2'. -Generating RTLIL representation for module `\MUXCY'. -Generating RTLIL representation for module `\MUXF7'. -Generating RTLIL representation for module `\MUXF8'. -Generating RTLIL representation for module `\XORCY'. -Generating RTLIL representation for module `\CARRY4'. -Generating RTLIL representation for module `\FDRE'. -Generating RTLIL representation for module `\FDSE'. -Generating RTLIL representation for module `\FDCE'. -Generating RTLIL representation for module `\FDPE'. -Generating RTLIL representation for module `\FDRE_1'. -Generating RTLIL representation for module `\FDSE_1'. -Generating RTLIL representation for module `\FDCE_1'. -Generating RTLIL representation for module `\FDPE_1'. -Generating RTLIL representation for module `\LDCE'. -Generating RTLIL representation for module `\LDPE'. -Generating RTLIL representation for module `\RAM16X1S'. -Generating RTLIL representation for module `\RAM16X1S_1'. -Generating RTLIL representation for module `\RAM32X1S'. -Generating RTLIL representation for module `\RAM32X1S_1'. -Generating RTLIL representation for module `\RAM64X1S'. -Generating RTLIL representation for module `\RAM64X1S_1'. -Generating RTLIL representation for module `\RAM128X1S'. -Generating RTLIL representation for module `\RAM128X1S_1'. -Generating RTLIL representation for module `\RAM256X1S'. -Generating RTLIL representation for module `\RAM512X1S'. -Generating RTLIL representation for module `\RAM16X2S'. -Generating RTLIL representation for module `\RAM32X2S'. -Generating RTLIL representation for module `\RAM64X2S'. -Generating RTLIL representation for module `\RAM16X4S'. -Generating RTLIL representation for module `\RAM32X4S'. -Generating RTLIL representation for module `\RAM16X8S'. -Generating RTLIL representation for module `\RAM32X8S'. -Generating RTLIL representation for module `\RAM16X1D'. -Generating RTLIL representation for module `\RAM16X1D_1'. -Generating RTLIL representation for module `\RAM32X1D'. -Generating RTLIL representation for module `\RAM32X1D_1'. -Generating RTLIL representation for module `\RAM64X1D'. -Generating RTLIL representation for module `\RAM64X1D_1'. -Generating RTLIL representation for module `\RAM128X1D'. -Generating RTLIL representation for module `\RAM256X1D'. -Generating RTLIL representation for module `\RAM32M'. -Generating RTLIL representation for module `\RAM32M16'. -Generating RTLIL representation for module `\RAM64M'. -Generating RTLIL representation for module `\RAM64M8'. -Generating RTLIL representation for module `\ROM16X1'. -Generating RTLIL representation for module `\ROM32X1'. -Generating RTLIL representation for module `\ROM64X1'. -Generating RTLIL representation for module `\ROM128X1'. -Generating RTLIL representation for module `\ROM256X1'. -Generating RTLIL representation for module `\SRL16E'. -Generating RTLIL representation for module `\SRLC16E'. -Generating RTLIL representation for module `\SRLC32E'. -Generating RTLIL representation for module `\MULT18X18'. -Generating RTLIL representation for module `\MULT18X18S'. -Generating RTLIL representation for module `\MULT18X18SIO'. -Generating RTLIL representation for module `\DSP48A'. -Generating RTLIL representation for module `\DSP48A1'. -Generating RTLIL representation for module `\DSP48E1'. -Successfully finished Verilog frontend. - -3.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v' to AST representation. -Generating RTLIL representation for module `\FDCPE'. -Generating RTLIL representation for module `\FDRSE'. -Generating RTLIL representation for module `\LDCPE'. -Generating RTLIL representation for module `\AND2B1L'. -Generating RTLIL representation for module `\OR2L'. -Generating RTLIL representation for module `\MUXF5'. -Generating RTLIL representation for module `\MUXF6'. -Generating RTLIL representation for module `\MUXF9'. -Generating RTLIL representation for module `\CARRY8'. -Generating RTLIL representation for module `\ORCY'. -Generating RTLIL representation for module `\MULT_AND'. -Generating RTLIL representation for module `\SRL16'. -Generating RTLIL representation for module `\SRLC16'. -Generating RTLIL representation for module `\CFGLUT5'. -Generating RTLIL representation for module `\RAMB16_S1'. -Generating RTLIL representation for module `\RAMB16_S2'. -Generating RTLIL representation for module `\RAMB16_S4'. -Generating RTLIL representation for module `\RAMB16_S9'. -Generating RTLIL representation for module `\RAMB16_S18'. -Generating RTLIL representation for module `\RAMB16_S36'. -Generating RTLIL representation for module `\RAMB16_S1_S1'. -Generating RTLIL representation for module `\RAMB16_S1_S2'. -Generating RTLIL representation for module `\RAMB16_S1_S4'. -Generating RTLIL representation for module `\RAMB16_S1_S9'. -Generating RTLIL representation for module `\RAMB16_S1_S18'. -Generating RTLIL representation for module `\RAMB16_S1_S36'. -Generating RTLIL representation for module `\RAMB16_S2_S2'. -Generating RTLIL representation for module `\RAMB16_S2_S4'. -Generating RTLIL representation for module `\RAMB16_S2_S9'. -Generating RTLIL representation for module `\RAMB16_S2_S18'. -Generating RTLIL representation for module `\RAMB16_S2_S36'. -Generating RTLIL representation for module `\RAMB16_S4_S4'. -Generating RTLIL representation for module `\RAMB16_S4_S9'. -Generating RTLIL representation for module `\RAMB16_S4_S18'. -Generating RTLIL representation for module `\RAMB16_S4_S36'. -Generating RTLIL representation for module `\RAMB16_S9_S9'. -Generating RTLIL representation for module `\RAMB16_S9_S18'. -Generating RTLIL representation for module `\RAMB16_S9_S36'. -Generating RTLIL representation for module `\RAMB16_S18_S18'. -Generating RTLIL representation for module `\RAMB16_S18_S36'. -Generating RTLIL representation for module `\RAMB16_S36_S36'. -Generating RTLIL representation for module `\RAMB16BWE_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36'. -Generating RTLIL representation for module `\RAMB16BWE_S18_S9'. -Generating RTLIL representation for module `\RAMB16BWE_S18_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S9'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S36'. -Generating RTLIL representation for module `\RAMB16BWER'. -Generating RTLIL representation for module `\RAMB8BWER'. -Generating RTLIL representation for module `\FIFO16'. -Generating RTLIL representation for module `\RAMB16'. -Generating RTLIL representation for module `\RAMB32_S64_ECC'. -Generating RTLIL representation for module `\FIFO18'. -Generating RTLIL representation for module `\FIFO18_36'. -Generating RTLIL representation for module `\FIFO36'. -Generating RTLIL representation for module `\FIFO36_72'. -Generating RTLIL representation for module `\RAMB18'. -Generating RTLIL representation for module `\RAMB36'. -Generating RTLIL representation for module `\RAMB18SDP'. -Generating RTLIL representation for module `\RAMB36SDP'. -Generating RTLIL representation for module `\FIFO18E1'. -Generating RTLIL representation for module `\FIFO36E1'. -Generating RTLIL representation for module `\RAMB18E1'. -Generating RTLIL representation for module `\RAMB36E1'. -Generating RTLIL representation for module `\FIFO18E2'. -Generating RTLIL representation for module `\FIFO36E2'. -Generating RTLIL representation for module `\RAMB18E2'. -Generating RTLIL representation for module `\RAMB36E2'. -Generating RTLIL representation for module `\URAM288'. -Generating RTLIL representation for module `\URAM288_BASE'. -Generating RTLIL representation for module `\DSP48'. -Generating RTLIL representation for module `\DSP48E'. -Generating RTLIL representation for module `\DSP48E2'. -Generating RTLIL representation for module `\IFDDRCPE'. -Generating RTLIL representation for module `\IFDDRRSE'. -Generating RTLIL representation for module `\OFDDRCPE'. -Generating RTLIL representation for module `\OFDDRRSE'. -Generating RTLIL representation for module `\OFDDRTCPE'. -Generating RTLIL representation for module `\OFDDRTRSE'. -Generating RTLIL representation for module `\IDDR2'. -Generating RTLIL representation for module `\ODDR2'. -Generating RTLIL representation for module `\IDDR'. -Generating RTLIL representation for module `\IDDR_2CLK'. -Generating RTLIL representation for module `\ODDR'. -Generating RTLIL representation for module `\IDELAYCTRL'. -Generating RTLIL representation for module `\IDELAY'. -Generating RTLIL representation for module `\ISERDES'. -Generating RTLIL representation for module `\OSERDES'. -Generating RTLIL representation for module `\IODELAY'. -Generating RTLIL representation for module `\ISERDES_NODELAY'. -Generating RTLIL representation for module `\IODELAYE1'. -Generating RTLIL representation for module `\ISERDESE1'. -Generating RTLIL representation for module `\OSERDESE1'. -Generating RTLIL representation for module `\IDELAYE2'. -Generating RTLIL representation for module `\ODELAYE2'. -Generating RTLIL representation for module `\ISERDESE2'. -Generating RTLIL representation for module `\OSERDESE2'. -Generating RTLIL representation for module `\PHASER_IN'. -Generating RTLIL representation for module `\PHASER_IN_PHY'. -Generating RTLIL representation for module `\PHASER_OUT'. -Generating RTLIL representation for module `\PHASER_OUT_PHY'. -Generating RTLIL representation for module `\PHASER_REF'. -Generating RTLIL representation for module `\PHY_CONTROL'. -Generating RTLIL representation for module `\IDDRE1'. -Generating RTLIL representation for module `\ODDRE1'. -Generating RTLIL representation for module `\IDELAYE3'. -Generating RTLIL representation for module `\ODELAYE3'. -Generating RTLIL representation for module `\ISERDESE3'. -Generating RTLIL representation for module `\OSERDESE3'. -Generating RTLIL representation for module `\BITSLICE_CONTROL'. -Generating RTLIL representation for module `\RIU_OR'. -Generating RTLIL representation for module `\RX_BITSLICE'. -Generating RTLIL representation for module `\RXTX_BITSLICE'. -Generating RTLIL representation for module `\TX_BITSLICE'. -Generating RTLIL representation for module `\TX_BITSLICE_TRI'. -Generating RTLIL representation for module `\IODELAY2'. -Generating RTLIL representation for module `\IODRP2'. -Generating RTLIL representation for module `\IODRP2_MCB'. -Generating RTLIL representation for module `\ISERDES2'. -Generating RTLIL representation for module `\OSERDES2'. -Generating RTLIL representation for module `\IBUF_DLY_ADJ'. -Generating RTLIL representation for module `\IBUF_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUF_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUF_ANALOG'. -Generating RTLIL representation for module `\IBUFE3'. -Generating RTLIL representation for module `\IBUFDS'. -Generating RTLIL representation for module `\IBUFDS_DLY_ADJ'. -Generating RTLIL representation for module `\IBUFDS_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUFDS_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUFDSE3'. -Generating RTLIL representation for module `\IBUFDS_DPHY'. -Generating RTLIL representation for module `\IBUFGDS'. -Generating RTLIL representation for module `\IBUFGDS_DIFF_OUT'. -Generating RTLIL representation for module `\IOBUF_DCIEN'. -Generating RTLIL representation for module `\IOBUF_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFE3'. -Generating RTLIL representation for module `\IOBUFDS'. -Generating RTLIL representation for module `\IOBUFDS_DCIEN'. -Generating RTLIL representation for module `\IOBUFDS_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_DCIEN'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFDSE3'. -Generating RTLIL representation for module `\OBUFDS'. -Generating RTLIL representation for module `\OBUFDS_DPHY'. -Generating RTLIL representation for module `\OBUFTDS'. -Generating RTLIL representation for module `\KEEPER'. -Generating RTLIL representation for module `\PULLDOWN'. -Generating RTLIL representation for module `\PULLUP'. -Generating RTLIL representation for module `\DCIRESET'. -Generating RTLIL representation for module `\HPIO_VREF'. -Generating RTLIL representation for module `\BUFGCE'. -Generating RTLIL representation for module `\BUFGCE_1'. -Generating RTLIL representation for module `\BUFGMUX'. -Generating RTLIL representation for module `\BUFGMUX_1'. -Generating RTLIL representation for module `\BUFGMUX_CTRL'. -Generating RTLIL representation for module `\BUFGMUX_VIRTEX4'. -Generating RTLIL representation for module `\BUFG_GT'. -Generating RTLIL representation for module `\BUFG_GT_SYNC'. -Generating RTLIL representation for module `\BUFG_PS'. -Generating RTLIL representation for module `\BUFGCE_DIV'. -Generating RTLIL representation for module `\BUFH'. -Generating RTLIL representation for module `\BUFIO2'. -Generating RTLIL representation for module `\BUFIO2_2CLK'. -Generating RTLIL representation for module `\BUFIO2FB'. -Generating RTLIL representation for module `\BUFPLL'. -Generating RTLIL representation for module `\BUFPLL_MCB'. -Generating RTLIL representation for module `\BUFIO'. -Generating RTLIL representation for module `\BUFIODQS'. -Generating RTLIL representation for module `\BUFR'. -Generating RTLIL representation for module `\BUFMR'. -Generating RTLIL representation for module `\BUFMRCE'. -Generating RTLIL representation for module `\DCM'. -Generating RTLIL representation for module `\DCM_SP'. -Generating RTLIL representation for module `\DCM_CLKGEN'. -Generating RTLIL representation for module `\DCM_ADV'. -Generating RTLIL representation for module `\DCM_BASE'. -Generating RTLIL representation for module `\DCM_PS'. -Generating RTLIL representation for module `\PMCD'. -Generating RTLIL representation for module `\PLL_ADV'. -Generating RTLIL representation for module `\PLL_BASE'. -Generating RTLIL representation for module `\MMCM_ADV'. -Generating RTLIL representation for module `\MMCM_BASE'. -Generating RTLIL representation for module `\MMCME2_ADV'. -Generating RTLIL representation for module `\MMCME2_BASE'. -Generating RTLIL representation for module `\PLLE2_ADV'. -Generating RTLIL representation for module `\PLLE2_BASE'. -Generating RTLIL representation for module `\MMCME3_ADV'. -Generating RTLIL representation for module `\MMCME3_BASE'. -Generating RTLIL representation for module `\PLLE3_ADV'. -Generating RTLIL representation for module `\PLLE3_BASE'. -Generating RTLIL representation for module `\MMCME4_ADV'. -Generating RTLIL representation for module `\MMCME4_BASE'. -Generating RTLIL representation for module `\PLLE4_ADV'. -Generating RTLIL representation for module `\PLLE4_BASE'. -Generating RTLIL representation for module `\BUFT'. -Generating RTLIL representation for module `\IN_FIFO'. -Generating RTLIL representation for module `\OUT_FIFO'. -Generating RTLIL representation for module `\HARD_SYNC'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3E'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3A'. -Generating RTLIL representation for module `\STARTUP_SPARTAN6'. -Generating RTLIL representation for module `\STARTUP_VIRTEX4'. -Generating RTLIL representation for module `\STARTUP_VIRTEX5'. -Generating RTLIL representation for module `\STARTUP_VIRTEX6'. -Generating RTLIL representation for module `\STARTUPE2'. -Generating RTLIL representation for module `\STARTUPE3'. -Generating RTLIL representation for module `\CAPTURE_SPARTAN3'. -Generating RTLIL representation for module `\CAPTURE_SPARTAN3A'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX4'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX5'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX6'. -Generating RTLIL representation for module `\CAPTUREE2'. -Generating RTLIL representation for module `\ICAP_SPARTAN3A'. -Generating RTLIL representation for module `\ICAP_SPARTAN6'. -Generating RTLIL representation for module `\ICAP_VIRTEX4'. -Generating RTLIL representation for module `\ICAP_VIRTEX5'. -Generating RTLIL representation for module `\ICAP_VIRTEX6'. -Generating RTLIL representation for module `\ICAPE2'. -Generating RTLIL representation for module `\ICAPE3'. -Generating RTLIL representation for module `\BSCAN_SPARTAN3'. -Generating RTLIL representation for module `\BSCAN_SPARTAN3A'. -Generating RTLIL representation for module `\BSCAN_SPARTAN6'. -Generating RTLIL representation for module `\BSCAN_VIRTEX4'. -Generating RTLIL representation for module `\BSCAN_VIRTEX5'. -Generating RTLIL representation for module `\BSCAN_VIRTEX6'. -Generating RTLIL representation for module `\BSCANE2'. -Generating RTLIL representation for module `\DNA_PORT'. -Generating RTLIL representation for module `\DNA_PORTE2'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX4'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX5'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX6'. -Generating RTLIL representation for module `\FRAME_ECCE2'. -Generating RTLIL representation for module `\FRAME_ECCE3'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX4'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX5'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX6'. -Generating RTLIL representation for module `\USR_ACCESSE2'. -Generating RTLIL representation for module `\POST_CRC_INTERNAL'. -Generating RTLIL representation for module `\SUSPEND_SYNC'. -Generating RTLIL representation for module `\KEY_CLEAR'. -Generating RTLIL representation for module `\MASTER_JTAG'. -Generating RTLIL representation for module `\SPI_ACCESS'. -Generating RTLIL representation for module `\EFUSE_USR'. -Generating RTLIL representation for module `\SYSMON'. -Generating RTLIL representation for module `\XADC'. -Generating RTLIL representation for module `\SYSMONE1'. -Generating RTLIL representation for module `\SYSMONE4'. -Generating RTLIL representation for module `\GTPA1_DUAL'. -Generating RTLIL representation for module `\GT11_CUSTOM'. -Generating RTLIL representation for module `\GT11_DUAL'. -Generating RTLIL representation for module `\GT11CLK'. -Generating