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Презентация была опубликована 9 лет назад пользователемАнтон Баркалов
1 Verilog - Gate and Switch Level Modeling - Ando KI Spring 2009
2 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 2 ) Contents Prerequisites Levels of abstraction Levels of modeling Built-in gates and switches Variable input/output logic gates Buffers and tri-state buffers MOS switches Bidirectional pass switch Pullup and pulldown Gate delay Examples UDP Form of UDP UDP table Combinational UDP example Sequential UDP example
3 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 3 ) Levels of abstraction Structural levels Switch level Referring to the ability to describe the circuit as a netlist of transistor switches. Gate level Referring to the ability to describe the circuit as a netlist of primitive logic gates and functions. Functional levels Register transfer level Referring to the ability to describe the circuit as data assignment. Behavioral level Referring to the ability to describe the behavior of circuit using abstract constructs such as loops and processes. reg Combinati onal logic block
4 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 4 ) Levels of modeling Analog-transistor level Uses an electronic model of circuit elements such as resistor, capacitor, and inductor. Allows analog values of voltages or currents to represent logic values on the interconnections. Switch level Describes the interconnection of transmission gates which are abstractions of individual MOS and CMOS transistors. Logic level Describes a digital circuit in terms of primitive logic functions such as AND, OR, NAND, and NOR. Allows for the nets interconnecting the logic functions to carry 0, 1, x, and z.
5 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 5 ) Built-in gates and switches
6 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 6 ) Variable input/output logic gates The gates (and, nand, nor, or, xor, xnor) shall have one output and one or more inputs. The first terminal shall be output. and Uand (out, in1, in2); or Uor (out, in1, in2, in3);
7 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 7 ) Buffers Multiple output logic gates buf: simply bypass not: inverter buf Ubuf (out1, in); buf Ubuf (out1, out2, in);
8 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 8 ) Tri-state buffers Tri-state buffer gates bufif0: buffer with active low control bufif1: buffer with active high control notif1: inverter buffer with active high control notif0: inverter buffer with active low control bufif1 Ubf1 (out, in, control);
9 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 9 ) MOS switches MOS switches are unidirectional channels for data similar to the buff gates. Normal MOS pmos nmos cmos Resistive MOS It has significantly higher impedances between sources and drains when it conduct than pmos/nmos. rpmos rnmos rcmos pmos Up (out, data, control); nmos Un (out, data, control); cmos Uc (out, data, ncon, pcon); pmosnmos ncon pcon dataout cmos control
10 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 10 ) Bidirectional pass switch tran, rtan tranif1, rtranif1 tranif0, rtranif0 These pass switch shall not delay signals propagating through them. However, these can have turn-on and turn-off delays. tran (inout1, inout2); tranif1 (inout1, inout2, control);
11 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 11 ) Pullup and pulldown sources A pullup source shall place a logic value 1 on the nets connected in its terminal list. A pulldown source shall place a logic value 0 on the nets connected in its terminal list. pullup Up1 (net1); pulldonw Ud1 (net2); pmos nmos gnd vdd
12 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 12 ) Gate delay The gate delay specification can be zero, one, two, or three delays. If there is no delay specification, there shall be no propagation delay through the gate. and Uand(out, in1, in2); If there is one delay specification, it shall apply to both the rise and fall delay. and #(3) Uand(out, in1, in2); If there are two delays, the first specifies rise delay and the second specifies fall delay. and #(3, 5) Uand(out, in1, in2); If there are three delays, the last one is for turn-off delay. Logic gates do not have the third delay. Buffer gates can have this. Rise time Fall time 0 or X or Z 1 or X or Z 0 1 #(1st delay[, 2nd delay[, 3 rd delay]]) The first delay: rise delay The second delay: fall delay The third delay: turn-off delay The transition to the high-impedances value. Each delay can be min:typ:max values and #(1:2:3,2:1:3) U(y, x, z);
13 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 13 ) Gate instantiation GateType is one of and, or, …, buf, …. ListOfGateInstances is a comma- separated list which specifies the terminals of each gate and optionally names each instance. delay will be #(r, f, t) form, where rise, fall, and transition (or turn-off). strength specifies strength of driving, such as supply, strong, pull, and weak. GateType [strength] [delay] ListOfGateInstances; and UA (out, in1, in2); and UB (out1, in1, in2); Note there are no instance name. and UC (out1, in1, in2), UD (out2, in1, in2); and (out3, in1, in2, in3), (out4, in1, in2); Note comma separation
