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Top 5 books to refer for a VHDL beginner

VHDL (VHSIC-HDL, Very High-Speed Integrated Circuit Hardware Description Language) is a hardware description language used in electronic des...

Tuesday, 25 September 2012

DesignWare DDR4 Memory Interface IP from Synopsys

Highlights:

  • Synopsys expands its industry-leading DesignWare® DDR Memory Interface IP family to include support for DDR4 SDRAMs
  • Backward compatibility with DDR3 and LPDDR2/3 mobile SDRAMs gives SoC designers flexibility as they transition from one SDRAM standard to the next
  • New DDR4 IP offers more features with up to 50 percent lower latency than the previous generation
  • DDR4 memory controller and PHY are connected by a standard DFI 3.1 interface to streamline connections to custom PHYs and controllers

Synopsys, Inc. (SNPS), a world leader in software and IP used in the design, verification and manufacture of electronic components and systems, today announced the expansion of its DesignWare DDR interface IP portfolio to include support for next-generation SDRAMs based on the emerging DDR4 standard. By supporting DDR4 as well as DDR3 and LPDDR2/3 in a single core, the DesignWare DDR solution enables designers to interface with either high-performance or low-power SDRAMs in the same system-on-chip (SoC), which is a key requirement of many SoCs such as applications processors for smartphones and tablets.

"Synopsys' support for DDR4 memory is an important contribution to building a robust DDR4 ecosystem," said Robert Feurle, vice president of DRAM marketing for Micron Technology, Inc. "DDR4 brings substantial power and performance benefits to the industry, and Micron is aggressively driving its introduction. By implementing their DesignWare DDR Interface IP with backward compatibility in mind, Synopsys is enabling chip developers to bridge the transition from today's DDR3-based SoCs to the upcoming DDR4 designs."

Synopsys' DesignWare DDR4 IP solution consists of the DDR4 multiPHY and Enhanced Universal DDR Memory Controller (uMCTL2) that connect through a commonly used DFI 3.1 interface. The new DDR4 IP supports all key DDR4 features planned for the upcoming JEDEC standard and, compared to the previous version, includes a 13 percent increase in raw bandwidth, up to a 50 percent reduction in overall latency and new low-power features that provide intelligent system monitoring and control to power down elements of the IP as determined by the system's traffic patterns. Real-time scheduling features in Synopsys' unique CAM-based DDR controller can optimize the scheduling of data read/write traffic from multiple hosts, maximizing performance and minimizing latency.

"While the initial target markets for DDR4 are networking, server, and compute platforms, engineers designing for digital TVs, set-top-boxes, multi-function printing, smartphone and tablet applications will also adopt DDR4 DRAM as prices drop and performance improves," said Desi Rhoden, executive vice president, Montage Technology, and JEDEC memory chairman. "Synopsys has leveraged their participation at JEDEC to develop DDR4-compatible products before the actual standard has been released, which is a key benefit of JEDEC membership."

"Synopsys' complete DDR interface IP portfolio includes support for LPDDR, LPDDR2, LPDDR3, DDR, DDR2, and DDR3," said John Koeter, vice president of marketing for IP and systems at Synopsys. "With this announcement, we are broadening our portfolio to include support for DDR4 while maintaining backward compatibility with existing JEDEC standard SDRAMs. As new DDR standards evolve, designers look for reliable solutions. Synopsys' track record of over 320 DDR IP design wins demonstrates that we offer a low-risk path to silicon success."

Availability for the DesignWare DDR4 multiPHY and uMCTL2 with support for DDR4 is planned for Q4 2012.

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Sunday, 23 September 2012

Smartphone is next stop for PCI Express

PCI Express, the I/O backbone of PCs and servers, is getting a low-power extension that will take it into Ultrabooks, tablets and smartphones starting next year. The enhanced interconnect will draw two to four times less power while helping mobile devices link to high-performance peripherals such as 60-GHz wireless networking controllers and solid-state drives.

The PCI Special Interest Group expects to approve by the end of the year a new version of its low level software for PCIe 3.0. The code will run on the M-PHY physical layer chips defined by the MIPI Alliance that creates handset interfaces.

Click here to read more ...

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Saturday, 22 September 2012

Callback in System Verilog

    Callback is one of the major confusing point for a System Verilog learner. Many people have asked the same question in many forums, but the answer doesn't seems to satisfy fully the quest of the person who has raised the querry. I too had the same issue, but I learned it slowly in a hard way. I am presenting here a way in which if I had an answer, I would have learned faster.

    We can pass data member to any function. Now consider a case where you are passing a function (say func1) as a data member to another function (say func2) and you get what is called callback. The reason why it is called callback is that the function func2 now can call anywhere in its code function func1.

    In computer programming, a callback is executable code that is passed as an argument to other code. It allows a lower-level software layer to call a subroutine (or function) defined in a higher-level layer.

    Note that SV doesn't give a straight-forward way of passing a function as argument for another function. But we can get the same result (almost we can say!) by using OOP. The idea is to describe all the functions (both func1 type and func2 type) in a base class (don't implement the funct2 kind of function and make them virtual for polymorphism), and then extend the class to a derived class where you implement the func2 type of function.

    Example:-

    class abc_transactor;

    virtual task pre_send(); endtask

    virtual task post_send(); endtask

    task xyz();

    // Some code here

    this.pre_send();

    // Some more code here

    this.post_send();

    // And some more code here

    endtask : xyz

    endclass : abc_transactor

    class my_abc_transactor extend abc_transactor;

    virtual task pre_send();

    ... // This function is implemented here

    endtask

    virtual task post_send();

    ... // This function is implemented here

    endtask

    endclass : my_abc_transactor

    Now let me explain how it is going to work. The base class abc_transactor has 3 tasks, 2 of which are declared virtual and are not implemented. But they are being called from another task xyz() which is fully implemented. The unimplemented virtual task are called callback class.