RTLIL representation for module `\GT11CLK_MGT'. -Generating RTLIL representation for module `\GTP_DUAL'. -Generating RTLIL representation for module `\GTX_DUAL'. -Generating RTLIL representation for module `\CRC32'. -Generating RTLIL representation for module `\CRC64'. -Generating RTLIL representation for module `\GTHE1_QUAD'. -Generating RTLIL representation for module `\GTXE1'. -Generating RTLIL representation for module `\IBUFDS_GTXE1'. -Generating RTLIL representation for module `\IBUFDS_GTHE1'. -Generating RTLIL representation for module `\GTHE2_CHANNEL'. -Generating RTLIL representation for module `\GTHE2_COMMON'. -Generating RTLIL representation for module `\GTPE2_CHANNEL'. -Generating RTLIL representation for module `\GTPE2_COMMON'. -Generating RTLIL representation for module `\GTXE2_CHANNEL'. -Generating RTLIL representation for module `\GTXE2_COMMON'. -Generating RTLIL representation for module `\IBUFDS_GTE2'. -Generating RTLIL representation for module `\GTHE3_CHANNEL'. -Generating RTLIL representation for module `\GTHE3_COMMON'. -Generating RTLIL representation for module `\GTHE4_CHANNEL'. -Generating RTLIL representation for module `\GTHE4_COMMON'. -Generating RTLIL representation for module `\GTYE3_CHANNEL'. -Generating RTLIL representation for module `\GTYE3_COMMON'. -Generating RTLIL representation for module `\GTYE4_CHANNEL'. -Generating RTLIL representation for module `\GTYE4_COMMON'. -Generating RTLIL representation for module `\IBUFDS_GTE3'. -Generating RTLIL representation for module `\IBUFDS_GTE4'. -Generating RTLIL representation for module `\OBUFDS_GTE3'. -Generating RTLIL representation for module `\OBUFDS_GTE3_ADV'. -Generating RTLIL representation for module `\OBUFDS_GTE4'. -Generating RTLIL representation for module `\OBUFDS_GTE4_ADV'. -Generating RTLIL representation for module `\PCIE_A1'. -Generating RTLIL representation for module `\PCIE_EP'. -Generating RTLIL representation for module `\PCIE_2_0'. -Generating RTLIL representation for module `\PCIE_2_1'. -Generating RTLIL representation for module `\PCIE_3_0'. -Generating RTLIL representation for module `\PCIE_3_1'. -Generating RTLIL representation for module `\PCIE40E4'. -Generating RTLIL representation for module `\EMAC'. -Generating RTLIL representation for module `\TEMAC'. -Generating RTLIL representation for module `\TEMAC_SINGLE'. -Generating RTLIL representation for module `\CMAC'. -Generating RTLIL representation for module `\CMACE4'. -Generating RTLIL representation for module `\PPC405_ADV'. -Generating RTLIL representation for module `\PPC440'. -Generating RTLIL representation for module `\MCB'. -Generating RTLIL representation for module `\PS7'. -Generating RTLIL representation for module `\PS8'. -Generating RTLIL representation for module `\ILKN'. -Generating RTLIL representation for module `\ILKNE4'. -Successfully finished Verilog frontend. - -3.3. Executing HIERARCHY pass (managing design hierarchy). - -3.3.1. Analyzing design hierarchy.. -Top module: \block_ram - -3.3.2. Analyzing design hierarchy.. -Top module: \block_ram -Removed 0 unused modules. - -3.4. Executing PROC pass (convert processes to netlists). - -3.4.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Cleaned up 0 empty switches. - -3.4.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). -Removed a total of 0 dead cases. - -3.4.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). -Removed 0 redundant assignments. -Promoted 1 assignment to connection. - -3.4.4. Executing PROC_INIT pass (extract init attributes). - -3.4.5. Executing PROC_ARST pass (detect async resets in processes). - -3.4.6. Executing PROC_MUX pass (convert decision trees to multiplexers). -Creating decoders for process `\block_ram.$proc$attributes_test.v:14$2'. - 1/3: $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 - 2/3: $0$memwr$\memory$attributes_test.v:16$1_DATA[3:0]$4 - 3/3: $0$memwr$\memory$attributes_test.v:16$1_ADDR[9:0]$3 - -3.4.7. Executing PROC_DLATCH pass (convert process syncs to latches). - -3.4.8. Executing PROC_DFF pass (convert process syncs to FFs). -Creating register for signal `\block_ram.\data_out_r' using process `\block_ram.$proc$attributes_test.v:14$2'. - created $dff cell `$procdff$48' with positive edge clock. -Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$1_ADDR' using process `\block_ram.$proc$attributes_test.v:14$2'. - created $dff cell `$procdff$49' with positive edge clock. -Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$1_DATA' using process `\block_ram.$proc$attributes_test.v:14$2'. - created $dff cell `$procdff$50' with positive edge clock. -Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$1_EN' using process `\block_ram.$proc$attributes_test.v:14$2'. - created $dff cell `$procdff$51' with positive edge clock. - -3.4.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Found and cleaned up 1 empty switch in `\block_ram.$proc$attributes_test.v:14$2'. -Removing empty process `block_ram.$proc$attributes_test.v:14$2'. -Cleaned up 1 empty switch. - -3.5. Executing TRIBUF pass. - -3.6. Executing DEMINOUT pass (demote inout ports to input or output). - -3.7. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.8. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Removed 0 unused cells and 7 unused wires. - - -3.9. Executing CHECK pass (checking for obvious problems). -checking module block_ram.. -found and reported 0 problems. - -3.10. Executing OPT pass (performing simple optimizations). - -3.10.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.10.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.10.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -3.10.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. - Consolidated identical input bits for $mux cell $procmux$42: - Old ports: A=4'0000, B=4'1111, Y=$0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 - New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] - New connections: $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [3:1] = { $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] $0$memwr$\memory$attributes_test.v:16$1_EN[3:0]$5 [0] } - Optimizing cells in module \block_ram. -Performed a total of 1 changes. - -3.10.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.10.6. Executing OPT_RMDFF pass (remove dff with constant values). - -3.10.7. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.10.8. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.10.9. Rerunning OPT passes. (Maybe there is more to do..) - -3.10.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -3.10.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. -Performed a total of 0 changes. - -3.10.12. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.10.13. Executing OPT_RMDFF pass (remove dff with constant values). - -3.10.14. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.10.15. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.10.16. Finished OPT passes. (There is nothing left to do.) - -3.11. Executing WREDUCE pass (reducing word size of cells). -Removed cell block_ram.$procmux$44 ($mux). -Removed cell block_ram.$procmux$46 ($mux). -Removed top 3 bits (of 4) from FF cell block_ram.$procdff$51 ($dff). - -3.12. Executing PEEPOPT pass (run peephole optimizers). - -3.13. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Removed 0 unused cells and 2 unused wires. - - -3.14. Executing PMUX2SHIFTX pass. - -3.15. Executing TECHMAP pass (map to technology primitives). - -3.15.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v' to AST representation. -Generating RTLIL representation for module `\_90_lut_cmp_'. -Successfully finished Verilog frontend. - -3.15.2. Continuing TECHMAP pass. -No more expansions possible. - -3.16. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). -Checking cell `$memwr$\memory$attributes_test.v:16$7' in module `\block_ram': merged $dff to cell. -Checking cell `$memrd$\memory$attributes_test.v:17$6' in module `\block_ram': merged data $dff to cell. - -3.17. Executing TECHMAP pass (map to technology primitives). - -3.17.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v' to AST representation. -Generating RTLIL representation for module `\_80_mul'. -Generating RTLIL representation for module `\_90_soft_mul'. -Successfully finished Verilog frontend. - -3.17.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v' to AST representation. -Generating RTLIL representation for module `\$__MUL25X18'. -Successfully finished Verilog frontend. - -3.17.3. Continuing TECHMAP pass. -No more expansions possible. - -3.18. Executing OPT_EXPR pass (perform const folding). - -3.19. Executing WREDUCE pass (reducing word size of cells). - -3.20. Executing XILINX_DSP pass (pack resources into DSPs). - -3.21. Executing ALUMACC pass (create $alu and $macc cells). -Extracting $alu and $macc cells in module block_ram: - created 0 $alu and 0 $macc cells. - -3.22. Executing SHARE pass (SAT-based resource sharing). - -3.23. Executing OPT pass (performing simple optimizations). - -3.23.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.23.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.23.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -3.23.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. -Performed a total of 0 changes. - -3.23.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.23.6. Executing OPT_RMDFF pass (remove dff with constant values). - -3.23.7. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Removed 4 unused cells and 5 unused wires. - - -3.23.8. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.23.9. Rerunning OPT passes. (Maybe there is more to do..) - -3.23.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -3.23.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. -Performed a total of 0 changes. - -3.23.12. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.23.13. Executing OPT_RMDFF pass (remove dff with constant values). - -3.23.14. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.23.15. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.23.16. Finished OPT passes. (There is nothing left to do.) - -3.24. Executing FSM pass (extract and optimize FSM). - -3.24.1. Executing FSM_DETECT pass (finding FSMs in design). - -3.24.2. Executing FSM_EXTRACT pass (extracting FSM from design). - -3.24.3. Executing FSM_OPT pass (simple optimizations of FSMs). - -3.24.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.24.5. Executing FSM_OPT pass (simple optimizations of FSMs). - -3.24.6. Executing FSM_RECODE pass (re-assigning FSM state encoding). - -3.24.7. Executing FSM_INFO pass (dumping all available information on FSM cells). - -3.24.8. Executing FSM_MAP pass (mapping FSMs to basic logic). - -3.25. Executing OPT pass (performing simple optimizations). - -3.25.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.25.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.25.3. Executing OPT_RMDFF pass (remove dff with constant values). - -3.25.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.25.5. Finished fast OPT passes. - -3.26. Executing MEMORY pass. - -3.26.1. Executing OPT_MEM pass (optimize memories). -Performed a total of 0 transformations. - -3.26.2. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). - -3.26.3. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.26.4. Executing MEMORY_SHARE pass (consolidating $memrd/$memwr cells). - -3.26.5. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.26.6. Executing MEMORY_COLLECT pass (generating $mem cells). -Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\block_ram': - $memwr$\memory$attributes_test.v:16$7 ($memwr) - $memrd$\memory$attributes_test.v:17$6 ($memrd) - -3.27. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.28. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). -Processing block_ram.memory: - Properties: ports=2 bits=4096 rports=1 wports=1 dbits=4 abits=10 words=1024 - Checking rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1): - Bram geometry: abits=9 dbits=72 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_SDP: awaste=0 dwaste=68 bwaste=34816 waste=34816 efficiency=5 - Rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1) accepted. - Mapping to bram type $__XILINX_RAMB36_SDP (variant 1): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=34816 efficiency=5 - Storing for later selection. - Checking rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1): - Bram geometry: abits=9 dbits=36 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_SDP: awaste=0 dwaste=32 bwaste=16384 waste=16384 efficiency=11 - Rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1) accepted. - Mapping to bram type $__XILINX_RAMB18_SDP (variant 1): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=16384 efficiency=11 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1): - Bram geometry: abits=10 dbits=36 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=0 dwaste=32 bwaste=32768 waste=32768 efficiency=11 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1) accepted. - Mapping to bram type $__XILINX_RAMB36_TDP (variant 1): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=32768 efficiency=11 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2): - Bram geometry: abits=11 dbits=18 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=1024 dwaste=14 bwaste=32768 waste=32768 efficiency=11 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2) accepted. - Mapping to bram type $__XILINX_RAMB36_TDP (variant 2): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=32768 efficiency=11 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3): - Bram geometry: abits=12 dbits=9 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=3072 dwaste=5 bwaste=32768 waste=32768 efficiency=11 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3) accepted. - Mapping to bram type $__XILINX_RAMB36_TDP (variant 3): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=32768 efficiency=11 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4): - Bram geometry: abits=13 dbits=4 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=7168 dwaste=0 bwaste=28672 waste=28672 efficiency=12 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4) accepted. - Mapping to bram type $__XILINX_RAMB36_TDP (variant 4): - Shuffle bit order to accommodate enable buckets of size 4.. - Results of bit order shuffling: 0 1 2 3 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=28672 efficiency=12 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5): - Bram geometry: abits=14 dbits=2 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=15360 dwaste=0 bwaste=30720 waste=30720 efficiency=6 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5) accepted. - Mapping to bram type $__XILINX_RAMB36_TDP (variant 5): - Shuffle bit order to accommodate enable buckets of size 2.. - Results of bit order shuffling: 0 1 2 3 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=30720 efficiency=6 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6): - Bram geometry: abits=15 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=31744 dwaste=0 bwaste=31744 waste=31744 efficiency=3 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6) rejected: requirement 'min efficiency 5' not met. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1): - Bram geometry: abits=10 dbits=18 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=0 dwaste=14 bwaste=14336 waste=14336 efficiency=22 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1) accepted. - Mapping to bram type $__XILINX_RAMB18_TDP (variant 1): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=14336 efficiency=22 - Storing for later selection. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2): - Bram geometry: abits=11 dbits=9 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=1024 dwaste=5 bwaste=14336 waste=14336 efficiency=22 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2) accepted. - Mapping to bram type $__XILINX_RAMB18_TDP (variant 2): - Shuffle bit order to accommodate enable buckets of size 9.. - Results of bit order shuffling: 0 1 2 3 -1 -1 -1 -1 -1 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=14336 efficiency=22 - Storing for later selection. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3): - Bram geometry: abits=12 dbits=4 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=3072 dwaste=0 bwaste=12288 waste=12288 efficiency=25 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3) accepted. - Mapping to bram type $__XILINX_RAMB18_TDP (variant 3): - Shuffle bit order to accommodate enable buckets of size 4.. - Results of bit order shuffling: 0 1 2 3 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=12288 efficiency=25 - Storing for later selection. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4): - Bram geometry: abits=13 dbits=2 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=7168 dwaste=0 bwaste=14336 waste=14336 efficiency=12 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4) accepted. - Mapping to bram type $__XILINX_RAMB18_TDP (variant 4): - Shuffle bit order to accommodate enable buckets of size 2.. - Results of bit order shuffling: 0 1 2 3 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=14336 efficiency=12 - Storing for later selection. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5): - Bram geometry: abits=14 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=15360 dwaste=0 bwaste=15360 waste=15360 efficiency=6 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5) accepted. - Mapping to bram type $__XILINX_RAMB18_TDP (variant 5): - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=15360 efficiency=6 - Storing for later selection. - Selecting best of 12 rules: - Efficiency for rule 4.5: efficiency=6, cells=4, acells=1 - Efficiency for rule 4.4: efficiency=12, cells=2, acells=1 - Efficiency for rule 4.3: efficiency=25, cells=1, acells=1 - Efficiency for rule 4.2: efficiency=22, cells=1, acells=1 - Efficiency for rule 4.1: efficiency=22, cells=1, acells=1 - Efficiency for rule 3.5: efficiency=6, cells=2, acells=1 - Efficiency for rule 3.4: efficiency=12, cells=1, acells=1 - Efficiency for rule 3.3: efficiency=11, cells=1, acells=1 - Efficiency for rule 3.2: efficiency=11, cells=1, acells=1 - Efficiency for rule 3.1: efficiency=11, cells=1, acells=1 - Efficiency for rule 2.1: efficiency=11, cells=2, acells=2 - Efficiency for rule 1.1: efficiency=5, cells=2, acells=2 - Selected rule 4.3 with efficiency 25. - Mapping to bram type $__XILINX_RAMB18_TDP (variant 3): - Shuffle bit order to accommodate enable buckets of size 4.. - Results of bit order shuffling: 0 1 2 3 - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Creating $__XILINX_RAMB18_TDP cell at grid position <0 0 0>: memory.0.0.0 - -3.29. Executing TECHMAP pass (map to technology primitives). - -3.29.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v' to AST representation. -Generating RTLIL representation for module `\$__XILINX_RAMB36_SDP'. -Generating RTLIL representation for module `\$__XILINX_RAMB18_SDP'. -Generating RTLIL representation for module `\$__XILINX_RAMB36_TDP'. -Generating RTLIL representation for module `\$__XILINX_RAMB18_TDP'. -Successfully finished Verilog frontend. - -3.29.2. Continuing TECHMAP pass. -Using template $paramod\$__XILINX_RAMB18_TDP\CFG_ABITS=12\CFG_DBITS=4\CFG_ENABLE_B=1\CLKPOL2=1\CLKPOL3=1 for cells of type $__XILINX_RAMB18_TDP. -No more expansions possible. - - -3.30. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). - -3.31. Executing TECHMAP pass (map to technology primitives). - -3.31.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v' to AST representation. -Generating RTLIL representation for module `\$__XILINX_RAM32X1D'. -Generating RTLIL representation for module `\$__XILINX_RAM64X1D'. -Generating RTLIL representation for module `\$__XILINX_RAM128X1D'. -Successfully finished Verilog frontend. - -3.31.2. Continuing TECHMAP pass. -No more expansions possible. - -3.32. Executing OPT pass (performing simple optimizations). - -3.32.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - - -3.32.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.32.3. Executing OPT_RMDFF pass (remove dff with constant values). - -3.32.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Removed 0 unused cells and 17 unused wires. - - -3.32.5. Finished fast OPT passes. - -3.33. Executing MEMORY_MAP pass (converting $mem cells to logic and flip-flops). - -3.34. Executing DFFSR2DFF pass (mapping DFFSR cells to simpler FFs). - -3.35. Executing DFF2DFFE pass (transform $dff to $dffe where applicable). -Transforming FF to FF+Enable cells in module block_ram: - -3.36. Executing OPT pass (performing simple optimizations). - -3.36.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.36.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.36.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - No muxes found in this module. -Removed 0 multiplexer ports. - -3.36.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. -Performed a total of 0 changes. - -3.36.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.36.6. Executing OPT_SHARE pass. - -3.36.7. Executing OPT_RMDFF pass (remove dff with constant values). - -3.36.8. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.36.9. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.36.10. Finished OPT passes. (There is nothing left to do.) - -3.37. Executing XILINX_SRL pass (Xilinx shift register extraction). - -3.38. Executing TECHMAP pass (map to technology primitives). - -3.38.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. -Generating RTLIL representation for module `\_90_simplemap_bool_ops'. -Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. -Generating RTLIL representation for module `\_90_simplemap_logic_ops'. -Generating RTLIL representation for module `\_90_simplemap_compare_ops'. -Generating RTLIL representation for module `\_90_simplemap_various'. -Generating RTLIL representation for module `\_90_simplemap_registers'. -Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. -Generating RTLIL representation for module `\_90_shift_shiftx'. -Generating RTLIL representation for module `\_90_fa'. -Generating RTLIL representation for module `\_90_lcu'. -Generating RTLIL representation for module `\_90_alu'. -Generating RTLIL representation for module `\_90_macc'. -Generating RTLIL representation for module `\_90_alumacc'. -Generating RTLIL representation for module `\$__div_mod_u'. -Generating RTLIL representation for module `\$__div_mod'. -Generating RTLIL representation for module `\_90_div'. -Generating RTLIL representation for module `\_90_mod'. -Generating RTLIL representation for module `\_90_pow'. -Generating RTLIL representation for module `\_90_pmux'. -Generating RTLIL representation for module `\_90_lut'. -Successfully finished Verilog frontend. - -3.38.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v' to AST representation. -Generating RTLIL representation for module `\_80_xilinx_lcu'. -Generating RTLIL representation for module `\_80_xilinx_alu'. -Successfully finished Verilog frontend. - -3.38.3. Continuing TECHMAP pass. -No more expansions possible. - -3.39. Executing OPT pass (performing simple optimizations). - -3.39.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.39.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -3.39.3. Executing OPT_RMDFF pass (remove dff with constant values). - -3.39.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -3.39.5. Finished fast OPT passes. - -3.40. Executing TECHMAP pass (map to technology primitives). - -3.40.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. -Generating RTLIL representation for module `\_90_simplemap_bool_ops'. -Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. -Generating RTLIL representation for module `\_90_simplemap_logic_ops'. -Generating RTLIL representation for module `\_90_simplemap_compare_ops'. -Generating RTLIL representation for module `\_90_simplemap_various'. -Generating RTLIL representation for module `\_90_simplemap_registers'. -Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. -Generating RTLIL representation for module `\_90_shift_shiftx'. -Generating RTLIL representation for module `\_90_fa'. -Generating RTLIL representation for module `\_90_lcu'. -Generating RTLIL representation for module `\_90_alu'. -Generating RTLIL representation for module `\_90_macc'. -Generating RTLIL representation for module `\_90_alumacc'. -Generating RTLIL representation for module `\$__div_mod_u'. -Generating RTLIL representation for module `\$__div_mod'. -Generating RTLIL representation for module `\_90_div'. -Generating RTLIL representation for module `\_90_mod'. -Generating RTLIL representation for module `\_90_pow'. -Generating RTLIL representation for module `\_90_pmux'. -Generating RTLIL representation for module `\_90_lut'. -Successfully finished Verilog frontend. - -3.40.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. -Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. -Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. -Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. -Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. -Generating RTLIL representation for module `\$__SHREG_'. -Generating RTLIL representation for module `\$__XILINX_SHREG_'. -Generating RTLIL representation for module `\$__XILINX_MUXF78'. -Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. -Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. -Successfully finished Verilog frontend. - -3.40.3. Continuing TECHMAP pass. -No more expansions possible. - -3.41. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -3.42. Executing ABC pass (technology mapping using ABC). - -3.42.1. Extracting gate netlist of module `\block_ram' to `/input.blif'.. -Extracted 0 gates and 0 wires to a netlist network with 0 inputs and 0 outputs. -Don't call ABC as there is nothing to map. -Removing temp directory. - -3.43. Executing XILINX_SRL pass (Xilinx shift register extraction). - -3.44. Executing TECHMAP pass (map to technology primitives). - -3.44.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v' to AST representation. -Generating RTLIL representation for module `\$lut'. -Successfully finished Verilog frontend. - -3.44.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. -Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. -Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. -Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. -Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. -Generating RTLIL representation for module `\$__SHREG_'. -Generating RTLIL representation for module `\$__XILINX_SHREG_'. -Generating RTLIL representation for module `\$__XILINX_MUXF78'. -Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. -Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. -Successfully finished Verilog frontend. - -3.44.3. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v' to AST representation. -Generating RTLIL representation for module `\$_DFF_N_'. -Generating RTLIL representation for module `\$_DFF_P_'. -Generating RTLIL representation for module `\$_DFFE_NP_'. -Generating RTLIL representation for module `\$_DFFE_PP_'. -Generating RTLIL representation for module `\$_DFF_NN0_'. -Generating RTLIL representation for module `\$_DFF_NP0_'. -Generating RTLIL representation for module `\$_DFF_PN0_'. -Generating RTLIL representation for module `\$_DFF_PP0_'. -Generating RTLIL representation for module `\$_DFF_NN1_'. -Generating RTLIL representation for module `\$_DFF_NP1_'. -Generating RTLIL representation for module `\$_DFF_PN1_'. -Generating RTLIL representation for module `\$_DFF_PP1_'. -Generating RTLIL representation for module `\$_DLATCH_N_'. -Generating RTLIL representation for module `\$_DLATCH_P_'. -Successfully finished Verilog frontend. - -3.44.4. Continuing TECHMAP pass. -No more expansions possible. - -3.45. Executing CLKBUFMAP pass (inserting global clock buffers). -Inserting BUFG on block_ram.clk[0]. - -3.46. Executing HIERARCHY pass (managing design hierarchy). - -3.46.1. Analyzing design hierarchy.. -Top module: \block_ram - -3.46.2. Analyzing design hierarchy.. -Top module: \block_ram -Removed 0 unused modules. - -3.47. Printing statistics. - -=== block_ram === - - Number of wires: 12 - Number of wire bits: 62 - Number of public wires: 6 - Number of public wire bits: 24 - Number of memories: 0 - Number of memory bits: 0 - Number of processes: 0 - Number of cells: 2 - BUFG 1 - RAMB18E1 1 - - Estimated number of LCs: 0 - -3.48. Executing CHECK pass (checking for obvious problems). -checking module block_ram.. -found and reported 0 problems. - -4. Executing Verilog-2005 frontend: attributes_test.v -Parsing Verilog input from `attributes_test.v' to AST representation. -Generating RTLIL representation for module `\block_ram'. -Generating RTLIL representation for module `\distributed_ram'. -Generating RTLIL representation for module `\distributed_ram_manual'. -Generating RTLIL representation for module `\distributed_ram_manual_syn'. -Successfully finished Verilog frontend. - -5. Executing HIERARCHY pass (managing design hierarchy). - -5.1. Analyzing design hierarchy.. -Top module: \distributed_ram - -5.2. Analyzing design hierarchy.. -Top module: \distributed_ram -Removing unused module `\distributed_ram_manual_syn'. -Removing unused module `\distributed_ram_manual'. -Removing unused module `\block_ram'. -Removed 3 unused modules. - -6. Executing SYNTH_XILINX pass. - -6.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v' to AST representation. -Generating RTLIL representation for module `\VCC'. -Generating RTLIL representation for module `\GND'. -Generating RTLIL representation for module `\IBUF'. -Generating RTLIL representation for module `\IBUFG'. -Generating RTLIL representation for module `\OBUF'. -Generating RTLIL representation for module `\IOBUF'. -Generating RTLIL representation for module `\OBUFT'. -Generating RTLIL representation for module `\BUFG'. -Generating RTLIL representation for module `\BUFGCTRL'. -Generating RTLIL representation for module `\BUFHCE'. -Generating RTLIL representation for module `\INV'. -Generating RTLIL representation for module `\LUT1'. -Generating RTLIL representation for module `\LUT2'. -Generating RTLIL representation for module `\LUT3'. -Generating RTLIL representation for module `\LUT4'. -Generating RTLIL representation for module `\LUT5'. -Generating RTLIL representation for module `\LUT6'. -Generating RTLIL representation for module `\LUT6_2'. -Generating RTLIL representation for module `\MUXCY'. -Generating RTLIL representation for module `\MUXF7'. -Generating RTLIL representation for module `\MUXF8'. -Generating RTLIL representation for module `\XORCY'. -Generating RTLIL representation for module `\CARRY4'. -Generating RTLIL representation for module `\FDRE'. -Generating RTLIL representation for module `\FDSE'. -Generating RTLIL representation for module `\FDCE'. -Generating RTLIL representation for module `\FDPE'. -Generating RTLIL representation for module `\FDRE_1'. -Generating RTLIL representation for module `\FDSE_1'. -Generating RTLIL representation for module `\FDCE_1'. -Generating RTLIL representation for module `\FDPE_1'. -Generating RTLIL representation for module `\LDCE'. -Generating RTLIL representation for module `\LDPE'. -Generating RTLIL representation for module `\RAM16X1S'. -Generating RTLIL representation for module `\RAM16X1S_1'. -Generating RTLIL representation for module `\RAM32X1S'. -Generating RTLIL representation for module `\RAM32X1S_1'. -Generating RTLIL representation for module `\RAM64X1S'. -Generating RTLIL representation for module `\RAM64X1S_1'. -Generating RTLIL representation for module `\RAM128X1S'. -Generating RTLIL representation for module `\RAM128X1S_1'. -Generating RTLIL representation for module `\RAM256X1S'. -Generating RTLIL representation for module `\RAM512X1S'. -Generating RTLIL representation for module `\RAM16X2S'. -Generating RTLIL representation for module `\RAM32X2S'. -Generating RTLIL representation for module `\RAM64X2S'. -Generating RTLIL representation for module `\RAM16X4S'. -Generating RTLIL representation for module `\RAM32X4S'. -Generating RTLIL representation for module `\RAM16X8S'. -Generating RTLIL representation for module `\RAM32X8S'. -Generating RTLIL representation for module `\RAM16X1D'. -Generating RTLIL representation for module `\RAM16X1D_1'. -Generating RTLIL representation for module `\RAM32X1D'. -Generating RTLIL representation for module `\RAM32X1D_1'. -Generating RTLIL representation for module `\RAM64X1D'. -Generating RTLIL representation for module `\RAM64X1D_1'. -Generating RTLIL representation for module `\RAM128X1D'. -Generating RTLIL representation for module `\RAM256X1D'. -Generating RTLIL representation for module `\RAM32M'. -Generating RTLIL representation for module `\RAM32M16'. -Generating RTLIL representation for module `\RAM64M'. -Generating RTLIL representation for module `\RAM64M8'. -Generating RTLIL representation for module `\ROM16X1'. -Generating RTLIL representation for module `\ROM32X1'. -Generating RTLIL representation for module `\ROM64X1'. -Generating RTLIL representation for module `\ROM128X1'. -Generating RTLIL representation for module `\ROM256X1'. -Generating RTLIL representation for module `\SRL16E'. -Generating RTLIL representation for module `\SRLC16E'. -Generating RTLIL representation for module `\SRLC32E'. -Generating RTLIL representation for module `\MULT18X18'. -Generating RTLIL representation for module `\MULT18X18S'. -Generating RTLIL representation for module `\MULT18X18SIO'. -Generating RTLIL representation for module `\DSP48A'. -Generating RTLIL representation for module `\DSP48A1'. -Generating RTLIL representation for module `\DSP48E1'. -Successfully finished Verilog frontend. - -6.