14 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 14 ) Example of gate delay (1/2) codes/verilog/gate_switch/gate_delay `timescale 1ns/1ns module top; reg in1, in2; wire out1, out2, out3; xor UxorA (out1, in1, in2); xor #(2) UxorB (out2, in1, in2); xor #(3, 4) UxorC (out3, in1, in2); initial begin in1 = 0; in2 = 0; #5; in1 = 1; in2 = 0; #10; in1 = 0; in2 = 1; #10; in1 = 1; in2 = 1; #10; in1 = 0; in2 = 0; #5; $finish; end initial begin $dumpfile("wave.vcd"); $dumpvars(1, in1, in2, out1, out2, out3); end endmodule DIY
15 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 15 ) Example of gate delay (2/2) codes/verilog/gate_switch/buf_delay `timescale 1ns/1ns module top; reg in, con; wire out; bufif1 #(1, 3, 2) Ub (out, in, con); // r, f, t initial begin con = 0; #2; in = 0; #5; con = 1; #5; con = 0; #5; con = 1; #5; in = 1; #5; con = 0; #5; con = 1; #5; in = 0; #5; con = 0; #5; con = 1; #5; $finish; end initial begin $dumpfile("wave.vcd"); $dumpvars(1, in, out, con); end endmodule f tr DIY
16 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 16 ) `timescale 1ns/1ns module top; reg d, clk; wire q, qb; initial begin clk = 0; forever #5 clk = ~clk; end initial begin d = 0; #7; d = 1; #10; d = 0; #10; d = 1; #10; d = 0; #10; $finish; end dff Udff (q, qb, d, clk); endmodule module dff (q, qb, d, clk); output q, qb; input d, clk; wire x, y; nand #1 U1 (q, x, qb); nand #1 U2 (qb, q, y); nand #1 U3 (x, d, clk); nand #1 U4 (y, x, clk); initial begin $dumpfile("wave.vcd"); $dumpvars(1, clk, d, q, qb); $dumpvars(1, x, y); end endmodule Example of gate-level model Guess what will happen if the NAND gates have no delay. codes/verilog/gate_switch/dff_gate DIY
17 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 17 ) Example of switching-level model `timescale 1ns/1ns module top; reg in; wire out; inverter Uinv (out, in); initial begin in = 0; #10; in = 1; #15; in = 0; #20; in = 1; #5 $finish; end initial begin $dumpfile("wave.vcd"); $dumpvars(1, out, in); end endmodule module inverter (out, in); output out; input in; // supply1 vdd; supply0 gnd; // pmos Upmos (out, vdd, in); nmos Unmos (out, gnd, in); endmodule in vdd gnd out = ~in pmos nmos codes/verilog/gate_switch/ inverter_switch DIY
18 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 18 ) Example of pullup/pulldown (1/2) `timescale 1ns/1ns module top; … … endmodule module inverter (out, in); output out; input in; // supply1 vdd; supply0 gnd; // pmos #(1) Upmos (out, vdd, in); nmos #(3) Unmos (out, gnd, in); // pullup pu (out); pulldown pd (out); endmodule in vdd gnd out = ~in vdd What causes it. codes/verilog/gate_switch/inverter_pull DIY
19 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 19 ) Example of pullup/pulldown (2/2) `timescale 1ns/1ns module top; reg data, cont; tri resultA, resultB; tri resultPA, resultPB; // without pull-up/down bufif1 Ua (resultA, data, cont); notif0 Ub (resultB, data, cont); // with pull-up/down bufif1 Upa (resultPA, data, cont); notif0 Upb (resultPB, data, cont); pulldown (resultPA); pullup (resultPB); initial begin data = 0; cont = 0; #5 cont = 1; #5 cont = 0; #5 data = 1; #5 cont = 1; #5 cont = 0; #5 $finish; end initial begin $dumpfile("wave.vcd"); $dumpvars(1, data, cont, resultA, resultB); $dumpvars(1, resultPA, resultPB); end endmodule Note Z Note pulled up or down codes/verilog/gate_switch/buf_pull DIY
20 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 20 ) `timescale 1ns/1ns module top; reg data, cont; trireg capA; trireg #(1,2,10) capB; nmos UA(capA, data, cont); nmos UB(capB, data, cont); initial begin data = 1; cont = 0; #5; cont = 1; #10; data = 0; cont = 0; #30; cont = 1; #10 cont = 0; #30; cont = 1; #5 #30 $finish; end initial begin $dumpfile("wave.vcd"); $dumpvars(1, data, cont, capA, capB); end endmodule Charge decay of trireg net trireg #(rise, fall, charge_decay) instance; No decay without charge_decay. After charge_decay time, the trireg net makes a transition from 1 or 0 to X. codes/verilog/gate_switch/charge_decay capdata cont After charge decay No charge decay DIY
21 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 21 ) UDP User-defined primitive Independent module The same level as module definition It can be appear anywhere in the source, either before or after it is instantiated inside a module. It shall not be appear in module definition, i.e., between module and endmodule. Instances of new UDPs can be used in exactly the same manner as the gate primitives. Each UDP has exactly one output. Value of UDP output can be 0, 1, or X. Z is not supported. Z in input will be X in the UDP. Types of UDP Combinational UDP Uses the value of its inputs to determine the next value of its output. Sequential UDP Uses the value of its inputs and the current value of its output to determine the value of its output.