    The child class, which extends from the base class, implements the previous unimplemented tasks. It inherits the xyz() task from the base class and hence doesn't need to change it. By this we can inject executable code to a function without modifying it.

    Now the next question is why is done. There are many reasons for it.

  1. The biggest advantage is that you can modify the behavior of task xyz() without modifying it in the base or child class. It is a big advantage as no one wants to fiddle with known good functioning code.

  2. Consider a case where you are writing a base class which is going to be used by multiple test environment, and for each test environment a known part of the code, or a known function/task is going to change. The natural choice is to implement those change-in-every-case functions/tasks as callback method and let the user extend your base class with specifying only that part of the code which need to be changed in his case.

    1.  

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Wednesday, 19 September 2012

Programming FPGAs with Python

py For everyone who wants to get started with developing for FPGA’s and dont want to waste time in learning a new programming  language or they just want to use their current knowledge of programming with Python to program an FPGA, this tool is just made for you!

The Python Hardware Processsor is written in Myhdl which makes it possible to run a very small subset of python on an FPGA, it converts a very simple Python code into either VHDL or Verilog and then a hardware description can be uploaded to the FPGA:

“Due to the python nature of Myhdl and the Python Hardware Prozessor written with it, it allows you, to write a Programm for the prozessor, to simulate the Hardware Processor and to convert the Processor to a valid hardware description (VHDL or Verilog) inside a single python environment.”

MyHDL surely won’t replace VHDL or Verilog but it could be a great tool for simulation and to test the behavior of your design and it’s certainly a tool worth looking into if you want to jump into the world of FPGAs.

Feel free to discuss in the comments thread.

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Monday, 17 September 2012

Draw AND gate using XOR gates only

Hi friends….

Do any one know how to design an AND gate using XOR gate.?

This was a good question for discussion among me and my friends during graduation. At last solution was quite impressive. I thought i would be good to discuss it here also as I had found this question is interviews for freshers.

Please let us know your comments and views.

Is it really possible to design AND gate using XOR gate.?
If yes, then HOW?
If no, then WHY?

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Monday, 10 September 2012

Verilog language reference manual LRM

Verilog was started initially as a proprietary hardware modeling language by Gateway Design Automation Inc. around 1984. It is rumored that the original language was designed by taking features from the most popular HDL language of the time, called HiLo, as well as from traditional computer languages such as C. At that time, Verilog was not standardized and the language modified itself in almost all the revisions that came out within 1984 to 1990.

Verilog simulator was first used beginning in 1985 and was extended substantially through 1987. The implementation was the Verilog simulator sold by Gateway. The first major extension was Verilog-XL, which added a few features and implemented the infamous "XL algorithm" which was a very efficient method for doing gate-level simulation.

The time was late 1990. Cadence Design System, whose primary product at that time included Thin film process simulator, decided to acquire Gateway Automation System. Along with other Gateway products, Cadence now became the owner of the Verilog language, and continued to market Verilog as both a language and a simulator. At the same time, Synopsys was marketing the top-down design methodology, using Verilog. This was a powerful combination.

In 1990, Cadence recognized that if Verilog remained a closed language, the pressures of standardization would eventually cause the industry to shift to VHDL. Consequently, Cadence organized the Open Verilog International (OVI), and in 1991 gave it the documentation for the Verilog Hardware Description Language. This was the event which "opened" the language.

OVI did a considerable amount of work to improve the Language Reference Manual (LRM), clarifying things and making the language specification as vendor-independent as possible.

Soon it was realized that if there were too many companies in the market for Verilog, potentially everybody would like to do what Gateway had done so far - changing the language for their own benefit. This would defeat the main purpose of releasing the language to public domain. As a result in 1994, the IEEE 1364 working group was formed to turn the OVI LRM into an IEEE standard. This effort was concluded with a successful ballot in 1995, and Verilog became an IEEE standard in December 1995.

When Cadence gave OVI the LRM, several companies began working on Verilog simulators. In 1992, the first of these were announced, and by 1993 there were several Verilog simulators available from companies other than Cadence. The most successful of these was VCS, the Verilog Compiled Simulator, from Chronologic Simulation. This was a true compiler as opposed to an interpreter, which is what Verilog-XL was. As a result, compile time was substantial, but simulation execution speed was much faster.

In the meantime, the popularity of Verilog and PLI was rising exponentially. Verilog as a HDL found more admirers than well-formed and federally funded VHDL. It was only a matter of time before people in OVI realized the need of a more universally accepted standard. Accordingly, the board of directors of OVI requested IEEE to form a working committee for establishing Verilog as an IEEE standard. The working committee 1364 was formed in mid 1993 and on October 14, 1993, it had its first meeting.

The standard, which combined both the Verilog language syntax and the PLI in a single volume, was passed in May 1995 and now known as IEEE Std. 1364-1995.

After many years, new features have been added to Verilog, and the new version is called Verilog 2001. This version seems to have fixed a lot of problems that Verilog 1995 had. This version is called 1364-2001.

Timeline:

1984 Verilog-XL simulator and language developed by Gateway Design Automation
1987 Synopsys introduced a Verilog based synthesis tool.
1989 Cadence Design Systems acquired Gateway, and Verilog.
1990 Cadence placed the Verilog language in the public domain.
1995 Verilog HDL became (IEEE Std 1364-1995).
1997 Verilog VCS bought by Viewlogic
1997 Viewlogic bought by Synopsys
1998 Synopsys issues Verilog VCS
2001 A significantly revised version was published in 2001.