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v' to AST representation. -Generating RTLIL representation for module `\FDCPE'. -Generating RTLIL representation for module `\FDRSE'. -Generating RTLIL representation for module `\LDCPE'. -Generating RTLIL representation for module `\AND2B1L'. -Generating RTLIL representation for module `\OR2L'. -Generating RTLIL representation for module `\MUXF5'. -Generating RTLIL representation for module `\MUXF6'. -Generating RTLIL representation for module `\MUXF9'. -Generating RTLIL representation for module `\CARRY8'. -Generating RTLIL representation for module `\ORCY'. -Generating RTLIL representation for module `\MULT_AND'. -Generating RTLIL representation for module `\SRL16'. -Generating RTLIL representation for module `\SRLC16'. -Generating RTLIL representation for module `\CFGLUT5'. -Generating RTLIL representation for module `\RAMB16_S1'. -Generating RTLIL representation for module `\RAMB16_S2'. -Generating RTLIL representation for module `\RAMB16_S4'. -Generating RTLIL representation for module `\RAMB16_S9'. -Generating RTLIL representation for module `\RAMB16_S18'. -Generating RTLIL representation for module `\RAMB16_S36'. -Generating RTLIL representation for module `\RAMB16_S1_S1'. -Generating RTLIL representation for module `\RAMB16_S1_S2'. -Generating RTLIL representation for module `\RAMB16_S1_S4'. -Generating RTLIL representation for module `\RAMB16_S1_S9'. -Generating RTLIL representation for module `\RAMB16_S1_S18'. -Generating RTLIL representation for module `\RAMB16_S1_S36'. -Generating RTLIL representation for module `\RAMB16_S2_S2'. -Generating RTLIL representation for module `\RAMB16_S2_S4'. -Generating RTLIL representation for module `\RAMB16_S2_S9'. -Generating RTLIL representation for module `\RAMB16_S2_S18'. -Generating RTLIL representation for module `\RAMB16_S2_S36'. -Generating RTLIL representation for module `\RAMB16_S4_S4'. -Generating RTLIL representation for module `\RAMB16_S4_S9'. -Generating RTLIL representation for module `\RAMB16_S4_S18'. -Generating RTLIL representation for module `\RAMB16_S4_S36'. -Generating RTLIL representation for module `\RAMB16_S9_S9'. -Generating RTLIL representation for module `\RAMB16_S9_S18'. -Generating RTLIL representation for module `\RAMB16_S9_S36'. -Generating RTLIL representation for module `\RAMB16_S18_S18'. -Generating RTLIL representation for module `\RAMB16_S18_S36'. -Generating RTLIL representation for module `\RAMB16_S36_S36'. -Generating RTLIL representation for module `\RAMB16BWE_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36'. -Generating RTLIL representation for module `\RAMB16BWE_S18_S9'. -Generating RTLIL representation for module `\RAMB16BWE_S18_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S9'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S36'. -Generating RTLIL representation for module `\RAMB16BWER'. -Generating RTLIL representation for module `\RAMB8BWER'. -Generating RTLIL representation for module `\FIFO16'. -Generating RTLIL representation for module `\RAMB16'. -Generating RTLIL representation for module `\RAMB32_S64_ECC'. -Generating RTLIL representation for module `\FIFO18'. -Generating RTLIL representation for module `\FIFO18_36'. -Generating RTLIL representation for module `\FIFO36'. -Generating RTLIL representation for module `\FIFO36_72'. -Generating RTLIL representation for module `\RAMB18'. -Generating RTLIL representation for module `\RAMB36'. -Generating RTLIL representation for module `\RAMB18SDP'. -Generating RTLIL representation for module `\RAMB36SDP'. -Generating RTLIL representation for module `\FIFO18E1'. -Generating RTLIL representation for module `\FIFO36E1'. -Generating RTLIL representation for module `\RAMB18E1'. -Generating RTLIL representation for module `\RAMB36E1'. -Generating RTLIL representation for module `\FIFO18E2'. -Generating RTLIL representation for module `\FIFO36E2'. -Generating RTLIL representation for module `\RAMB18E2'. -Generating RTLIL representation for module `\RAMB36E2'. -Generating RTLIL representation for module `\URAM288'. -Generating RTLIL representation for module `\URAM288_BASE'. -Generating RTLIL representation for module `\DSP48'. -Generating RTLIL representation for module `\DSP48E'. -Generating RTLIL representation for module `\DSP48E2'. -Generating RTLIL representation for module `\IFDDRCPE'. -Generating RTLIL representation for module `\IFDDRRSE'. -Generating RTLIL representation for module `\OFDDRCPE'. -Generating RTLIL representation for module `\OFDDRRSE'. -Generating RTLIL representation for module `\OFDDRTCPE'. -Generating RTLIL representation for module `\OFDDRTRSE'. -Generating RTLIL representation for module `\IDDR2'. -Generating RTLIL representation for module `\ODDR2'. -Generating RTLIL representation for module `\IDDR'. -Generating RTLIL representation for module `\IDDR_2CLK'. -Generating RTLIL representation for module `\ODDR'. -Generating RTLIL representation for module `\IDELAYCTRL'. -Generating RTLIL representation for module `\IDELAY'. -Generating RTLIL representation for module `\ISERDES'. -Generating RTLIL representation for module `\OSERDES'. -Generating RTLIL representation for module `\IODELAY'. -Generating RTLIL representation for module `\ISERDES_NODELAY'. -Generating RTLIL representation for module `\IODELAYE1'. -Generating RTLIL representation for module `\ISERDESE1'. -Generating RTLIL representation for module `\OSERDESE1'. -Generating RTLIL representation for module `\IDELAYE2'. -Generating RTLIL representation for module `\ODELAYE2'. -Generating RTLIL representation for module `\ISERDESE2'. -Generating RTLIL representation for module `\OSERDESE2'. -Generating RTLIL representation for module `\PHASER_IN'. -Generating RTLIL representation for module `\PHASER_IN_PHY'. -Generating RTLIL representation for module `\PHASER_OUT'. -Generating RTLIL representation for module `\PHASER_OUT_PHY'. -Generating RTLIL representation for module `\PHASER_REF'. -Generating RTLIL representation for module `\PHY_CONTROL'. -Generating RTLIL representation for module `\IDDRE1'. -Generating RTLIL representation for module `\ODDRE1'. -Generating RTLIL representation for module `\IDELAYE3'. -Generating RTLIL representation for module `\ODELAYE3'. -Generating RTLIL representation for module `\ISERDESE3'. -Generating RTLIL representation for module `\OSERDESE3'. -Generating RTLIL representation for module `\BITSLICE_CONTROL'. -Generating RTLIL representation for module `\RIU_OR'. -Generating RTLIL representation for module `\RX_BITSLICE'. -Generating RTLIL representation for module `\RXTX_BITSLICE'. -Generating RTLIL representation for module `\TX_BITSLICE'. -Generating RTLIL representation for module `\TX_BITSLICE_TRI'. -Generating RTLIL representation for module `\IODELAY2'. -Generating RTLIL representation for module `\IODRP2'. -Generating RTLIL representation for module `\IODRP2_MCB'. -Generating RTLIL representation for module `\ISERDES2'. -Generating RTLIL representation for module `\OSERDES2'. -Generating RTLIL representation for module `\IBUF_DLY_ADJ'. -Generating RTLIL representation for module `\IBUF_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUF_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUF_ANALOG'. -Generating RTLIL representation for module `\IBUFE3'. -Generating RTLIL representation for module `\IBUFDS'. -Generating RTLIL representation for module `\IBUFDS_DLY_ADJ'. -Generating RTLIL representation for module `\IBUFDS_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUFDS_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUFDSE3'. -Generating RTLIL representation for module `\IBUFDS_DPHY'. -Generating RTLIL representation for module `\IBUFGDS'. -Generating RTLIL representation for module `\IBUFGDS_DIFF_OUT'. -Generating RTLIL representation for module `\IOBUF_DCIEN'. -Generating RTLIL representation for module `\IOBUF_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFE3'. -Generating RTLIL representation for module `\IOBUFDS'. -Generating RTLIL representation for module `\IOBUFDS_DCIEN'. -Generating RTLIL representation for module `\IOBUFDS_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_DCIEN'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFDSE3'. -Generating RTLIL representation for module `\OBUFDS'. -Generating RTLIL representation for module `\OBUFDS_DPHY'. -Generating RTLIL representation for module `\OBUFTDS'. -Generating RTLIL representation for module `\KEEPER'. -Generating RTLIL representation for module `\PULLDOWN'. -Generating RTLIL representation for module `\PULLUP'. -Generating RTLIL representation for module `\DCIRESET'. -Generating RTLIL representation for module `\HPIO_VREF'. -Generating RTLIL representation for module `\BUFGCE'. -Generating RTLIL representation for module `\BUFGCE_1'. -Generating RTLIL representation for module `\BUFGMUX'. -Generating RTLIL representation for module `\BUFGMUX_1'. -Generating RTLIL representation for module `\BUFGMUX_CTRL'. -Generating RTLIL representation for module `\BUFGMUX_VIRTEX4'. -Generating RTLIL representation for module `\BUFG_GT'. -Generating RTLIL representation for module `\BUFG_GT_SYNC'. -Generating RTLIL representation for module `\BUFG_PS'. -Generating RTLIL representation for module `\BUFGCE_DIV'. -Generating RTLIL representation for module `\BUFH'. -Generating RTLIL representation for module `\BUFIO2'. -Generating RTLIL representation for module `\BUFIO2_2CLK'. -Generating RTLIL representation for module `\BUFIO2FB'. -Generating RTLIL representation for module `\BUFPLL'. -Generating RTLIL representation for module `\BUFPLL_MCB'. -Generating RTLIL representation for module `\BUFIO'. -Generating RTLIL representation for module `\BUFIODQS'. -Generating RTLIL representation for module `\BUFR'. -Generating RTLIL representation for module `\BUFMR'. -Generating RTLIL representation for module `\BUFMRCE'. -Generating RTLIL representation for module `\DCM'. -Generating RTLIL representation for module `\DCM_SP'. -Generating RTLIL representation for module `\DCM_CLKGEN'. -Generating RTLIL representation for module `\DCM_ADV'. -Generating RTLIL representation for module `\DCM_BASE'. -Generating RTLIL representation for module `\DCM_PS'. -Generating RTLIL representation for module `\PMCD'. -Generating RTLIL representation for module `\PLL_ADV'. -Generating RTLIL representation for module `\PLL_BASE'. -Generating RTLIL representation for module `\MMCM_ADV'. -Generating RTLIL representation for module `\MMCM_BASE'. -Generating RTLIL representation for module `\MMCME2_ADV'. -Generating RTLIL representation for module `\MMCME2_BASE'. -Generating RTLIL representation for module `\PLLE2_ADV'. -Generating RTLIL representation for module `\PLLE2_BASE'. -Generating RTLIL representation for module `\MMCME3_ADV'. -Generating RTLIL representation for module `\MMCME3_BASE'. -Generating RTLIL representation for module `\PLLE3_ADV'. -Generating RTLIL representation for module `\PLLE3_BASE'. -Generating RTLIL representation for module `\MMCME4_ADV'. -Generating RTLIL representation for module `\MMCME4_BASE'. -Generating RTLIL representation for module `\PLLE4_ADV'. -Generating RTLIL representation for module `\PLLE4_BASE'. -Generating RTLIL representation for module `\BUFT'. -Generating RTLIL representation for module `\IN_FIFO'. -Generating RTLIL representation for module `\OUT_FIFO'. -Generating RTLIL representation for module `\HARD_SYNC'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3E'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3A'. -Generating RTLIL representation for module `\STARTUP_SPARTAN6'. -Generating RTLIL representation for module `\STARTUP_VIRTEX4'. -Generating RTLIL representation for module `\STARTUP_VIRTEX5'. -Generating RTLIL representation for module `\STARTUP_VIRTEX6'. -Generating RTLIL representation for module `\STARTUPE2'. -Generating RTLIL representation for module `\STARTUPE3'. -Generating RTLIL representation for module `\CAPTURE_SPARTAN3'. -Generating RTLIL representation for module `\CAPTURE_SPARTAN3A'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX4'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX5'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX6'. -Generating RTLIL representation for module `\CAPTUREE2'. -Generating RTLIL representation for module `\ICAP_SPARTAN3A'. -Generating RTLIL representation for module `\ICAP_SPARTAN6'. -Generating RTLIL representation for module `\ICAP_VIRTEX4'. -Generating RTLIL representation for module `\ICAP_VIRTEX5'. -Generating RTLIL representation for module `\ICAP_VIRTEX6'. -Generating RTLIL representation for module `\ICAPE2'. -Generating RTLIL representation for module `\ICAPE3'. -Generating RTLIL representation for module `\BSCAN_SPARTAN3'. -Generating RTLIL representation for module `\BSCAN_SPARTAN3A'. -Generating RTLIL representation for module `\BSCAN_SPARTAN6'. -Generating RTLIL representation for module `\BSCAN_VIRTEX4'. -Generating RTLIL representation for module `\BSCAN_VIRTEX5'. -Generating RTLIL representation for module `\BSCAN_VIRTEX6'. -Generating RTLIL representation for module `\BSCANE2'. -Generating RTLIL representation for module `\DNA_PORT'. -Generating RTLIL representation for module `\DNA_PORTE2'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX4'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX5'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX6'. -Generating RTLIL representation for module `\FRAME_ECCE2'. -Generating RTLIL representation for module `\FRAME_ECCE3'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX4'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX5'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX6'. -Generating RTLIL representation for module `\USR_ACCESSE2'. -Generating RTLIL representation for module `\POST_CRC_INTERNAL'. -Generating RTLIL representation for module `\SUSPEND_SYNC'. -Generating RTLIL representation for module `\KEY_CLEAR'. -Generating RTLIL representation for module `\MASTER_JTAG'. -Generating RTLIL representation for module `\SPI_ACCESS'. -Generating RTLIL representation for module `\EFUSE_USR'. -Generating RTLIL representation for module `\SYSMON'. -Generating RTLIL representation for module `\XADC'. -Generating RTLIL representation for module `\SYSMONE1'. -Generating RTLIL representation for module `\SYSMONE4'. -Generating RTLIL representation for module `\GTPA1_DUAL'. -Generating RTLIL representation for module `\GT11_CUSTOM'. -Generating RTLIL representation for module `\GT11_DUAL'. -Generating RTLIL representation for module `\GT11CLK'. -Generating RTLIL representation for module `\GT11CLK_MGT'. -Generating RTLIL representation for module `\GTP_DUAL'. -Generating RTLIL representation for module `\GTX_DUAL'. -Generating RTLIL representation for module `\CRC32'. -Generating RTLIL representation for module `\CRC64'. -Generating RTLIL representation for module `\GTHE1_QUAD'. -Generating RTLIL representation for module `\GTXE1'. -Generating RTLIL representation for module `\IBUFDS_GTXE1'. -Generating RTLIL representation for module `\IBUFDS_GTHE1'. -Generating RTLIL representation for module `\GTHE2_CHANNEL'. -Generating RTLIL representation for module `\GTHE2_COMMON'. -Generating RTLIL representation for module `\GTPE2_CHANNEL'. -Generating RTLIL representation for module `\GTPE2_COMMON'. -Generating RTLIL representation for module `\GTXE2_CHANNEL'. -Generating RTLIL representation for module `\GTXE2_COMMON'. -Generating RTLIL representation for module `\IBUFDS_GTE2'. -Generating RTLIL representation for module `\GTHE3_CHANNEL'. -Generating RTLIL representation for module `\GTHE3_COMMON'. -Generating RTLIL representation for module `\GTHE4_CHANNEL'. -Generating RTLIL representation for module `\GTHE4_COMMON'. -Generating RTLIL representation for module `\GTYE3_CHANNEL'. -Generating RTLIL representation for module `\GTYE3_COMMON'. -Generating RTLIL representation for module `\GTYE4_CHANNEL'. -Generating RTLIL representation for module `\GTYE4_COMMON'. -Generating RTLIL representation for module `\IBUFDS_GTE3'. -Generating RTLIL representation for module `\IBUFDS_GTE4'. -Generating RTLIL representation for module `\OBUFDS_GTE3'. -Generating RTLIL representation for module `\OBUFDS_GTE3_ADV'. -Generating RTLIL representation for module `\OBUFDS_GTE4'. -Generating RTLIL representation for module `\OBUFDS_GTE4_ADV'. -Generating RTLIL representation for module `\PCIE_A1'. -Generating RTLIL representation for module `\PCIE_EP'. -Generating RTLIL representation for module `\PCIE_2_0'. -Generating RTLIL representation for module `\PCIE_2_1'. -Generating RTLIL representation for module `\PCIE_3_0'. -Generating RTLIL representation for module `\PCIE_3_1'. -Generating RTLIL representation for module `\PCIE40E4'. -Generating RTLIL representation for module `\EMAC'. -Generating RTLIL representation for module `\TEMAC'. -Generating RTLIL representation for module `\TEMAC_SINGLE'. -Generating RTLIL representation for module `\CMAC'. -Generating RTLIL representation for module `\CMACE4'. -Generating RTLIL representation for module `\PPC405_ADV'. -Generating RTLIL representation for module `\PPC440'. -Generating RTLIL representation for module `\MCB'. -Generating RTLIL representation for module `\PS7'. -Generating RTLIL representation for module `\PS8'. -Generating RTLIL representation for module `\ILKN'. -Generating RTLIL representation for module `\ILKNE4'. -Successfully finished Verilog frontend. - -6.3. Executing HIERARCHY pass (managing design hierarchy). - -6.3.1. Analyzing design hierarchy.. -Top module: \distributed_ram - -6.3.2. Analyzing design hierarchy.. -Top module: \distributed_ram -Removed 0 unused modules. - -6.4. Executing PROC pass (convert processes to netlists). - -6.4.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Cleaned up 0 empty switches. - -6.4.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). -Removed a total of 0 dead cases. - -6.4.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). -Removed 0 redundant assignments. -Promoted 1 assignment to connection. - -6.4.4. Executing PROC_INIT pass (extract init attributes). - -6.4.5. Executing PROC_ARST pass (detect async resets in processes). - -6.4.6. Executing PROC_MUX pass (convert decision trees to multiplexers). -Creating decoders for process `\distributed_ram.$proc$attributes_test.v:36$188'. - 1/3: $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 - 2/3: $0$memwr$\memory$attributes_test.v:38$187_DATA[7:0]$190 - 3/3: $0$memwr$\memory$attributes_test.v:38$187_ADDR[3:0]$189 - -6.4.7. Executing PROC_DLATCH pass (convert process syncs to latches). - -6.4.8. Executing PROC_DFF pass (convert process syncs to FFs). -Creating register for signal `\distributed_ram.\data_out_r' using process `\distributed_ram.$proc$attributes_test.v:36$188'. - created $dff cell `$procdff$227' with positive edge clock. -Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$187_ADDR' using process `\distributed_ram.$proc$attributes_test.v:36$188'. - created $dff cell `$procdff$228' with positive edge clock. -Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$187_DATA' using process `\distributed_ram.$proc$attributes_test.v:36$188'. - created $dff cell `$procdff$229' with positive edge clock. -Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$187_EN' using process `\distributed_ram.$proc$attributes_test.v:36$188'. - created $dff cell `$procdff$230' with positive edge clock. - -6.4.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Found and cleaned up 1 empty switch in `\distributed_ram.$proc$attributes_test.v:36$188'. -Removing empty process `distributed_ram.$proc$attributes_test.v:36$188'. -Cleaned up 1 empty switch. - -6.5. Executing TRIBUF pass. - -6.6. Executing DEMINOUT pass (demote inout ports to input or output). - -6.7. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.8. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. -Removed 0 unused cells and 7 unused wires. - - -6.9. Executing CHECK pass (checking for obvious problems). -checking module distributed_ram.. -found and reported 0 problems. - -6.10. Executing OPT pass (performing simple optimizations). - -6.10.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.10.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.10.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -6.10.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \distributed_ram. - Consolidated identical input bits for $mux cell $procmux$221: - Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 - New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] - New connections: $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [7:1] = { $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] $0$memwr$\memory$attributes_test.v:38$187_EN[7:0]$191 [0] } - Optimizing cells in module \distributed_ram. -Performed a total of 1 changes. - -6.10.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.10.6. Executing OPT_RMDFF pass (remove dff with constant values). - -6.10.7. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.10.8. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.10.9. Rerunning OPT passes. (Maybe there is more to do..) - -6.10.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -6.10.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \distributed_ram. -Performed a total of 0 changes. - -6.10.12. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.10.13. Executing OPT_RMDFF pass (remove dff with constant values). - -6.10.14. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.10.15. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.10.16. Finished OPT passes. (There is nothing left to do.) - -6.11. Executing WREDUCE pass (reducing word size of cells). -Removed cell distributed_ram.$procmux$223 ($mux). -Removed cell distributed_ram.$procmux$225 ($mux). -Removed top 7 bits (of 8) from FF cell distributed_ram.$procdff$230 ($dff). - -6.12. Executing PEEPOPT pass (run peephole optimizers). - -6.13. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. -Removed 0 unused cells and 2 unused wires. - - -6.14. Executing PMUX2SHIFTX pass. - -6.15. Executing TECHMAP pass (map to technology primitives). - -6.15.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v' to AST representation. -Generating RTLIL representation for module `\_90_lut_cmp_'. -Successfully finished Verilog frontend. - -6.15.2. Continuing TECHMAP pass. -No more expansions possible. - -6.16. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). -Checking cell `$memwr$\memory$attributes_test.v:38$193' in module `\distributed_ram': merged $dff to cell. -Checking cell `$memrd$\memory$attributes_test.v:39$192' in module `\distributed_ram': merged data $dff to cell. - -6.17. Executing TECHMAP pass (map to technology primitives). - -6.17.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v' to AST representation. -Generating RTLIL representation for module `\_80_mul'. -Generating RTLIL representation for module `\_90_soft_mul'. -Successfully finished Verilog frontend. - -6.17.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v' to AST representation. -Generating RTLIL representation for module `\$__MUL25X18'. -Successfully finished Verilog frontend. - -6.17.3. Continuing TECHMAP pass. -No more expansions possible. - -6.18. Executing OPT_EXPR pass (perform const folding). - -6.19. Executing WREDUCE pass (reducing word size of cells). - -6.20. Executing XILINX_DSP pass (pack resources into DSPs). - -6.21. Executing ALUMACC pass (create $alu and $macc cells). -Extracting $alu and $macc cells in module distributed_ram: - created 0 $alu and 0 $macc cells. - -6.22. Executing SHARE pass (SAT-based resource sharing). - -6.23. Executing OPT pass (performing simple optimizations). - -6.23.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.23.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.23.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -6.23.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \distributed_ram. -Performed a total of 0 changes. - -6.23.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.23.6. Executing OPT_RMDFF pass (remove dff with constant values). - -6.23.7. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. -Removed 4 unused cells and 5 unused wires. - - -6.23.8. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.23.9. Rerunning OPT passes. (Maybe there is more to do..) - -6.23.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -6.23.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \distributed_ram. -Performed a total of 0 changes. - -6.23.12. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.23.13. Executing OPT_RMDFF pass (remove dff with constant values). - -6.23.14. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.23.15. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.23.16. Finished OPT passes. (There is nothing left to do.) - -6.24. Executing FSM pass (extract and optimize FSM). - -6.24.1. Executing FSM_DETECT pass (finding FSMs in design). - -6.24.2. Executing FSM_EXTRACT pass (extracting FSM from design). - -6.24.3. Executing FSM_OPT pass (simple optimizations of FSMs). - -6.24.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.24.5. Executing FSM_OPT pass (simple optimizations of FSMs). - -6.24.6. Executing FSM_RECODE pass (re-assigning FSM state encoding). - -6.24.7. Executing FSM_INFO pass (dumping all available information on FSM cells). - -6.24.8. Executing FSM_MAP pass (mapping FSMs to basic logic). - -6.25. Executing OPT pass (performing simple optimizations). - -6.25.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.25.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.25.3. Executing OPT_RMDFF pass (remove dff with constant values). - -6.25.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.25.5. Finished fast OPT passes. - -6.26. Executing MEMORY pass. - -6.26.1. Executing OPT_MEM pass (optimize memories). -Performed a total of 0 transformations. - -6.26.2. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). - -6.26.3. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.26.4. Executing MEMORY_SHARE pass (consolidating $memrd/$memwr cells). - -6.26.5. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.26.6. Executing MEMORY_COLLECT pass (generating $mem cells). -Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram': - $memwr$\memory$attributes_test.v:38$193 ($memwr) - $memrd$\memory$attributes_test.v:39$192 ($memrd) - -6.27. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.28. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). -Processing distributed_ram.memory: - Properties: ports=2 bits=128 rports=1 wports=1 dbits=8 abits=4 words=16 - Checking rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1): - Bram geometry: abits=9 dbits=72 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_SDP: awaste=496 dwaste=64 bwaste=36736 waste=36736 efficiency=0 - Rule #1 for bram type $__XILINX_RAMB36_SDP (variant 1) rejected: requirement 'min efficiency 5' not met. - Checking rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1): - Bram geometry: abits=9 dbits=36 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_SDP: awaste=496 dwaste=28 bwaste=18304 waste=18304 efficiency=0 - Rule #2 for bram type $__XILINX_RAMB18_SDP (variant 1) rejected: requirement 'min efficiency 5' not met. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1): - Bram geometry: abits=10 dbits=36 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=1008 dwaste=28 bwaste=36736 waste=36736 efficiency=0 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 1) rejected: requirement 'min efficiency 5' not met. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2): - Bram geometry: abits=11 dbits=18 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=2032 dwaste=10 bwaste=36736 waste=36736 efficiency=0 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 2) rejected: requirement 'min efficiency 5' not met. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3): - Bram geometry: abits=12 dbits=9 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=4080 dwaste=1 bwaste=36736 waste=36736 efficiency=0 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 3) rejected: requirement 'min efficiency 5' not met. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4): - Bram geometry: abits=13 dbits=4 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=8176 dwaste=0 bwaste=32704 waste=32704 efficiency=0 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 4) rejected: requirement 'min efficiency 5' not met. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5): - Bram geometry: abits=14 dbits=2 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=16368 dwaste=0 bwaste=32736 waste=32736 efficiency=0 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 5) rejected: requirement 'min efficiency 5' not met. - Checking rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6): - Bram geometry: abits=15 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB36_TDP: awaste=32752 dwaste=0 bwaste=32752 waste=32752 efficiency=0 - Rule #3 for bram type $__XILINX_RAMB36_TDP (variant 6) rejected: requirement 'min efficiency 5' not met. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1): - Bram geometry: abits=10 dbits=18 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=1008 dwaste=10 bwaste=18304 waste=18304 efficiency=0 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 1) rejected: requirement 'min efficiency 5' not met. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2): - Bram geometry: abits=11 dbits=9 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=2032 dwaste=1 bwaste=18304 waste=18304 efficiency=0 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 2) rejected: requirement 'min efficiency 5' not met. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3): - Bram geometry: abits=12 dbits=4 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=4080 dwaste=0 bwaste=16320 waste=16320 efficiency=0 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 3) rejected: requirement 'min efficiency 5' not met. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4): - Bram geometry: abits=13 dbits=2 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=8176 dwaste=0 bwaste=16352 waste=16352 efficiency=0 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 4) rejected: requirement 'min efficiency 5' not met. - Checking rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5): - Bram geometry: abits=14 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAMB18_TDP: awaste=16368 dwaste=0 bwaste=16368 waste=16368 efficiency=0 - Rule #4 for bram type $__XILINX_RAMB18_TDP (variant 5) rejected: requirement 'min efficiency 5' not met. - No acceptable bram resources found. - -6.29. Executing TECHMAP pass (map to technology primitives). - -6.29.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_brams_map.v' to AST representation. -Generating RTLIL representation for module `\$__XILINX_RAMB36_SDP'. -Generating RTLIL representation for module `\$__XILINX_RAMB18_SDP'. -Generating RTLIL representation for module `\$__XILINX_RAMB36_TDP'. -Generating RTLIL representation for module `\$__XILINX_RAMB18_TDP'. -Successfully finished Verilog frontend. - -6.29.2. Continuing TECHMAP pass. -No more expansions possible. - -6.30. Executing MEMORY_BRAM pass (mapping $mem cells to block memories). -Processing distributed_ram.memory: - Properties: ports=2 bits=128 rports=1 wports=1 dbits=8 abits=4 words=16 - Checking rule #1 for bram type $__XILINX_RAM32X1D (variant 1): - Bram geometry: abits=5 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAM32X1D: awaste=16 dwaste=0 bwaste=16 waste=16 efficiency=50 - Rule #1 for bram type $__XILINX_RAM32X1D (variant 1) accepted. - Mapping to bram type $__XILINX_RAM32X1D (variant 1): - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=16 efficiency=50 - Storing for later selection. - Checking rule #2 for bram type $__XILINX_RAM64X1D (variant 1): - Bram geometry: abits=6 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAM64X1D: awaste=48 dwaste=0 bwaste=48 waste=48 efficiency=25 - Rule #2 for bram type $__XILINX_RAM64X1D (variant 1) accepted. - Mapping to bram type $__XILINX_RAM64X1D (variant 1): - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=48 efficiency=25 - Storing for later selection. - Checking rule #3 for bram type $__XILINX_RAM128X1D (variant 1): - Bram geometry: abits=7 dbits=1 wports=0 rports=0 - Estimated number of duplicates for more read ports: dups=1 - Metrics for $__XILINX_RAM128X1D: awaste=112 dwaste=0 bwaste=112 waste=112 efficiency=12 - Rule #3 for bram type $__XILINX_RAM128X1D (variant 1) accepted. - Mapping to bram type $__XILINX_RAM128X1D (variant 1): - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Updated properties: dups=1 waste=112 efficiency=12 - Storing for later selection. - Selecting best of 3 rules: - Efficiency for rule 3.1: efficiency=12, cells=8, acells=1 - Efficiency for rule 2.1: efficiency=25, cells=8, acells=1 - Efficiency for rule 1.1: efficiency=50, cells=8, acells=1 - Selected rule 1.1 with efficiency 50. - Mapping to bram type $__XILINX_RAM32X1D (variant 1): - Write port #0 is in clock domain \clk. - Mapped to bram port B1. - Read port #0 is in clock domain \clk. - Mapped to bram port A1.1. - Creating $__XILINX_RAM32X1D cell at grid position <0 0 0>: memory.0.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <1 0 0>: memory.1.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <2 0 0>: memory.2.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <3 0 0>: memory.3.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <4 0 0>: memory.4.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <5 0 0>: memory.5.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <6 0 0>: memory.6.0.0 - Creating $__XILINX_RAM32X1D cell at grid position <7 0 0>: memory.7.0.0 - -6.31. Executing TECHMAP pass (map to technology primitives). - -6.31.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lutrams_map.v' to AST representation. -Generating RTLIL representation for module `\$__XILINX_RAM32X1D'. -Generating RTLIL representation for module `\$__XILINX_RAM64X1D'. -Generating RTLIL representation for module `\$__XILINX_RAM128X1D'. -Successfully finished Verilog frontend. - -6.31.2. Continuing TECHMAP pass. -Using template $paramod\$__XILINX_RAM32X1D\CLKPOL2=1 for cells of type $__XILINX_RAM32X1D. -No more expansions possible. - - -6.32. Executing OPT pass (performing simple optimizations). - -6.32.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - - -6.32.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.32.3. Executing OPT_RMDFF pass (remove dff with constant values). - -6.32.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. -Removed 0 unused cells and 65 unused wires. - - -6.32.5. Finished fast OPT passes. - -6.33. Executing MEMORY_MAP pass (converting $mem cells to logic and flip-flops). - -6.34. Executing DFFSR2DFF pass (mapping DFFSR cells to simpler FFs). - -6.35. Executing DFF2DFFE pass (transform $dff to $dffe where applicable). -Transforming FF to FF+Enable cells in module distributed_ram: - -6.36. Executing OPT pass (performing simple optimizations). - -6.36.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.36.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.36.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - No muxes found in this module. -Removed 0 multiplexer ports. - -6.36.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \distributed_ram. -Performed a total of 0 changes. - -6.36.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.36.6. Executing OPT_SHARE pass. - -6.36.7. Executing OPT_RMDFF pass (remove dff with constant values). - -6.36.8. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.36.9. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.36.10. Finished OPT passes. (There is nothing left to do.) - -6.37. Executing XILINX_SRL pass (Xilinx shift register extraction). - -6.38. Executing TECHMAP pass (map to technology primitives). - -6.38.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. -Generating RTLIL representation for module `\_90_simplemap_bool_ops'. -Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. -Generating RTLIL representation for module `\_90_simplemap_logic_ops'. -Generating RTLIL representation for module `\_90_simplemap_compare_ops'. -Generating RTLIL representation for module `\_90_simplemap_various'. -Generating RTLIL representation for module `\_90_simplemap_registers'. -Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. -Generating RTLIL representation for module `\_90_shift_shiftx'. -Generating RTLIL representation for module `\_90_fa'. -Generating RTLIL representation for module `\_90_lcu'. -Generating RTLIL representation for module `\_90_alu'. -Generating RTLIL representation for module `\_90_macc'. -Generating RTLIL representation for module `\_90_alumacc'. -Generating RTLIL representation for module `\$__div_mod_u'. -Generating RTLIL representation for module `\$__div_mod'. -Generating RTLIL representation for module `\_90_div'. -Generating RTLIL representation for module `\_90_mod'. -Generating RTLIL representation for module `\_90_pow'. -Generating RTLIL representation for module `\_90_pmux'. -Generating RTLIL representation for module `\_90_lut'. -Successfully finished Verilog frontend. - -6.38.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/arith_map.v' to AST representation. -Generating RTLIL representation for module `\_80_xilinx_lcu'. -Generating RTLIL representation for module `\_80_xilinx_alu'. -Successfully finished Verilog frontend. - -6.38.3. Continuing TECHMAP pass. -Using extmapper simplemap for cells of type $dff. -No more expansions possible. - - -6.39. Executing OPT pass (performing simple optimizations). - -6.39.