www.pudn.com > CPLD_PWM.rar > add_sub_4ph.tdf
--lpm_add_sub CARRY_CHAIN="MANUAL" CARRY_CHAIN_LENGTH=48 DEVICE_FAMILY="MAX7000S" LPM_DIRECTION="ADD" LPM_REPRESENTATION="UNSIGNED" LPM_WIDTH=10 ONE_INPUT_IS_CONSTANT="YES" cin dataa datab result --VERSION_BEGIN 5.0 cbx_cycloneii 2004:12:20:14:28:52:SJ cbx_lpm_add_sub 2005:04:12:13:30:42:SJ cbx_mgl 2005:04:13:17:26:48:SJ cbx_stratix 2005:03:14:17:09:02:SJ cbx_stratixii 2004:12:22:13:27:12:SJ VERSION_END -- Copyright (C) 1988-2005 Altera Corporation -- Your use of Altera Corporation's design tools, logic functions -- and other software and tools, and its AMPP partner logic -- functions, and any output files any of the foregoing -- (including device programming or simulation files), and any -- associated documentation or information are expressly subject -- to the terms and conditions of the Altera Program License -- Subscription Agreement, Altera MegaCore Function License -- Agreement, or other applicable license agreement, including, -- without limitation, that your use is for the sole purpose of -- programming logic devices manufactured by Altera and sold by -- Altera or its authorized distributors. Please refer to the -- applicable agreement for further details. FUNCTION carry_sum (cin, sin) RETURNS ( cout, sout); --synthesis_resources = lut 11 SUBDESIGN add_sub_4ph ( cin : input; dataa[9..0] : input; datab[9..0] : input; result[9..0] : output; ) VARIABLE add_sub_cella[9..0] : carry_sum; external_cin_cell : carry_sum; datab_node[9..0] : WIRE; main_cin_wire : WIRE; BEGIN add_sub_cella[0].cin = ((dataa[0..0] & datab_node[0..0]) # ((dataa[0..0] # datab_node[0..0]) & main_cin_wire)); add_sub_cella[1].cin = ((dataa[1..1] & datab_node[1..1]) # ((dataa[1..1] # datab_node[1..1]) & add_sub_cella[0].cout)); add_sub_cella[2].cin = ((dataa[2..2] & datab_node[2..2]) # ((dataa[2..2] # datab_node[2..2]) & add_sub_cella[1].cout)); add_sub_cella[3].cin = ((dataa[3..3] & datab_node[3..3]) # ((dataa[3..3] # datab_node[3..3]) & add_sub_cella[2].cout)); add_sub_cella[4].cin = ((dataa[4..4] & datab_node[4..4]) # ((dataa[4..4] # datab_node[4..4]) & add_sub_cella[3].cout)); add_sub_cella[5].cin = ((dataa[5..5] & datab_node[5..5]) # ((dataa[5..5] # datab_node[5..5]) & add_sub_cella[4].cout)); add_sub_cella[6].cin = ((dataa[6..6] & datab_node[6..6]) # ((dataa[6..6] # datab_node[6..6]) & add_sub_cella[5].cout)); add_sub_cella[7].cin = ((dataa[7..7] & datab_node[7..7]) # ((dataa[7..7] # datab_node[7..7]) & add_sub_cella[6].cout)); add_sub_cella[8].cin = ((dataa[8..8] & datab_node[8..8]) # ((dataa[8..8] # datab_node[8..8]) & add_sub_cella[7].cout)); add_sub_cella[9].cin = ((dataa[9..9] & datab_node[9..9]) # ((dataa[9..9] # datab_node[9..9]) & add_sub_cella[8].cout)); add_sub_cella[0].sin = ((dataa[0..0] $ datab_node[0..0]) $ main_cin_wire); add_sub_cella[1].sin = ((dataa[1..1] $ datab_node[1..1]) $ add_sub_cella[0].cout); add_sub_cella[2].sin = ((dataa[2..2] $ datab_node[2..2]) $ add_sub_cella[1].cout); add_sub_cella[3].sin = ((dataa[3..3] $ datab_node[3..3]) $ add_sub_cella[2].cout); add_sub_cella[4].sin = ((dataa[4..4] $ datab_node[4..4]) $ add_sub_cella[3].cout); add_sub_cella[5].sin = ((dataa[5..5] $ datab_node[5..5]) $ add_sub_cella[4].cout); add_sub_cella[6].sin = ((dataa[6..6] $ datab_node[6..6]) $ add_sub_cella[5].cout); add_sub_cella[7].sin = ((dataa[7..7] $ datab_node[7..7]) $ add_sub_cella[6].cout); add_sub_cella[8].sin = ((dataa[8..8] $ datab_node[8..8]) $ add_sub_cella[7].cout); add_sub_cella[9].sin = ((dataa[9..9] $ datab_node[9..9]) $ add_sub_cella[8].cout); external_cin_cell.cin = cin; external_cin_cell.sin = B"0"; datab_node[] = datab[]; main_cin_wire = external_cin_cell.cout; result[] = add_sub_cella[].sout; END; --VALID FILE