DOWNLOAD VERIOG LRM

Intel Is Cooling Entire Servers By Submerging Them in Oil

originalAir cooled computers are for wimps. But while the idea of keeping temperatures in check using water might be a step in the right direction, Intel is doing something even more radical: it's dunking entire servers—the whole lot—into oil to keep them chill.

Don't panic, though: they're using mineral oil, which doesn't conduct electricity. It's a pretty wacky idea, but it seems to be working. After a year of testing with Green Revolution Cooling, Intel has observed some of the best efficiency ratings it's ever seen. Probably most impressive is that immersion in the oil doesn't seem to affect hardware reliability.

All up, it's extremely promising: completely immersing components in liquid means you can pack components in more tightly as the cooling is so much more efficient. For now, though, it's probably best to avoid filling your computer case with liquid of any kind.



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Sunday, 9 September 2012

Vectors

Formal Definition

Vectors are multiple bit widths net or reg data type variables that can be declared by specifying their range.

Simplified Syntax

net_type [msb:lsb] list_of_net_identifiers;

reg [msb:lsb] list_of_register_identifiers;

Description

Vector range specification contains two constant expressions: the msb (most significant bit) constant expression, which is the left-hand value of the range and the lsb (least significant bit) constant expression, which is the right-hand value of the range. The msb and lsb constant expressions should be separated by a colon.

Both the msb constant expression and the lsb constant expression can be any value - positive, negative, or zero. The lsb constant expression can be greater, equal or less than the msb constant expression.

Vectors can be declared for all types of net data types and for reg data types. Specifying vectors for integer, real, realtime, and time data types is illegal.

Vector nets and registers are treated as unsigned values (see: Arithmetic expressions with registers and integers for more explanations).

Examples

Example 1

reg [3:0] addr;

The 'addr' variable is a 4-bit vector register made up of addr[3] (the most significant bit), addr[2], addr[1], and addr[0] (the least significant bit).

Example 2

wire [-3:4] d;

The d variable is 8-bit vector net made up of d[-3] (msb), d[-2], d[-1], d[0], d[1], d[2], d[3], d[4] (lsb).

Example 3

tri [5:0] x, y, z;

The above line declares three 6-bit vectors.

Important Notes

  • Both the msb and the lsb expressions should be constant expressions.
  • The msb and the lsb constant expressions may be positive, negative, or zero.
  • The lsb constant expression may be greater, equal or less than the msb constant expression.
  • Vectors can be declared only for nets and reg data types.
  • Vector declaration for integer, real, realtime, and time data types are illegal.

Value Change Dump (VCD) File

Formal Definition

The Value change dump (VCD) file contains information about any value changes on the selected variables.

Simplified Syntax

$dumpfile(name)

$dumpvars

$dumpvars(level, list_of_variables_or_modules)

$dumpoff

$dumpon

$dumpall

$dumplimit

$dumpflush

Description

$dumpfile(filename)

This task is used to specify the VCD file name. The filename parameter is optional. If it is not given, then the file will be named "Verilog.dump”.

$dumpvars(level, list_of_variables_or_modules)

This task is used to specify which variables should be dumped. Both parameters are optional and if none are used, then all variables will be dumped.

If level = 0, then all variables within the modules from the list will be dumped. If any module from the list contains module instances, then all variables from these modules will also be dumped.

If level = 1, then only listed variables and variables of listed modules will be dumped.

$dumpoff

This task stops the dumping of variables. All variables are dumped with x value and all next changes of variables will not be dumped.

$dumpon

This task starts previously stopped dumping of variables.

$dumpall

When this task is used, then the current value of all dumped variables will be written to file.

$dumplimit(filesize)

This task can set the maximum size of the VCD file.

$dumpflush

This task can be used to make sure that all changes of dumped variables are written to file.

Examples

module top;
reg a, b;
wire y;
assign y = a & b;
always begin
  a = 1'b0;
  #10;
  a = 1'b1;
  #10;
  a = 1'bx;
  #10;
end
always begin
  b = 1'b0;
  #30;
  b = 1'b1;
  #30;
  b = 1'bx;
  #30;
end
initial begin
  $dumpfile("test.txt");
  $dumpvars(1,a,y);
  #200;
  $dumpoff;
  #200;
  $dumpon;
  #20;
  $dumpall;
  #10;
  $dumpflush;
end
endmodule

The dumpfile will contain only changes of 'a' and 'y' variables. After 200 time units, dumping will be suspended for 200 time units. Next, dumping will start again and after 20 time units, all variables will be dumped.

Important Notes

  • Value change dump file can be used for hierarchical monitoring of all signal changes within design modules.


UDP State Table

Formal Definition

A UDP state table defines the behavior of UDP.

Simplified Syntax

table

  comb_input comb_input ... comb_input : output;

  seq_input seq_input ... seq_input : current_state : next_state;

endtable

Description

Each row of the state table defines the behavior of the UDP for a specific input combination. Each combination of inputs can be given only one time. It is illegal to define the same combination of inputs for different outputs.

The number of input values must match the number of UDP inputs in a port declaration.

The UDP state table for combinational and sequential UDPs is different. The combinational UDPs (Example 1) contain two fields: an input field and an output field. The sequential UDPs (Example 2) contain three fields: an input, a current state, and the next state (output) field.

The input field should contain a list of values (separated by white spaces), which should match the number of UDP input ports. The order of these ports is highly important. The first input port on the UDP port list matches the first input value in each row.

The rows of the state table can contain only 0, 1, unknown (x) value, and special characters. The high-impedance (z) value cannot be specified. The special characters are provided to increase readability of a description and to make it easier (Example 3).

Symbol

Interpretation

Comments

0

Logic 0

 

1

Logic 1

 

x

Unknown value

Not permitted in output field.

b

Substitute for 0 and 1

Not permitted in output field.

?