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.39.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\distributed_ram'. -Removed a total of 0 cells. - -6.39.3. Executing OPT_RMDFF pass (remove dff with constant values). - -6.39.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram.. - -6.39.5. Finished fast OPT passes. - -6.40. Executing TECHMAP pass (map to technology primitives). - -6.40.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/techmap.v' to AST representation. -Generating RTLIL representation for module `\_90_simplemap_bool_ops'. -Generating RTLIL representation for module `\_90_simplemap_reduce_ops'. -Generating RTLIL representation for module `\_90_simplemap_logic_ops'. -Generating RTLIL representation for module `\_90_simplemap_compare_ops'. -Generating RTLIL representation for module `\_90_simplemap_various'. -Generating RTLIL representation for module `\_90_simplemap_registers'. -Generating RTLIL representation for module `\_90_shift_ops_shr_shl_sshl_sshr'. -Generating RTLIL representation for module `\_90_shift_shiftx'. -Generating RTLIL representation for module `\_90_fa'. -Generating RTLIL representation for module `\_90_lcu'. -Generating RTLIL representation for module `\_90_alu'. -Generating RTLIL representation for module `\_90_macc'. -Generating RTLIL representation for module `\_90_alumacc'. -Generating RTLIL representation for module `\$__div_mod_u'. -Generating RTLIL representation for module `\$__div_mod'. -Generating RTLIL representation for module `\_90_div'. -Generating RTLIL representation for module `\_90_mod'. -Generating RTLIL representation for module `\_90_pow'. -Generating RTLIL representation for module `\_90_pmux'. -Generating RTLIL representation for module `\_90_lut'. -Successfully finished Verilog frontend. - -6.40.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. -Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. -Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. -Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. -Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. -Generating RTLIL representation for module `\$__SHREG_'. -Generating RTLIL representation for module `\$__XILINX_SHREG_'. -Generating RTLIL representation for module `\$__XILINX_MUXF78'. -Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. -Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. -Successfully finished Verilog frontend. - -6.40.3. Continuing TECHMAP pass. -No more expansions possible. - -6.41. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram. - -6.42. Executing ABC pass (technology mapping using ABC). - -6.42.1. Extracting gate netlist of module `\distributed_ram' to `/input.blif'.. -Extracted 0 gates and 0 wires to a netlist network with 0 inputs and 0 outputs. -Don't call ABC as there is nothing to map. -Removing temp directory. - -6.43. Executing XILINX_SRL pass (Xilinx shift register extraction). - -6.44. Executing TECHMAP pass (map to technology primitives). - -6.44.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/lut_map.v' to AST representation. -Generating RTLIL representation for module `\$lut'. -Successfully finished Verilog frontend. - -6.44.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_map.v' to AST representation. -Generating RTLIL representation for module `\_90_dff_nn0_to_np0'. -Generating RTLIL representation for module `\_90_dff_pn0_to_pp0'. -Generating RTLIL representation for module `\_90_dff_nn1_to_np1'. -Generating RTLIL representation for module `\_90_dff_pn1_to_pp1'. -Generating RTLIL representation for module `\$__SHREG_'. -Generating RTLIL representation for module `\$__XILINX_SHREG_'. -Generating RTLIL representation for module `\$__XILINX_MUXF78'. -Generating RTLIL representation for module `\$__XILINX_TINOUTPAD'. -Generating RTLIL representation for module `\$__XILINX_TOUTPAD'. -Successfully finished Verilog frontend. - -6.44.3. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_ff_map.v' to AST representation. -Generating RTLIL representation for module `\$_DFF_N_'. -Generating RTLIL representation for module `\$_DFF_P_'. -Generating RTLIL representation for module `\$_DFFE_NP_'. -Generating RTLIL representation for module `\$_DFFE_PP_'. -Generating RTLIL representation for module `\$_DFF_NN0_'. -Generating RTLIL representation for module `\$_DFF_NP0_'. -Generating RTLIL representation for module `\$_DFF_PN0_'. -Generating RTLIL representation for module `\$_DFF_PP0_'. -Generating RTLIL representation for module `\$_DFF_NN1_'. -Generating RTLIL representation for module `\$_DFF_NP1_'. -Generating RTLIL representation for module `\$_DFF_PN1_'. -Generating RTLIL representation for module `\$_DFF_PP1_'. -Generating RTLIL representation for module `\$_DLATCH_N_'. -Generating RTLIL representation for module `\$_DLATCH_P_'. -Successfully finished Verilog frontend. - -6.44.4. Continuing TECHMAP pass. -Using template $paramod\$_DFF_P_\_TECHMAP_WIREINIT_Q_=1'x for cells of type $_DFF_P_. -No more expansions possible. - -Removed 0 unused cells and 32 unused wires. - -6.45. Executing CLKBUFMAP pass (inserting global clock buffers). -Inserting BUFG on distributed_ram.clk[0]. - -6.46. Executing HIERARCHY pass (managing design hierarchy). - -6.46.1. Analyzing design hierarchy.. -Top module: \distributed_ram - -6.46.2. Analyzing design hierarchy.. -Top module: \distributed_ram -Removed 0 unused modules. - -6.47. Printing statistics. - -=== distributed_ram === - - Number of wires: 16 - Number of wire bits: 40 - Number of public wires: 6 - Number of public wire bits: 30 - Number of memories: 0 - Number of memory bits: 0 - Number of processes: 0 - Number of cells: 17 - BUFG 1 - FDRE 8 - RAM32X1D 8 - - Estimated number of LCs: 0 - -6.48. Executing CHECK pass (checking for obvious problems). -checking module distributed_ram.. -found and reported 0 problems. - -7. Executing Verilog-2005 frontend: attributes_test.v -Parsing Verilog input from `attributes_test.v' to AST representation. -Generating RTLIL representation for module `\block_ram'. -Generating RTLIL representation for module `\distributed_ram'. -Generating RTLIL representation for module `\distributed_ram_manual'. -Generating RTLIL representation for module `\distributed_ram_manual_syn'. -Successfully finished Verilog frontend. - -8. Executing PREP pass. - -8.1. Executing HIERARCHY pass (managing design hierarchy). - -8.2. Executing PROC pass (convert processes to netlists). - -8.2.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Cleaned up 0 empty switches. - -8.2.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). -Removed a total of 0 dead cases. - -8.2.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). -Removed 0 redundant assignments. -Promoted 4 assignments to connections. - -8.2.4. Executing PROC_INIT pass (extract init attributes). - -8.2.5. Executing PROC_ARST pass (detect async resets in processes). - -8.2.6. Executing PROC_MUX pass (convert decision trees to multiplexers). -Creating decoders for process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. - 1/3: $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 - 2/3: $0$memwr$\memory$attributes_test.v:82$440_DATA[7:0]$444 - 3/3: $0$memwr$\memory$attributes_test.v:82$440_ADDR[3:0]$442 -Creating decoders for process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. - 1/3: $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 - 2/3: $0$memwr$\memory$attributes_test.v:60$433_DATA[7:0]$437 - 3/3: $0$memwr$\memory$attributes_test.v:60$433_ADDR[3:0]$436 -Creating decoders for process `\distributed_ram.$proc$attributes_test.v:36$427'. - 1/3: $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 - 2/3: $0$memwr$\memory$attributes_test.v:38$426_DATA[7:0]$429 - 3/3: $0$memwr$\memory$attributes_test.v:38$426_ADDR[3:0]$428 -Creating decoders for process `\block_ram.$proc$attributes_test.v:14$420'. - 1/3: $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 - 2/3: $0$memwr$\memory$attributes_test.v:16$419_DATA[3:0]$422 - 3/3: $0$memwr$\memory$attributes_test.v:16$419_ADDR[9:0]$421 - -8.2.7. Executing PROC_DLATCH pass (convert process syncs to latches). - -8.2.8. Executing PROC_DFF pass (convert process syncs to FFs). -Creating register for signal `\distributed_ram_manual_syn.$memwr$\memory$attributes_test.v:82$440_ADDR' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. - created $dff cell `$procdff$471' with positive edge clock. -Creating register for signal `\distributed_ram_manual_syn.\data_out_r' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. - created $dff cell `$procdff$472' with positive edge clock. -Creating register for signal `\distributed_ram_manual_syn.$memwr$\memory$attributes_test.v:82$440_EN' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. - created $dff cell `$procdff$473' with positive edge clock. -Creating register for signal `\distributed_ram_manual_syn.$memwr$\memory$attributes_test.v:82$440_DATA' using process `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. - created $dff cell `$procdff$474' with positive edge clock. -Creating register for signal `\distributed_ram_manual.$memwr$\memory$attributes_test.v:60$433_EN' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. - created $dff cell `$procdff$475' with positive edge clock. -Creating register for signal `\distributed_ram_manual.$memwr$\memory$attributes_test.v:60$433_ADDR' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. - created $dff cell `$procdff$476' with positive edge clock. -Creating register for signal `\distributed_ram_manual.$memwr$\memory$attributes_test.v:60$433_DATA' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. - created $dff cell `$procdff$477' with positive edge clock. -Creating register for signal `\distributed_ram_manual.\data_out_r' using process `\distributed_ram_manual.$proc$attributes_test.v:58$434'. - created $dff cell `$procdff$478' with positive edge clock. -Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$426_ADDR' using process `\distributed_ram.$proc$attributes_test.v:36$427'. - created $dff cell `$procdff$479' with positive edge clock. -Creating register for signal `\distributed_ram.\data_out_r' using process `\distributed_ram.$proc$attributes_test.v:36$427'. - created $dff cell `$procdff$480' with positive edge clock. -Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$426_DATA' using process `\distributed_ram.$proc$attributes_test.v:36$427'. - created $dff cell `$procdff$481' with positive edge clock. -Creating register for signal `\distributed_ram.$memwr$\memory$attributes_test.v:38$426_EN' using process `\distributed_ram.$proc$attributes_test.v:36$427'. - created $dff cell `$procdff$482' with positive edge clock. -Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$419_ADDR' using process `\block_ram.$proc$attributes_test.v:14$420'. - created $dff cell `$procdff$483' with positive edge clock. -Creating register for signal `\block_ram.\data_out_r' using process `\block_ram.$proc$attributes_test.v:14$420'. - created $dff cell `$procdff$484' with positive edge clock. -Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$419_DATA' using process `\block_ram.$proc$attributes_test.v:14$420'. - created $dff cell `$procdff$485' with positive edge clock. -Creating register for signal `\block_ram.$memwr$\memory$attributes_test.v:16$419_EN' using process `\block_ram.$proc$attributes_test.v:14$420'. - created $dff cell `$procdff$486' with positive edge clock. - -8.2.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Found and cleaned up 1 empty switch in `\distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. -Removing empty process `distributed_ram_manual_syn.$proc$attributes_test.v:80$441'. -Found and cleaned up 1 empty switch in `\distributed_ram_manual.$proc$attributes_test.v:58$434'. -Removing empty process `distributed_ram_manual.$proc$attributes_test.v:58$434'. -Found and cleaned up 1 empty switch in `\distributed_ram.$proc$attributes_test.v:36$427'. -Removing empty process `distributed_ram.$proc$attributes_test.v:36$427'. -Found and cleaned up 1 empty switch in `\block_ram.$proc$attributes_test.v:14$420'. -Removing empty process `block_ram.$proc$attributes_test.v:14$420'. -Cleaned up 4 empty switches. - -8.3. Executing OPT_EXPR pass (perform const folding). -Optimizing module distributed_ram_manual_syn. -Optimizing module distributed_ram_manual. -Optimizing module distributed_ram. -Optimizing module block_ram. - -8.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \distributed_ram_manual_syn.. -Finding unused cells or wires in module \distributed_ram_manual.. -Finding unused cells or wires in module \distributed_ram.. -Finding unused cells or wires in module \block_ram.. -Removed 0 unused cells and 28 unused wires. - - -8.5. Executing CHECK pass (checking for obvious problems). -checking module block_ram.. -checking module distributed_ram.. -checking module distributed_ram_manual.. -checking module distributed_ram_manual_syn.. -found and reported 0 problems. - -8.6. Executing OPT pass (performing simple optimizations). - -8.6.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. -Optimizing module distributed_ram. -Optimizing module distributed_ram_manual. -Optimizing module distributed_ram_manual_syn. - -8.6.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Finding identical cells in module `\distributed_ram'. -Finding identical cells in module `\distributed_ram_manual'. -Finding identical cells in module `\distributed_ram_manual_syn'. -Removed a total of 0 cells. - -8.6.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Running muxtree optimizer on module \distributed_ram_manual.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Running muxtree optimizer on module \distributed_ram_manual_syn.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -8.6.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. - Consolidated identical input bits for $mux cell $procmux$465: - Old ports: A=4'0000, B=4'1111, Y=$0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 - New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] - New connections: $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [3:1] = { $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] $0$memwr$\memory$attributes_test.v:16$419_EN[3:0]$423 [0] } - Optimizing cells in module \block_ram. - Optimizing cells in module \distributed_ram. - Consolidated identical input bits for $mux cell $procmux$459: - Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 - New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] - New connections: $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [7:1] = { $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] $0$memwr$\memory$attributes_test.v:38$426_EN[7:0]$430 [0] } - Optimizing cells in module \distributed_ram. - Optimizing cells in module \distributed_ram_manual. - Consolidated identical input bits for $mux cell $procmux$453: - Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 - New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] - New connections: $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [7:1] = { $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] $0$memwr$\memory$attributes_test.v:60$433_EN[7:0]$435 [0] } - Optimizing cells in module \distributed_ram_manual. - Optimizing cells in module \distributed_ram_manual_syn. - Consolidated identical input bits for $mux cell $procmux$447: - Old ports: A=8'00000000, B=8'11111111, Y=$0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 - New ports: A=1'0, B=1'1, Y=$0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] - New connections: $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [7:1] = { $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] $0$memwr$\memory$attributes_test.v:82$440_EN[7:0]$443 [0] } - Optimizing cells in module \distributed_ram_manual_syn. -Performed a total of 4 changes. - -8.6.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Finding identical cells in module `\distributed_ram'. -Finding identical cells in module `\distributed_ram_manual'. -Finding identical cells in module `\distributed_ram_manual_syn'. -Removed a total of 0 cells. - -8.6.6. Executing OPT_RMDFF pass (remove dff with constant values). - -8.6.7. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Finding unused cells or wires in module \distributed_ram.. -Finding unused cells or wires in module \distributed_ram_manual.. -Finding unused cells or wires in module \distributed_ram_manual_syn.. - -8.6.8. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. -Optimizing module distributed_ram. -Optimizing module distributed_ram_manual. -Optimizing module distributed_ram_manual_syn. - -8.6.9. Rerunning OPT passes. (Maybe there is more to do..) - -8.6.10. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Running muxtree optimizer on module \distributed_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Running muxtree optimizer on module \distributed_ram_manual.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Running muxtree optimizer on module \distributed_ram_manual_syn.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -8.6.11. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. - Optimizing cells in module \distributed_ram. - Optimizing cells in module \distributed_ram_manual. - Optimizing cells in module \distributed_ram_manual_syn. -Performed a total of 0 changes. - -8.6.12. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Finding identical cells in module `\distributed_ram'. -Finding identical cells in module `\distributed_ram_manual'. -Finding identical cells in module `\distributed_ram_manual_syn'. -Removed a total of 0 cells. - -8.6.13. Executing OPT_RMDFF pass (remove dff with constant values). - -8.6.14. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Finding unused cells or wires in module \distributed_ram.. -Finding unused cells or wires in module \distributed_ram_manual.. -Finding unused cells or wires in module \distributed_ram_manual_syn.. - -8.6.15. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. -Optimizing module distributed_ram. -Optimizing module distributed_ram_manual. -Optimizing module distributed_ram_manual_syn. - -8.6.16. Finished OPT passes. (There is nothing left to do.) - -8.7. Executing WREDUCE pass (reducing word size of cells). -Removed top 3 bits (of 4) from FF cell block_ram.$procdff$486 ($dff). -Removed top 7 bits (of 8) from FF cell distributed_ram.$procdff$482 ($dff). -Removed top 7 bits (of 8) from FF cell distributed_ram_manual.$procdff$475 ($dff). -Removed top 7 bits (of 8) from FF cell distributed_ram_manual_syn.$procdff$473 ($dff). - -8.8. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). -Checking cell `$memwr$\memory$attributes_test.v:16$425' in module `\block_ram': merged $dff to cell. -Checking cell `$memwr$\memory$attributes_test.v:38$432' in module `\distributed_ram': merged $dff to cell. -Checking cell `$memwr$\memory$attributes_test.v:60$439' in module `\distributed_ram_manual': merged $dff to cell. -Checking cell `$memwr$\memory$attributes_test.v:82$446' in module `\distributed_ram_manual_syn': merged $dff to cell. - -8.9. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Finding unused cells or wires in module \distributed_ram.. -Finding unused cells or wires in module \distributed_ram_manual.. -Finding unused cells or wires in module \distributed_ram_manual_syn.. -Removed 12 unused cells and 12 unused wires. - - -8.10. Executing MEMORY_COLLECT pass (generating $mem cells). -Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\block_ram': - $memwr$\memory$attributes_test.v:16$425 ($memwr) - $memrd$\memory$attributes_test.v:17$424 ($memrd) -Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram': - $memwr$\memory$attributes_test.v:38$432 ($memwr) - $memrd$\memory$attributes_test.v:39$431 ($memrd) -Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram_manual': - $memwr$\memory$attributes_test.v:60$439 ($memwr) - $memrd$\memory$attributes_test.v:61$438 ($memrd) -Collecting $memrd, $memwr and $meminit for memory `\memory' in module `\distributed_ram_manual_syn': - $memwr$\memory$attributes_test.v:82$446 ($memwr) - $memrd$\memory$attributes_test.v:83$445 ($memrd) - -8.11. Executing OPT pass (performing simple optimizations). - -8.11.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. -Optimizing module distributed_ram. -Optimizing module distributed_ram_manual. -Optimizing module distributed_ram_manual_syn. - -8.11.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Finding identical cells in module `\distributed_ram'. -Finding identical cells in module `\distributed_ram_manual'. -Finding identical cells in module `\distributed_ram_manual_syn'. -Removed a total of 0 cells. - -8.11.3. Executing OPT_RMDFF pass (remove dff with constant values). - -8.11.4. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Finding unused cells or wires in module \distributed_ram.. -Finding unused cells or wires in module \distributed_ram_manual.. -Finding unused cells or wires in module \distributed_ram_manual_syn.. - -8.11.5. Finished fast OPT passes. - -8.12. Printing statistics. - -=== block_ram === - - Number of wires: 10 - Number of wire bits: 46 - Number of public wires: 6 - Number of public wire bits: 24 - Number of memories: 0 - Number of memory bits: 0 - Number of processes: 0 - Number of cells: 5 - $dff 1 - $mem 1 - $mux 3 - -=== distributed_ram === - - Number of wires: 10 - Number of wire bits: 58 - Number of public wires: 6 - Number of public wire bits: 30 - Number of memories: 0 - Number of memory bits: 0 - Number of processes: 0 - Number of cells: 5 - $dff 1 - $mem 1 - $mux 3 - -=== distributed_ram_manual === - - Number of wires: 10 - Number of wire bits: 58 - Number of public wires: 6 - Number of public wire bits: 30 - Number of memories: 0 - Number of memory bits: 0 - Number of processes: 0 - Number of cells: 5 - $dff 1 - $mem 1 - $mux 3 - -=== distributed_ram_manual_syn === - - Number of wires: 10 - Number of wire bits: 58 - Number of public wires: 6 - Number of public wire bits: 30 - Number of memories: 0 - Number of memory bits: 0 - Number of processes: 0 - Number of cells: 5 - $dff 1 - $mem 1 - $mux 3 - -8.13. Executing CHECK pass (checking for obvious problems). -checking module block_ram.. -checking module distributed_ram.. -checking module distributed_ram_manual.. -checking module distributed_ram_manual_syn.. -found and reported 0 problems. - -9. Executing SYNTH_XILINX pass. - -9.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_sim.v' to AST representation. -Generating RTLIL representation for module `\VCC'. -Generating RTLIL representation for module `\GND'. -Generating RTLIL representation for module `\IBUF'. -Generating RTLIL representation for module `\IBUFG'. -Generating RTLIL representation for module `\OBUF'. -Generating RTLIL representation for module `\IOBUF'. -Generating RTLIL representation for module `\OBUFT'. -Generating RTLIL representation for module `\BUFG'. -Generating RTLIL representation for module `\BUFGCTRL'. -Generating RTLIL representation for module `\BUFHCE'. -Generating RTLIL representation for module `\INV'. -Generating RTLIL representation for module `\LUT1'. -Generating RTLIL representation for module `\LUT2'. -Generating RTLIL representation for module `\LUT3'. -Generating RTLIL representation for module `\LUT4'. -Generating RTLIL representation for module `\LUT5'. -Generating RTLIL representation for module `\LUT6'. -Generating RTLIL representation for module `\LUT6_2'. -Generating RTLIL representation for module `\MUXCY'. -Generating RTLIL representation for module `\MUXF7'. -Generating RTLIL representation for module `\MUXF8'. -Generating RTLIL representation for module `\XORCY'. -Generating RTLIL representation for module `\CARRY4'. -Generating RTLIL representation for module `\FDRE'. -Generating RTLIL representation for module `\FDSE'. -Generating RTLIL representation for module `\FDCE'. -Generating RTLIL representation for module `\FDPE'. -Generating RTLIL representation for module `\FDRE_1'. -Generating RTLIL representation for module `\FDSE_1'. -Generating RTLIL representation for module `\FDCE_1'. -Generating RTLIL representation for module `\FDPE_1'. -Generating RTLIL representation for module `\LDCE'. -Generating RTLIL representation for module `\LDPE'. -Generating RTLIL representation for module `\RAM16X1S'. -Generating RTLIL representation for module `\RAM16X1S_1'. -Generating RTLIL representation for module `\RAM32X1S'. -Generating RTLIL representation for module `\RAM32X1S_1'. -Generating RTLIL representation for module `\RAM64X1S'. -Generating RTLIL representation for module `\RAM64X1S_1'. -Generating RTLIL representation for module `\RAM128X1S'. -Generating RTLIL representation for module `\RAM128X1S_1'. -Generating RTLIL representation for module `\RAM256X1S'. -Generating RTLIL representation for module `\RAM512X1S'. -Generating RTLIL representation for module `\RAM16X2S'. -Generating RTLIL representation for module `\RAM32X2S'. -Generating RTLIL representation for module `\RAM64X2S'. -Generating RTLIL representation for module `\RAM16X4S'. -Generating RTLIL representation for module `\RAM32X4S'. -Generating RTLIL representation for module `\RAM16X8S'. -Generating RTLIL representation for module `\RAM32X8S'. -Generating RTLIL representation for module `\RAM16X1D'. -Generating RTLIL representation for module `\RAM16X1D_1'. -Generating RTLIL representation for module `\RAM32X1D'. -Generating RTLIL representation for module `\RAM32X1D_1'. -Generating RTLIL representation for module `\RAM64X1D'. -Generating RTLIL representation for module `\RAM64X1D_1'. -Generating RTLIL representation for module `\RAM128X1D'. -Generating RTLIL representation for module `\RAM256X1D'. -Generating RTLIL representation for module `\RAM32M'. -Generating RTLIL representation for module `\RAM32M16'. -Generating RTLIL representation for module `\RAM64M'. -Generating RTLIL representation for module `\RAM64M8'. -Generating RTLIL representation for module `\ROM16X1'. -Generating RTLIL representation for module `\ROM32X1'. -Generating RTLIL representation for module `\ROM64X1'. -Generating RTLIL representation for module `\ROM128X1'. -Generating RTLIL representation for module `\ROM256X1'. -Generating RTLIL representation for module `\SRL16E'. -Generating RTLIL representation for module `\SRLC16E'. -Generating RTLIL representation for module `\SRLC32E'. -Generating RTLIL representation for module `\MULT18X18'. -Generating RTLIL representation for module `\MULT18X18S'. -Generating RTLIL representation for module `\MULT18X18SIO'. -Generating RTLIL representation for module `\DSP48A'. -Generating RTLIL representation for module `\DSP48A1'. -Generating RTLIL representation for module `\DSP48E1'. -Successfully finished Verilog frontend. - -9.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/cells_xtra.v' to AST representation. -Generating RTLIL representation for module `\FDCPE'. -Generating RTLIL representation for module `\FDRSE'. -Generating RTLIL representation for module `\LDCPE'. -Generating RTLIL representation for module `\AND2B1L'. -Generating RTLIL representation for module `\OR2L'. -Generating RTLIL representation for module `\MUXF5'. -Generating RTLIL representation for module `\MUXF6'. -Generating RTLIL representation for module `\MUXF9'. -Generating RTLIL representation for module `\CARRY8'. -Generating RTLIL representation for module `\ORCY'. -Generating RTLIL representation for module `\MULT_AND'. -Generating RTLIL representation for module `\SRL16'. -Generating RTLIL representation for module `\SRLC16'. -Generating RTLIL representation for module `\CFGLUT5'. -Generating RTLIL representation for module `\RAMB16_S1'. -Generating RTLIL representation for module `\RAMB16_S2'. -Generating RTLIL representation for module `\RAMB16_S4'. -Generating RTLIL representation for module `\RAMB16_S9'. -Generating RTLIL representation for module `\RAMB16_S18'. -Generating RTLIL representation for module `\RAMB16_S36'. -Generating RTLIL representation for module `\RAMB16_S1_S1'. -Generating RTLIL representation for module `\RAMB16_S1_S2'. -Generating RTLIL representation for module `\RAMB16_S1_S4'. -Generating RTLIL representation for module `\RAMB16_S1_S9'. -Generating RTLIL representation for module `\RAMB16_S1_S18'. -Generating RTLIL representation for module `\RAMB16_S1_S36'. -Generating RTLIL representation for module `\RAMB16_S2_S2'. -Generating RTLIL representation for module `\RAMB16_S2_S4'. -Generating RTLIL representation for module `\RAMB16_S2_S9'. -Generating RTLIL representation for module `\RAMB16_S2_S18'. -Generating RTLIL representation for module `\RAMB16_S2_S36'. -Generating RTLIL representation for module `\RAMB16_S4_S4'. -Generating RTLIL representation for module `\RAMB16_S4_S9'. -Generating RTLIL representation for module `\RAMB16_S4_S18'. -Generating RTLIL representation for module `\RAMB16_S4_S36'. -Generating RTLIL representation for module `\RAMB16_S9_S9'. -Generating RTLIL representation for module `\RAMB16_S9_S18'. -Generating RTLIL representation for module `\RAMB16_S9_S36'. -Generating RTLIL representation for module `\RAMB16_S18_S18'. -Generating RTLIL representation for module `\RAMB16_S18_S36'. -Generating RTLIL representation for module `\RAMB16_S36_S36'. -Generating RTLIL representation for module `\RAMB16BWE_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36'. -Generating RTLIL representation for module `\RAMB16BWE_S18_S9'. -Generating RTLIL representation for module `\RAMB16BWE_S18_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S9'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S18'. -Generating RTLIL representation for module `\RAMB16BWE_S36_S36'. -Generating RTLIL representation for module `\RAMB16BWER'. -Generating RTLIL representation for module `\RAMB8BWER'. -Generating RTLIL representation for module `\FIFO16'. -Generating RTLIL representation for module `\RAMB16'. -Generating RTLIL representation for module `\RAMB32_S64_ECC'. -Generating RTLIL representation for module `\FIFO18'. -Generating RTLIL representation for module `\FIFO18_36'. -Generating RTLIL representation for module `\FIFO36'. -Generating RTLIL representation for module `\FIFO36_72'. -Generating RTLIL representation for module `\RAMB18'. -Generating RTLIL representation for module `\RAMB36'. -Generating RTLIL representation for module `\RAMB18SDP'. -Generating RTLIL representation for module `\RAMB36SDP'. -Generating RTLIL representation for module `\FIFO18E1'. -Generating RTLIL representation for module `\FIFO36E1'. -Generating RTLIL representation for module `\RAMB18E1'. -Generating RTLIL representation for module `\RAMB36E1'. -Generating RTLIL representation for module `\FIFO18E2'. -Generating RTLIL representation for module `\FIFO36E2'. -Generating RTLIL representation for module `\RAMB18E2'. -Generating RTLIL representation for module `\RAMB36E2'. -Generating RTLIL representation for module `\URAM288'. -Generating RTLIL representation for module `\URAM288_BASE'. -Generating RTLIL representation for module `\DSP48'. -Generating RTLIL representation for module `\DSP48E'. -Generating RTLIL representation for module `\DSP48E2'. -Generating RTLIL representation for module `\IFDDRCPE'. -Generating RTLIL representation for module `\IFDDRRSE'. -Generating RTLIL representation for module `\OFDDRCPE'. -Generating RTLIL representation for module `\OFDDRRSE'. -Generating RTLIL representation for module `\OFDDRTCPE'. -Generating RTLIL representation for module `\OFDDRTRSE'. -Generating RTLIL representation for module `\IDDR2'. -Generating RTLIL representation for module `\ODDR2'. -Generating RTLIL representation for module `\IDDR'. -Generating RTLIL representation for module `\IDDR_2CLK'. -Generating RTLIL representation for module `\ODDR'. -Generating RTLIL representation for module `\IDELAYCTRL'. -Generating RTLIL representation for module `\IDELAY'. -Generating RTLIL representation for module `\ISERDES'. -Generating RTLIL representation for module `\OSERDES'. -Generating RTLIL representation for module `\IODELAY'. -Generating RTLIL representation for module `\ISERDES_NODELAY'. -Generating RTLIL representation for module `\IODELAYE1'. -Generating RTLIL representation for module `\ISERDESE1'. -Generating RTLIL representation for module `\OSERDESE1'. -Generating RTLIL representation for module `\IDELAYE2'. -Generating RTLIL representation for module `\ODELAYE2'. -Generating RTLIL representation for module `\ISERDESE2'. -Generating RTLIL representation for module `\OSERDESE2'. -Generating RTLIL representation for module `\PHASER_IN'. -Generating RTLIL representation for module `\PHASER_IN_PHY'. -Generating RTLIL representation for module `\PHASER_OUT'. -Generating RTLIL representation for module `\PHASER_OUT_PHY'. -Generating RTLIL representation for module `\PHASER_REF'. -Generating RTLIL representation for module `\PHY_CONTROL'. -Generating RTLIL representation for module `\IDDRE1'. -Generating RTLIL representation for module `\ODDRE1'. -Generating RTLIL representation for module `\IDELAYE3'. -Generating RTLIL representation for module `\ODELAYE3'. -Generating RTLIL representation for module `\ISERDESE3'. -Generating RTLIL representation for module `\OSERDESE3'. -Generating RTLIL representation for module `\BITSLICE_CONTROL'. -Generating RTLIL representation for module `\RIU_OR'. -Generating RTLIL representation for module `\RX_BITSLICE'. -Generating RTLIL representation for module `\RXTX_BITSLICE'. -Generating RTLIL representation for module `\TX_BITSLICE'. -Generating RTLIL representation for module `\TX_BITSLICE_TRI'. -Generating RTLIL representation for module `\IODELAY2'. -Generating RTLIL representation for module `\IODRP2'. -Generating RTLIL representation for module `\IODRP2_MCB'. -Generating RTLIL representation for module `\ISERDES2'. -Generating RTLIL representation for module `\OSERDES2'. -Generating RTLIL representation for module `\IBUF_DLY_ADJ'. -Generating RTLIL representation for module `\IBUF_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUF_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUF_ANALOG'. -Generating RTLIL representation for module `\IBUFE3'. -Generating RTLIL representation for module `\IBUFDS'. -Generating RTLIL representation for module `\IBUFDS_DLY_ADJ'. -Generating RTLIL representation for module `\IBUFDS_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUFDS_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_IBUFDISABLE'. -Generating RTLIL representation for module `\IBUFDS_DIFF_OUT_INTERMDISABLE'. -Generating RTLIL representation for module `\IBUFDSE3'. -Generating RTLIL representation for module `\IBUFDS_DPHY'. -Generating RTLIL representation for module `\IBUFGDS'. -Generating RTLIL representation for module `\IBUFGDS_DIFF_OUT'. -Generating RTLIL representation for module `\IOBUF_DCIEN'. -Generating RTLIL representation for module `\IOBUF_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFE3'. -Generating RTLIL representation for module `\IOBUFDS'. -Generating RTLIL representation for module `\IOBUFDS_DCIEN'. -Generating RTLIL representation for module `\IOBUFDS_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_DCIEN'. -Generating RTLIL representation for module `\IOBUFDS_DIFF_OUT_INTERMDISABLE'. -Generating RTLIL representation for module `\IOBUFDSE3'. -Generating RTLIL representation for module `\OBUFDS'. -Generating RTLIL representation for module `\OBUFDS_DPHY'. -Generating RTLIL representation for module `\OBUFTDS'. -Generating RTLIL representation for module `\KEEPER'. -Generating RTLIL representation for module `\PULLDOWN'. -Generating RTLIL representation for module `\PULLUP'. -Generating RTLIL representation for module `\DCIRESET'. -Generating RTLIL