22 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 22 ) Form of UDP UDP has exactly one output port. The output port must come first in the comma-separated list of ports. UDP has none or multiple input ports. Bidirectional port is not permitted. All port shall be scalar. Vector ports are not permitted. Combinational UDP Cannot has reg. Sequential UDP Can have reg declaration for the output port. Can have initial block. It specifies the value of the output port when simulation begins. primitive name_of_UDP (oport [, iport1 [, iport2 [, …]]]); output oport; [reg oport] [input iport1; [input iport2; [input iport3; […]]]] [initial oport = initial_value;] table … endtable endprimitive
23 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 23 ) // UDP table for combinational UDP // iport1 iport2 iport3 … : oport; table : ; endtable UDP table The state table of UDP defines the behavior of a UDP. // UDP table for sequential UDP // iport1 iport2 iport3 … : current_oport : next_oprt; table : : ; endtable
24 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 24 ) Combinational UDP example primitive multiplexer (mux, control, dataA, dataB); output mux; input control, dataA, dataB; table // control dataA dataB mux 01 0 : 1 ; 01 1 : 1 ; 01 x : 1 ; 00 0 : 0 ; 00 1 : 0 ; 00 x : 0 ; 10 1 : 1 ; 11 1 : 1 ; 1x 1 : 1 ; 10 0 : 0 ; 11 0 : 0 ; 1x 0 : 0 ; x0 0 : 0 ; x1 1 : 1 ; endtable endprimitive primitive multiplexer (mux, control, dataA, dataB); output mux; input control, dataA, dataB; table // control dataA dataB mux 01?:1 ; // ? = 0 1 x 00?:0 ; 1?1:1 ; 1?0:0 ; x00:0 ; x11:1; endtable endprimitive ? is 0, 1, and x. 0xx and 1xx are not specified. Thus this will make x for its output when it happens. Output port comes first. control mux dataA dataB 0 1 codes/verilog/gate_switch/udp_mux DIY
25 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 25 ) Sequential UDP examples (1/2) // level-sensitive sequential UDP primitive latch (q, clock, data); output q; reg q; input clock, data; table// clock data qq+ 01 : ? :1 ; 00 : ? :0 ; 1? : ? :- ;// - = no change endtable endprimitive // edge-sensitive sequential UDP primitive d_edge_ff (q, clock, data); output q;reg q; input clock, data; table // clock dataqq+ (01) 0:?:0; // obtain output on rising edge of clock (01) 1:?:1; // obtain output on rising edge of clock (0?) 1:1:1; // obtain output on rising edge of clock (0?) 0:0:0; // obtain output on rising edge of clock (?0) ?:?:-; // ignore negative edge of clock ? (??):?:-; // ignore data changes on steady clock endtable endprimitive (01) Rising edge. (10) Falling edge. (??) Any value change. Note reg. ? is 0, 1, and x. codes/verilog/gate_switch/udp_ff DIY
26 Copyright © by Ando KiIntroduction to Verilog-HDL module ( 26 ) Sequential UDP examples (2/2) primitive dff1 (q, clk, d); input clk, d; output q; reg q; initial q = 1b1; table // clkdqq+ r0:?:0; r1:?:1; f?:?:-; ?*:?:-; endtable endprimitive module dff (q, qb, clk, d); input clk, d; output q, qb; dff1 g1 (qi, clk, d); buf #3 g2 (q, qi); not #5 g3 (qb, qi); endmodule Note initial. * is the same as (??), any value change. Stable signal of clock does not affect the output even input changes. See how to instantiate UDP. codes/verilog/gate_switch/udp_dff DIY
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