Substitute for 0, 1, and x

Not permitted in output field.

-

No change

Permitted only in output field of sequential UDPs.

(vw)

Transition from v to w value

Permitted only in input field of sequential UDPs. v and w can be 0, 1, x, b, and ?

*

Same as (??)

Any value change on input. Permitted only in input field of sequential UDPs.

r

Same as (01)

Rising edge on input. Permitted only in input field of sequential UDPs.

f

Same as (10)

Falling edge on input. Permitted only in input field of sequential UDPs.

p

Same as (01), (0x), (x1)

Positive edge on input. Permitted only in input field of sequential UDPs.

n

Same as (10), (1x), (x0)

Negative edge on input. Permitted only in input field of sequential UDPs.

Table 25: Summary of symbols

If some combinations of input signal values are not specified in a UDP state tables then the output value will be unknown (x).

Only one transition can appear in each row of sequential UDPs.

Examples

Example 1

primitive mux (o, i3, i2, i1, i0, a1, a0);

output o;
input i3, i2, i1, i0, a1, a0;
table
// i3 i2 i1 i0 a1 a0 : o;
0 ? ? ? 1 1 : 0;
1 ? ? ? 1 1 : 1;
? 0 ? ? 1 0 : 0;
? 1 ? ? 1 0 : 1;
? ? 0 ? 0 1 : 0;
? ? 1 ? 0 1 : 1;
? ? ? 0 0 0 : 0;
? ? ? 1 0 0 : 1;
endtable
endprimitive

If any address bit (a1, a0) is unknown, then the output value will be unknown (because there is no row which describes the output value for this combination of address signals).

If a1 = 0 and a0 = 0 then the signal from input i0 is driven to output (value of others inputs does not matter).

If a1 = 0 and a0 = 1 then signal from input i1 is driven to the output.

If a1 = 1 and a0 = 0 then signal from input i2 is driven to the output.

If a1 = 1 and a0 = 1 then signal from input i3 is driven to the output.

Example 2

primitive special_d_ff (q, clk, m, d, rst, set);
output q;
reg q;
input clk, m, d, rst, set;
table
// clk m d rst set : current : next;
// positive edge on clk and normal mode (m = 0)
(01) 0 0 0 0 : ? : 0 ; // line 1
(0x) 0 0 0 0 : ? : 0 ; // line 2
(x1) 0 0 0 0 : ? : 0 ; // line 3
(01) 0 1 0 0 : ? : 1 ; // line 4
(0x) 0 1 0 0 : ? : 1 ; // line 5
(x1) 0 1 0 0 : ? : 1 ; // line 6
// positive edge on clk and negation mode (m = 1)
p 1 ? 0 0 : 0 : 1 ; // line 7
p 1 ? 0 0 : 1 : 0 ; // line 8
// negative edge on clk and any mode (m = 0 or m = 1)
n ? ? 0 0 : ? : - ; // line 9
// reset
? ? ? 1 ? : ? : 0 ; // line 10
// preset
? ? ? 0 1 : ? : 1 ; // line 11
// any changes on inputs with no changes on clk
? * ? ? ? : ? : - ; // line 12
? ? * ? ? : ? : - ; // line 13
? ? ? * ? : ? : - ; // line 14
? ? ? ? * : ? : - ; // line 15
endtable
endprimitive

This is 'd' flip-flop with an additional input, which can convert it into a modulo 2 counter.

If m = 0 then this UDP works as a normal 'd' flip-flop (lines 1-6), but if m = 1 then it negates its current value (lines 7 and 8). If any falling edge occurs on the clk input, then it will not change the output (line 9). If rst is 1, then the output will go to 0 (line 10). If the rst is 0 and set is 1, then the output will go to 1 (line 11 - it means that rst has higher priority than set).

Any changes on the data input will not cause any changes on output (lines 12-15).

Example 3

primitive circuit_1 (o, i1, i2, i3);
output o;
input i1, i2, i3;
table
0 0 0 : 1 ;
0 0 1 : 1 ;
0 0 x : 1 ;
0 1 0 : 1 ;
0 1 1 : 1 ;
0 1 x : 1 ;
1 0 0 : 0 ;
1 0 1 : 0 ;
1 0 x : 0 ;
1 1 0 : 1 ;
1 1 1 : 1 ;
1 1 x : 1 ;
x 0 0 : 0 ;
x 0 1 : 0 ;
x 0 x : 0 ;
x 1 0 : 0 ;
x 1 1 : 0 ;
x 1 x : 0 ;
endtable
endprimitive
primitive circuit_2 (o, i1, i2, i3);
output o;
input i1, i2, i3;
table
0 ? ? : 1 ;
1 0 ? : 0 ;
1 1 ? : 1 ;
x b ? : 0 ;
endtable
endprimitive

'Circuit_1' and 'circit_2' are the same circuit, but the behavior of the 'circuit_1' was specified without special characters.

Important Notes

  • Each row of sequential UDPs can contain only one transition.
  • Special characters can make the UDP state table easier to read and write.
  • Any undefined combination of inputs will set the output to x value.

UDP Instantiation

Formal Definition

The UDP instantiation provides a means of using UDP in modules.

Simplified Syntax

udp_name (strengths) #(delays) instance_name[range] (list of ports);

Description

UDPs can be instantiated only within modules.

The name of an instance is optional (Example 1). A UDP instantiation can contain strength and delays declarations (Example 2). UDPs do not support high-impedance (z) values, therefore only two delays are permitted. Signals connected to input ports can be any net or reg data type. Only net data type variables can be connected to the output port. The strength declaration can contain only drive strength.

It is possible to specify an array of UDP instances by using a range (Example 3).

Examples

Example 1

primitive d_ff (q, clk, d);
...
endprimitive
d_ff (q, clk, d);

The name of an instance is optional.