representation for module `\HPIO_VREF'. -Generating RTLIL representation for module `\BUFGCE'. -Generating RTLIL representation for module `\BUFGCE_1'. -Generating RTLIL representation for module `\BUFGMUX'. -Generating RTLIL representation for module `\BUFGMUX_1'. -Generating RTLIL representation for module `\BUFGMUX_CTRL'. -Generating RTLIL representation for module `\BUFGMUX_VIRTEX4'. -Generating RTLIL representation for module `\BUFG_GT'. -Generating RTLIL representation for module `\BUFG_GT_SYNC'. -Generating RTLIL representation for module `\BUFG_PS'. -Generating RTLIL representation for module `\BUFGCE_DIV'. -Generating RTLIL representation for module `\BUFH'. -Generating RTLIL representation for module `\BUFIO2'. -Generating RTLIL representation for module `\BUFIO2_2CLK'. -Generating RTLIL representation for module `\BUFIO2FB'. -Generating RTLIL representation for module `\BUFPLL'. -Generating RTLIL representation for module `\BUFPLL_MCB'. -Generating RTLIL representation for module `\BUFIO'. -Generating RTLIL representation for module `\BUFIODQS'. -Generating RTLIL representation for module `\BUFR'. -Generating RTLIL representation for module `\BUFMR'. -Generating RTLIL representation for module `\BUFMRCE'. -Generating RTLIL representation for module `\DCM'. -Generating RTLIL representation for module `\DCM_SP'. -Generating RTLIL representation for module `\DCM_CLKGEN'. -Generating RTLIL representation for module `\DCM_ADV'. -Generating RTLIL representation for module `\DCM_BASE'. -Generating RTLIL representation for module `\DCM_PS'. -Generating RTLIL representation for module `\PMCD'. -Generating RTLIL representation for module `\PLL_ADV'. -Generating RTLIL representation for module `\PLL_BASE'. -Generating RTLIL representation for module `\MMCM_ADV'. -Generating RTLIL representation for module `\MMCM_BASE'. -Generating RTLIL representation for module `\MMCME2_ADV'. -Generating RTLIL representation for module `\MMCME2_BASE'. -Generating RTLIL representation for module `\PLLE2_ADV'. -Generating RTLIL representation for module `\PLLE2_BASE'. -Generating RTLIL representation for module `\MMCME3_ADV'. -Generating RTLIL representation for module `\MMCME3_BASE'. -Generating RTLIL representation for module `\PLLE3_ADV'. -Generating RTLIL representation for module `\PLLE3_BASE'. -Generating RTLIL representation for module `\MMCME4_ADV'. -Generating RTLIL representation for module `\MMCME4_BASE'. -Generating RTLIL representation for module `\PLLE4_ADV'. -Generating RTLIL representation for module `\PLLE4_BASE'. -Generating RTLIL representation for module `\BUFT'. -Generating RTLIL representation for module `\IN_FIFO'. -Generating RTLIL representation for module `\OUT_FIFO'. -Generating RTLIL representation for module `\HARD_SYNC'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3E'. -Generating RTLIL representation for module `\STARTUP_SPARTAN3A'. -Generating RTLIL representation for module `\STARTUP_SPARTAN6'. -Generating RTLIL representation for module `\STARTUP_VIRTEX4'. -Generating RTLIL representation for module `\STARTUP_VIRTEX5'. -Generating RTLIL representation for module `\STARTUP_VIRTEX6'. -Generating RTLIL representation for module `\STARTUPE2'. -Generating RTLIL representation for module `\STARTUPE3'. -Generating RTLIL representation for module `\CAPTURE_SPARTAN3'. -Generating RTLIL representation for module `\CAPTURE_SPARTAN3A'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX4'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX5'. -Generating RTLIL representation for module `\CAPTURE_VIRTEX6'. -Generating RTLIL representation for module `\CAPTUREE2'. -Generating RTLIL representation for module `\ICAP_SPARTAN3A'. -Generating RTLIL representation for module `\ICAP_SPARTAN6'. -Generating RTLIL representation for module `\ICAP_VIRTEX4'. -Generating RTLIL representation for module `\ICAP_VIRTEX5'. -Generating RTLIL representation for module `\ICAP_VIRTEX6'. -Generating RTLIL representation for module `\ICAPE2'. -Generating RTLIL representation for module `\ICAPE3'. -Generating RTLIL representation for module `\BSCAN_SPARTAN3'. -Generating RTLIL representation for module `\BSCAN_SPARTAN3A'. -Generating RTLIL representation for module `\BSCAN_SPARTAN6'. -Generating RTLIL representation for module `\BSCAN_VIRTEX4'. -Generating RTLIL representation for module `\BSCAN_VIRTEX5'. -Generating RTLIL representation for module `\BSCAN_VIRTEX6'. -Generating RTLIL representation for module `\BSCANE2'. -Generating RTLIL representation for module `\DNA_PORT'. -Generating RTLIL representation for module `\DNA_PORTE2'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX4'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX5'. -Generating RTLIL representation for module `\FRAME_ECC_VIRTEX6'. -Generating RTLIL representation for module `\FRAME_ECCE2'. -Generating RTLIL representation for module `\FRAME_ECCE3'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX4'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX5'. -Generating RTLIL representation for module `\USR_ACCESS_VIRTEX6'. -Generating RTLIL representation for module `\USR_ACCESSE2'. -Generating RTLIL representation for module `\POST_CRC_INTERNAL'. -Generating RTLIL representation for module `\SUSPEND_SYNC'. -Generating RTLIL representation for module `\KEY_CLEAR'. -Generating RTLIL representation for module `\MASTER_JTAG'. -Generating RTLIL representation for module `\SPI_ACCESS'. -Generating RTLIL representation for module `\EFUSE_USR'. -Generating RTLIL representation for module `\SYSMON'. -Generating RTLIL representation for module `\XADC'. -Generating RTLIL representation for module `\SYSMONE1'. -Generating RTLIL representation for module `\SYSMONE4'. -Generating RTLIL representation for module `\GTPA1_DUAL'. -Generating RTLIL representation for module `\GT11_CUSTOM'. -Generating RTLIL representation for module `\GT11_DUAL'. -Generating RTLIL representation for module `\GT11CLK'. -Generating RTLIL representation for module `\GT11CLK_MGT'. -Generating RTLIL representation for module `\GTP_DUAL'. -Generating RTLIL representation for module `\GTX_DUAL'. -Generating RTLIL representation for module `\CRC32'. -Generating RTLIL representation for module `\CRC64'. -Generating RTLIL representation for module `\GTHE1_QUAD'. -Generating RTLIL representation for module `\GTXE1'. -Generating RTLIL representation for module `\IBUFDS_GTXE1'. -Generating RTLIL representation for module `\IBUFDS_GTHE1'. -Generating RTLIL representation for module `\GTHE2_CHANNEL'. -Generating RTLIL representation for module `\GTHE2_COMMON'. -Generating RTLIL representation for module `\GTPE2_CHANNEL'. -Generating RTLIL representation for module `\GTPE2_COMMON'. -Generating RTLIL representation for module `\GTXE2_CHANNEL'. -Generating RTLIL representation for module `\GTXE2_COMMON'. -Generating RTLIL representation for module `\IBUFDS_GTE2'. -Generating RTLIL representation for module `\GTHE3_CHANNEL'. -Generating RTLIL representation for module `\GTHE3_COMMON'. -Generating RTLIL representation for module `\GTHE4_CHANNEL'. -Generating RTLIL representation for module `\GTHE4_COMMON'. -Generating RTLIL representation for module `\GTYE3_CHANNEL'. -Generating RTLIL representation for module `\GTYE3_COMMON'. -Generating RTLIL representation for module `\GTYE4_CHANNEL'. -Generating RTLIL representation for module `\GTYE4_COMMON'. -Generating RTLIL representation for module `\IBUFDS_GTE3'. -Generating RTLIL representation for module `\IBUFDS_GTE4'. -Generating RTLIL representation for module `\OBUFDS_GTE3'. -Generating RTLIL representation for module `\OBUFDS_GTE3_ADV'. -Generating RTLIL representation for module `\OBUFDS_GTE4'. -Generating RTLIL representation for module `\OBUFDS_GTE4_ADV'. -Generating RTLIL representation for module `\PCIE_A1'. -Generating RTLIL representation for module `\PCIE_EP'. -Generating RTLIL representation for module `\PCIE_2_0'. -Generating RTLIL representation for module `\PCIE_2_1'. -Generating RTLIL representation for module `\PCIE_3_0'. -Generating RTLIL representation for module `\PCIE_3_1'. -Generating RTLIL representation for module `\PCIE40E4'. -Generating RTLIL representation for module `\EMAC'. -Generating RTLIL representation for module `\TEMAC'. -Generating RTLIL representation for module `\TEMAC_SINGLE'. -Generating RTLIL representation for module `\CMAC'. -Generating RTLIL representation for module `\CMACE4'. -Generating RTLIL representation for module `\PPC405_ADV'. -Generating RTLIL representation for module `\PPC440'. -Generating RTLIL representation for module `\MCB'. -Generating RTLIL representation for module `\PS7'. -Generating RTLIL representation for module `\PS8'. -Generating RTLIL representation for module `\ILKN'. -Generating RTLIL representation for module `\ILKNE4'. -Successfully finished Verilog frontend. - -9.3. Executing HIERARCHY pass (managing design hierarchy). - -9.3.1. Analyzing design hierarchy.. -Top module: \block_ram - -9.3.2. Analyzing design hierarchy.. -Top module: \block_ram -Removing unused module `\distributed_ram'. -Removing unused module `\distributed_ram_manual'. -Removing unused module `\distributed_ram_manual_syn'. -Removed 3 unused modules. - -9.4. Executing PROC pass (convert processes to netlists). - -9.4.1. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Cleaned up 0 empty switches. - -9.4.2. Executing PROC_RMDEAD pass (remove dead branches from decision trees). -Removed a total of 0 dead cases. - -9.4.3. Executing PROC_PRUNE pass (remove redundant assignments in processes). -Removed 0 redundant assignments. -Promoted 0 assignments to connections. - -9.4.4. Executing PROC_INIT pass (extract init attributes). - -9.4.5. Executing PROC_ARST pass (detect async resets in processes). - -9.4.6. Executing PROC_MUX pass (convert decision trees to multiplexers). - -9.4.7. Executing PROC_DLATCH pass (convert process syncs to latches). - -9.4.8. Executing PROC_DFF pass (convert process syncs to FFs). - -9.4.9. Executing PROC_CLEAN pass (remove empty switches from decision trees). -Cleaned up 0 empty switches. - -9.5. Executing TRIBUF pass. - -9.6. Executing DEMINOUT pass (demote inout ports to input or output). - -9.7. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -9.8. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -9.9. Executing CHECK pass (checking for obvious problems). -checking module block_ram.. -found and reported 0 problems. - -9.10. Executing OPT pass (performing simple optimizations). - -9.10.1. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -9.10.2. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -9.10.3. Executing OPT_MUXTREE pass (detect dead branches in mux trees). -Running muxtree optimizer on module \block_ram.. - Creating internal representation of mux trees. - Evaluating internal representation of mux trees. - Analyzing evaluation results. -Removed 0 multiplexer ports. - - -9.10.4. Executing OPT_REDUCE pass (consolidate $*mux and $reduce_* inputs). - Optimizing cells in module \block_ram. -Performed a total of 0 changes. - -9.10.5. Executing OPT_MERGE pass (detect identical cells). -Finding identical cells in module `\block_ram'. -Removed a total of 0 cells. - -9.10.6. Executing OPT_RMDFF pass (remove dff with constant values). - -9.10.7. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. - -9.10.8. Executing OPT_EXPR pass (perform const folding). -Optimizing module block_ram. - -9.10.9. Finished OPT passes. (There is nothing left to do.) - -9.11. Executing WREDUCE pass (reducing word size of cells). -Removed cell block_ram.$procmux$469 ($mux). -Removed cell block_ram.$procmux$467 ($mux). - -9.12. Executing PEEPOPT pass (run peephole optimizers). - -9.13. Executing OPT_CLEAN pass (remove unused cells and wires). -Finding unused cells or wires in module \block_ram.. -Removed 0 unused cells and 2 unused wires. - - -9.14. Executing PMUX2SHIFTX pass. - -9.15. Executing TECHMAP pass (map to technology primitives). - -9.15.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/cmp2lut.v' to AST representation. -Generating RTLIL representation for module `\_90_lut_cmp_'. -Successfully finished Verilog frontend. - -9.15.2. Continuing TECHMAP pass. -No more expansions possible. - -9.16. Executing MEMORY_DFF pass (merging $dff cells to $memrd and $memwr). - -9.17. Executing TECHMAP pass (map to technology primitives). - -9.17.1. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/mul2dsp.v' to AST representation. -Generating RTLIL representation for module `\_80_mul'. -Generating RTLIL representation for module `\_90_soft_mul'. -Successfully finished Verilog frontend. - -9.17.2. Executing Verilog-2005 frontend: /opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v -Parsing Verilog input from `/opt/eda/fpga/FOSS/memattr/yosys_release/share/xilinx/xc7_dsp_map.v' to AST representation. -Generating RTLIL representation for module `\$__MUL25X18'. -Successfully finished Verilog frontend. - -9.17.3. Continuing TECHMAP pass. -No more expansions possible. - -9.18. Executing OPT_EXPR pass (perform const folding). - -9.19. Executing WREDUCE pass (reducing word size of cells). - -9.20. Executing XILINX_DSP pass (pack resources into DSPs). - -9.21. Executing ALUMACC pass (create $alu and $macc cells). -Extracting $alu and $macc cells in module block_ram: - created 0 $alu and 0 $macc cells. - -9.22. Executing SHARE pass (SAT-based resource sharing). From 87e21b0122bd682db8aeffae3e1ac503c9cea2d2 Mon Sep 17 00:00:00 2001 From: Diego H Date: Mon, 16 Dec 2019 10:23:45 -0600 Subject: [PATCH 4/4] Fixing compiler warning/issues. Moving test script to the correct place --- passes/memory/memory_bram.cc | 16 ++++++++-------- .../attributes_test.ys | 12 ++++++------ 2 files changed, 14 insertions(+), 14 deletions(-) rename tests/arch/{common/memory_attributes => xilinx}/attributes_test.ys (81%) diff --git a/passes/memory/memory_bram.cc b/passes/memory/memory_bram.cc index 10b48e321..703e87f05 100644 --- a/passes/memory/memory_bram.cc +++ b/passes/memory/memory_bram.cc @@ -821,8 +821,8 @@ grow_read_ports:; log(" Updated properties: dups=%d waste=%d efficiency=%d\n", match_properties["dups"], match_properties["waste"], match_properties["efficiency"]); - for (auto& iter: match.attr_match) { - for (auto& iter: iter.second) { + for (auto iter: match.attr_match) { + for (auto iter: iter.second) { auto it = cell->attributes.find(iter.first); if (iter.second.empty()) { @@ -1124,8 +1124,8 @@ void handle_cell(Cell *cell, const rules_t &rules) goto next_match_rule; } - for (auto& iter: match.attr_match) { - for (auto& iter: iter.second) { + for (auto iter: match.attr_match) { + for (auto iter: iter.second) { auto it = cell->attributes.find(iter.first); if (it != cell->attributes.end()) { @@ -1149,10 +1149,10 @@ void handle_cell(Cell *cell, const rules_t &rules) if (!it->second.empty()) { if (it->second.decode_string().length() == 1) it->second = it->second.as_string().back(); - if (!it->second.decode_string().compare(iter.second.decode_string())) - goto next_match_rule; - log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", - log_id(match.name), log_id(iter.first), iter.second.decode_string().c_str()); + if (!it->second.decode_string().compare(iter.second.decode_string())) + goto next_match_rule; + log(" Rule for bram type %s is rejected: requirement 'attribute %s=\"%s\"' not met.\n", + log_id(match.name), log_id(iter.first), iter.second.decode_string().c_str()); } } } diff --git a/tests/arch/common/memory_attributes/attributes_test.ys b/tests/arch/xilinx/attributes_test.ys similarity index 81% rename from tests/arch/common/memory_attributes/attributes_test.ys rename to tests/arch/xilinx/attributes_test.ys index 4e06a35e7..4c881b280 100644 --- a/tests/arch/common/memory_attributes/attributes_test.ys +++ b/tests/arch/xilinx/attributes_test.ys @@ -1,5 +1,5 @@ # Check that blockram memory without parameters is not modified -read_verilog attributes_test.v +read_verilog ../common/memory_attributes/attributes_test.v hierarchy -top block_ram synth_xilinx -top block_ram cd block_ram # Constrain all select calls below inside the top module @@ -7,7 +7,7 @@ select -assert-count 1 t:RAMB18E1 # Check that distributed memory without parameters is not modified design -reset -read_verilog attributes_test.v +read_verilog ../common/memory_attributes/attributes_test.v hierarchy -top distributed_ram synth_xilinx -top distributed_ram cd distributed_ram # Constrain all select calls below inside the top module @@ -15,7 +15,7 @@ select -assert-count 8 t:RAM32X1D # Set ram_style distributed to blockram memory; will be implemented as distributed design -reset -read_verilog attributes_test.v +read_verilog ../common/memory_attributes/attributes_test.v prep setattr -mod -set ram_style "distributed" block_ram synth_xilinx -top block_ram @@ -24,7 +24,7 @@ select -assert-count 32 t:RAM128X1D # Set synthesis, logic_block to blockram memory; will be implemented as distributed design -reset -read_verilog attributes_test.v +read_verilog ../common/memory_attributes/attributes_test.v prep setattr -mod -set logic_block 1 block_ram synth_xilinx -top block_ram @@ -34,14 +34,14 @@ select -assert-count 32 t:RAM128X1D # Set ram_style block to a distributed memory; will be implemented as blockram design -reset -read_verilog attributes_test.v +read_verilog ../common/memory_attributes/attributes_test.v synth_xilinx -top distributed_ram_manual cd distributed_ram_manual # Constrain all select calls below inside the top module select -assert-count 1 t:RAMB18E1 # Set synthesis, ram_block block to a distributed memory; will be implemented as blockram design -reset -read_verilog attributes_test.v +read_verilog ../common/memory_attributes/attributes_test.v synth_xilinx -top distributed_ram_manual_syn cd distributed_ram_manual_syn # Constrain all select calls below inside the top module select -assert-count 1 t:RAMB18E1