Example 2

d_ff (weak1, strong0) #5 d1 (q, clk, d);

UDP instance with strength and delay declaration.

Example 3

wire [3:0] q;
reg [3:0] d;
reg clk;
d_ff flips[3:0] (q, clk, d);

Important Notes

· UDP instantiation can contain up to two delay values.


UDP Declaration

Formal Definition

User Defined Primitives (UDP) provide a means of expanding a set of built-in primitives.

Simplified Syntax

primitive udp_name ( port_list );

output output_port;

input list_of_imputs;

initial output_port = value;

table

  combinational_input_list : output_value;

  sequential_input_list : current_state : next_state;

endtable

endprimitive

Description

User Defined Primitives can describe both combinational (Example 1) and sequential (Example 2) circuits. The behavioral description is provided as a truth table.

The UDP declaration starts with the keyword primitive and ends with the keyword endprimitive. A port list, an output port declaration and input ports declaration are similar to their equivalents in a module declaration.

Port list

The port list contains a comma-separated list of primitive ports. There can be only one output port and several input ports. The inout ports are illegal. The first port on the list should be the output port. There are some restrictions concerning the number of input ports. The combinational UDPs list of ports should not contain more than 10 inputs, and the sequential UDPs port list should not contain more than 9 inputs. If the port list contains more inputs, then a warning will be issued. These restrictions are caused by illegibility of written UDPs.

Port declaration

Input and output port declarations should match the port list of the UDP they are enclosed in. If the described UDP is sequential, then reg declaration for output port should be provided. All ports of the UDP should be of scalar type (1-bit wide). Vectors are illegal.

Initial statement

Sequential UDPs can contain an initial statement for an output port. This statement begins with the keyword initial, followed by an assignment to the output port. Assigned values should be 1-bit wide and there must not be any delays.

State table

The state table starts with the keyword table and ends with the keyword endtable. The state tables for combinational and sequential UDPs are different. The state table is comprised of rows each of which ended with a the semicolon. Table row describes the behavior of UDP for a particular combination of inputs. The combinational UDPs have two fields separated by a colon. One field is for the inputs and one for the outputs. The sequential UDPs have three fields: one for the inputs, one for the current output state, and one for the next output state. If any combination of input signals, is not explicitly specified in the UDP declaration, the output value will be unknown (x). A particular combination of inputs can be specified only one time.

Examples

Example 1

primitive and_gate (o, in1, in2);
output o;
input in1, in2;
table
  // in1 in2 : o
  0 0 : 0;
  0 1 : 0;
  1 0 : 0;
  1 1 : 1;
endtable
endprimitive

Example of simple combinational UDP based on the and gate truth table.

Example 2

primitive d_ff (q, d, clk);
output q;
reg q;
input d, clk;
table
  // d clk : q : q+
  0 p : ? : 0;
  1 p : ? : 1;
  ? n : ? : -;
endtable
endprimitive

Example of sequential UDP based on a D flip-flop.

Important Notes

· UDP can have only one output.

· Inout ports are illegal.

· Combinational UDP should not have more than 10 inputs.

· Sequential UDP should not have more than 9 inputs.

· Vector declaration for UDP ports is illegal.


Timing Check Tasks


Formal Definition

Timing Check Tasks are for verification of timing properties of designs and for reporting timing violations.

Simplified Syntax

$setup (data_event, reference_event, limit[, notifier]) ;

$skew (reference_event, data_event, limit[,notifier]) ;

$hold (reference_event, data_event, limit[,notifier]) ;

$recovery (reference_event, data_event, limit, [notifier]) ;

$setuphold (reference_event, data_event, setup_limit, hold_limit, [notifier]) ;

$width (reference_event, limit, threshold [,notifier]) ;

$period (reference_event, limit[,notifier]) ;

$nochange (reference_event, data_event, start_edge_offset, end_edge_offset [,notifier]) ;

Description

Timing check tasks are invoked every time critical events occur within given time limits. See the table below with descriptions of all arguments:

Argument

Description

Type

Reference_event

The transition at a control signal that establishes the reference time for tracking timing violations on the data_event

Module input or inout that is scalar or vector net

Data_event

The signal change that initiates the timing check and is monitored for violations.

Module input or inout that is scalar or vector net

Limit

A time limit used to detect timing violations on the data_event

Constant expression or specparam

Threshold

The largest pulse width that is ignored by the timing check $width

Constant expression or specparam

Setup_limit

A time limit used to detect timing violations on the data_event for $setup.

Constant expression or specparam

Hold_limit

A time limit used to detect timing violations on the data_event for $hold.

Constant expression or specparam

Notifier

An optional argument that "notifies" the simulator when a timing violation occurs

Register

$setup checks setup time. When modeling synchronous circuits, flip-flops need time to force a correct value. Data cannot change within the setup time because flip-flops cannot detect the new value. If data changes within a given time limit, $setup reports a timing violation. If a data event and reference event occur at the same time there is no violation. The$setup first checks timing data then records a new data value. The formula to report a timing violation is as shown below:

(time of reference event) - (time of data event) < limit

Notice that the limit argument has to be a positive number.

$skew checks the following:

(time of data event) - (time of reference event) > limit

$skew can be used to check synchronicity of clocks inside a circuit. If different clocks are used in a design and are synchronized, $skew will report a timing violation when the active edge of one of them occurs outside the time limit allowed for the other clock to occur.

When the data event and the reference event occur at the same time, $skew will not report a timing violation.

$hold will report a timing violation if the following formula is true:

(time of data event) - (time of reference event) < limit

$hold simply checks that data is stable in the specified interval of time after the edge of the clock. In flip-flops, data should remain stable for a given time after the active edge of the clock to allow for propagation of data.

Also, a violation will be reported if the data event and the reference event occur at the same time.

$recovery responds when the following formula is true:

(time of data event) - (time of reference event) < limit

The 'reference_event' must be an edge-triggered event: posedge or negedge. A timing violation occurs if the time interval between an edge-triggered reference event and a data event exceeds the 'limit'. If a reference event and data event occur at the same time, a timing violation is reported. If a 'reference_event' argument is specified without edge specification, an error is reported.

$setuphold checks setup and hold timing violations. This task combines the functionality of $setup and $hold in one task. The following formula has to be applied:

setup_limit + hold_limit > 0

'reference_event' have to be one of the following:

  1. $hold lower bound event
  2. $setup upper bound event

'data_event' have to be one of the following:

  1. $hold upper bound event
  2. $setup lower bound event

In $width both limit and threshold have to be positive numbers. The 'reference_event' must be the edge specification, otherwise an error will be reported. The 'data_event' is not specified directly, but by default means 'reference_event' with opposite edge. A timing violation occurs with the following formula:

threshold < (time of data event) - (time of reference event) < limit

$width reports when width of the active-edge is too small. In FF case it is very important to ensure that the width of an active-edge is sufficient and FF will work properly.

The $period checks that a period of signal is sufficiently long. The reference_event has to be an edge specification. The data_event is not specified directly and by default, is the same as a reference_event. The $period reports a timing violation when the following formula comes true:

(time of data event) - (time of reference event) < limit

The $nochange checks if the data signal is stable in an interval of start_edge_offset and end_edge_offset. If the signal has changed, a timing violation is reported. The reference_event argument can be posedge or negedge but the edge control specifiers are disallowed.

Examples

Example 1

module setup (data1, data2, q);
input data1, data2;
output q;
and (q, data1, data2);
specify
specparam tsetup = 7, delay = 10 ;
(data1 => q) = 10 ;
$setup(data1, posedge data2, tsetup);
endspecify
endmodule

Example 2

module two_clocks (clk1, clk2, q);
input clk1, clk2;
output q;
specify
  specparam tskew = 7;
  $skew(posedge clk1, posedge clk2, tskew);
endspecify
endmodule

Example 3

module hold (data1, data2, q);
input data1, data2;
output q;
and (q, data1, data2);
specify
specparam thold = 7, delay = 10 ;
(data1 => q) = 10 ;
$hold(posedge data2, data1, thold);
endspecify
endmodule

Example 4

module recovery (in1, out1);
input in1 ;
output out1 ;
assign out1 = in1 ? 1'b1 : 1'bz ;
specify
  specparam trecovery = 10;
  $recovery(posedge in1, out1, trecovery);
endspecify
endmodule

Example 5

module setuphold (data1, data2, q);
input data1, data2;
output q;
and (q, data1, data2);
specify
specparam tsetup = 7,
thold = 7,
delay = 10 ;
(data1 => q) = 10 ;
$setuphold(posedge data2, data1, tsetup, thold);
endspecify
endmodule

Example 6

module width (data1, data2, q);
input data1, data2;
output q;
and (q, data1, data2);
specify
specparam twidth = 10,
delay = 10 ;
(data2 => q) = 10 ;
$width(posedge data2, twidth);
endspecify
endmodule

Example 7

module dff (clk, q);
input clk;
output q;
buf (q, clk);
specify
  specparam tperiod = 100 ;
  $period(posedge clk, tperiod);
endspecify
endmodule

Example 8

module nochange (data1, data2, q);
input data1, data2;
output q;
and (q, data1, data2);
specify
specparam tstart = -5,
tend = 5 ;
$nochange(posedge data2, data1, tstart, tend);
endspecify
endmodule

Important Notes

  • All timing check system tasks should be invoked within specify blocks.

Timescale System Tasks

Formal Definition

Timescale system tasks provide a means of setting and printing timescale information.

Simplified Syntax

$printtimescale [(hierarchical_path)] ;

$timeformat [(unit_number, precision, suffix, min_width )] ;

Description

The $printtimeformat system task is used when information about time units and precision is needed. An argument is optional. When the $printtimescale system task is invoked without an argument, the time unit and precision of the current modules are displayed. If an argument is specified, then the time unit and precision of the module specified is displayed in a hierarchical path. The following format is used to display this information:

Time scale of (module) is unit / precision

The $timeformat system task has double functionality.

First, when any delays are entered interactively, it specifies the time unit. Second, it specifies the %t format specification. These format specifications are used in $display, $fdisplay, $write, $fwrite, $strobe, $fstrobe and $monitor, $fmonitor system tasks.

The first argument of $timeformat system task should be an integer.

Unit

Time

Unit

Time

0

1 s

-8

10 ns

-1

100 ms

-9

1 ns

-2

10 ms

-10

100 ps

-3

1 ms

-11

10 ps

-4

100 us

-12

1 ps

-5

10 us

-13

100 fs

-6

1 us

-14

10 fs

-7

100 ns

-15

1 fs

Default argument values are given in the following table:

Argument

Value

Unit

The smallest time precision argument of all the `timescale compiler directives in the source description

Precision

0

Suffix

Null

Minimum width

20

Examples

Example 1

`timescale 1 ns / 100 ps
module a (y, a, b);
  output y;
  input a, b;
  assign y = a & b;
endmodule
`timescale 1 s / 10 fs
module top;
  wire y, a, b;
  a u(y, a, b);
  initial $printtimescale(top.u);
endmodule

Important Notes

  • The $timeformat system task specifies the %t format specification until the next `timescale compiler directive occurs.

initial $timeformat(-9, 5, " ns", 10);
/* $timeformat [ ( n, p, suffix , min_field_width ) ] ;
units = 1 second ** (-n), n = 0->15, e.g. for n = 9, units = ns
p = digits after decimal point for %t e.g. p = 5 gives 0.00000
suffix for %t (despite timescale directive)
min_field_width is number of character positions for %t */


Tasks

Formal Definition

Tasks provide a means of splitting code into small parts. Often tasks consist of frequently used functionalities.

Simplified Syntax

task identifier;

  parameter_declaration;

  input_declaration;

  output_declaration;

  inout_declaration;

  register_declaration;

  event_declaration;

  statement;

endtask

Description

Task definition begins with the keyword task and ends with the keyword endtask. A task should be followed by a task identifier and end with a semicolon. A task can contain a declaration of parameters, input arguments, output arguments, inout arguments, registers and events (these declarations are similar to module items declaration) but they are not required. Net declaration is illegal.

A task can contain zero or more behavioral statements, e.g. case statement, if statement. A begin-end block is required for bracketing multiple statements.

The task enabling statement should be made up of a task identifier and the list of comma-separated task arguments. The list of task arguments should be enclosed in parenthesis. If the task does not contain any argument declarations, then it should be enabled by specifying its identifier followed by a semicolon (Example 2).

The list of task enabling arguments should correspond exactly to the list of task arguments. If a task argument is declared as an input, then a corresponding argument of the task enabling statement can be any expression. If a task argument is declared as an output or an inout then the corresponding argument of the task enabling statement should be one of the following items:

  • Register data types
  • Memory references
  • Concatenations of registers or memory references
  • Bit-selects and part-selects of reg, integer and time registers

Only the last assignment to an output or an inout argument is passed to the corresponding task enabling arguments. If a task has assignments to global variables, then all changes of these variables are effective immediately.

Tasks can enable others tasks (Example 3) and functions. A task may be enabled several times in a module. If one task is enabled concurrently, then all registers and events declared in that task should be static, i.e., one variable for all instances.

A task can contain time-controlling statements. A task does not return a value by its name.

Examples

Example 1

task first_task;
  parameter size = 4;
  input a;
  integer a;
  inout [size-1:0] b;
  output c;
  reg [size-1:0] d;
  event e;
begin
  d = b;
  c = |d;
  b = ~b;
if (!a) -> e;
  end
endtask

This is an example of using parameters, input arguments, inout arguments, output arguments, registers and events within tasks. The 'a' argument is declared as an input and as an integer data type.

'First_task' can be enabled as follows:

integer x;
reg a, b, y;
reg [3:0] z;
reg [7:0] w;
first_task(x, z, y);
first_task(x, w[7:4], w[1]);
first_task(1, {a, b, w[3], x[0]}, y);

When being enabled, the first argument of the 'first_task' should be an integer data type expression, the second should be a 4-bit register expression, and the last argument should be 1-bit register expression.

Example 2

reg a, b;
task my_task; // task definition
begin
  a = 1'b1;
  b = 1'bx;
end
endtask
my_task; // task enabling

If 'my_task' is enabled then it will change the value of global variables 'a' and 'b'.

Example 3

task negation;
  inout data;
  data = ~data;
endtask
task my_nor;
  input a, b;
  output c;
  begin
  negation(a);
  negation(b);
  c = a & b;
  end
endtask

The 'my_nor' task enables negation tasks.

Important Notes

  • A task can contain time-controlling statements
  • A task does not return any value by its name

Structured Procedures

Formal Definition

Structured procedures provide a means of modeling blocks of procedural statements.

Simplified Syntax

always statement

initial statement

function

task

Description

Functions and tasks are described in the section: Task and Functions.

The initial statement (Example 1) is executed only during a simulation run. The always procedural block statement (Example 2) is executed continuously during simulation, i.e. when the flow of program reaches the last statement in the block, the flow continues with the first statement in the block.

The always statement should contain at least one procedural timing control because otherwise it may hang the simulation.

Module definition can contain more than one initial or always statement.

Care must be taken when same reg type variables are used in multiple procedural blocks, initial or always. This is because these blocks run in parallel and changing or assigning to one variable affects the same variable in another parallel block.

Examples

Example 1

initial out = 1'b0;
initial begin
  #10;
  a = 1'b0;
  #10;
  a = 1'b1;
  #10;
  a = 1'bz;
end

Example 2

always @(posedge clk)
q = d;
always #10 clk = ~clk;
initial clk = 0;
initial repeat(20)#\10 clk=~clk;

The first initial statement sets clk to 0 at time 0, and the second initial block toggles the clk 20 times every 10 time units.

Important Notes

· The always statement should contain at least one procedural timing control.


Strings

Formal Definition

The strings are sequences of 8-bit ASCII characters enclosed within quotation marks.

Simplified Syntax

"This is a string"

reg [8*number_of_characters:1] string_variable;

Description

The string should be given in one line. Strings can contain special characters (Example 1).

Character

Meaning

\n

New line character

\t

Tab character

\\

\ character

\”

" character

\ddd

A character specified by octal digit

Table 24: Summary of special characters

String variables should be declared as reg type vectors (Example 2). Each character needs 8 bits.

If a string variable is used in an expression, it should be treated as an unsigned value. If the size of a string assigned to a string variable is smaller than the declared size of the variable, then it will be left-padded with zeros.

The null string "” should be treated same as "\0”.

Concatenations of string variables preserve left-padded zeros of these variables (Example 3).

Examples

Example 1

"\n This is the first line\n This is the second line"
"\t Line\t with\t tab\t characters"

Example 2

reg [8*12:1] message;

The message variable can contain 12 characters.

Example 3

reg [10*8:1] s1, s2;
s1 = "Verilog";
s2 = "-HDL";
{s1, s2} <> {"Verilog", "-HDL"}

These expressions are not equal because {s1, s2} has 0s between "Verilog” and "-HDL” and {"Verilog”, "-HDL”} does not have any 0s between words.

Important Notes

  • Concatenation of string variables preserves left-padded zeros of these variables.

Strengths

Formal Definition

The strength declaration construct is used for modeling net type variables for a close correspondence with physical wires.

Simplified Syntax

(Strength1, Strength0)
(Strength0, Strength1)
Strength1:
supply1, strong1, pull1, large1, weak1, medium1, small1, highz1
Strength0:
supply0, strong0, pull0, large0, weak0, medium0, small0, highz0

Description

Strengths can be used to resolve which value should appear on a net or gate output.

There are two types of strengths: drive strengths (Example 1) and charge strengths (Example 2). The drive strengths can be used for nets (except trireg net), gates, and UDPs. The charge strengths can be used only for trireg nets. The drive strength types are supply, strong, pull, weak, and highz strengths. The charge strength types are large, mediumand small strengths.

All strengths can be ordered by their value. The supply strength is the strongest and the highz strength is the weakest strength level. Strength value can be displayed by system tasks ($display, $monitor - by using of the %v characters - see Display tasks for more explanation).

Strength

Value

Value displayed by display tasks

supply

7

Su

strong

6

St

pull

5

Pu

large

4

La

weak

3

We

medium

2

Me

small

1

Sm

highz

0

HiZ

Table 23 Strengths ordered by value

If two or more drivers drive a signal then it will have the value of the strongest driver (Example 3).

If two drivers of a net have the same strength and value, then the net result will have the same value and strength (Example 4).

If two drivers of a net have the same strength but different values then signal value will be unknown and it will have the same strength as both drivers (Example 5).

If one of the drivers of a net has an H or L value, then signal value will be n1n2X, where n1 is the strength value of the driver that has the smaller strength, and n2 is strength value of driver that has the larger strength (Example 6).

The combinations (highz0, highz1) and (highz1, highz0) are illegal.

Examples

Example 1

and (strong1, weak0) b(o, i1, i2);

Instance of and gate with strong1 strength and weak0 strength specified.

Example 2

trireg (medium) t;

The charge strength declaration for trireg net.

Example 3

buf (strong1, weak0) g1 (y, a);
buf (pull1, supply0) g2 (y, b);

If a = 0 and b = 0 then y will be 0 with supply strength because both gates will set y to 0 and supply (7) strength has bigger value than weak (3) strength.

If a = 0 and b = 1 then y will be 1 with pull strength because g1 will set y to 0 with weak (3) strength and g2 will set y to 1 with pull (5) strength (pull strength is stronger than the weak strength).

If a = 1 and b = 0 then y will be 0 with supply strength because g1 will set y to 1 with strong (6) strength and g2 will set y to 0 with supply (7) strength (supply strength is stronger than the strong strength).

If a = 1 and b = 1 then y will be 1 with strong strength because g1 will set y to 1 with strong (6) strength and g2 will set y to 1 with pull (5) strength.

Example 4

buf (strong1, weak0) g1 (y, a);
buf (strong1, weak0) g1 (y, b);

If a = 0 and b = 0 then y will be 0 with weak strength.

If a = 1 and b = 1 then y will be 1 with strong strength.

Example 5

buf (strong1, weak0) g1 (y, a);
buf (weak1, strong0) g1 (y, b);

If a = 1 and b = 0 then y will be x with strong strength.

Example 6

bufif0 (strong1, weak0) g1 (y, i1, ctrl);
bufif0 (strong1, weak0) g2 (y, i2, ctrl);

If ctrl = x, i1 = 0, and i2 = 1 then y will be x with 36X strength, because g1 will set y to L with strong strength (StL - 6) and g2 will set y to H with weak strength (WeH - 3).

Important Notes

  • If one of the drivers has an H or L value, then the output value will be X.

Module Instantiation


Stochastic Analysis Tasks

Formal Definition

Stochastic analysis tasks provide a means of managing queues.

Simplified Syntax

$q_initialize(identifier, type, length, status) ;
$q_add(identifier, job, information, status) ;
$q_remove(identifiers, job, information, status) ;
$q_full(identifier, status) ;
$q_exam(identifier, statistic_code, statistic_value, status) ;

Description

All statistic analysis tasks include identifier, and status arguments. The identifier is a unique integer value identifying the queue. The status argument is an output integer parameter giving information about the correctness of the specified task execution.

Status

Message

0

The queue generation was successful.

1

The queue cannot be increased; queue is full.

2

The identifier is undefined; please define an identifier.

3

Cannot remove a value; queue is empty.

4

The queue cannot be generated; this type is unsupported.

5

The length parameter is <= 0; the queue cannot be generated.

6

The identifier is duplicated; please define new identifier.

7

The queue cannot be generated; insufficient memory.

$q_initialize creates a queue. Parameter type determines the type of a queue. In case of 1, the created queue is FIFO and in case of 2 the queue is LIFO. Parameter length is an integer value specifying the maximum number of entries.

$q_add adds a new entry to the queue. Parameter job identifies the job. The special user-defined parameter, information, can maintain any information useful for the user.

$q_remove receives data from the queue. Parameters of this task are the same as those of the $q_add task.

$q_full checks to see of the queue identified by the identifier parameter is full.

$q_exam returns statistical information about the queue. Parameter statistic_code determines what you need to check and returns the result in statistic_value. The following table lists all possible values of statistic_code:

Statistic_code

Statistic_value

1

Length of queue.

2

Mean interarrival time.

3

Maximum length of queue.

4

Shortest wait time.

5

Longest wait time for jobs still in the queue.

6

Average wait time in the queue.

Examples

Example 1

always @(posedge clk)
begin
// check if queue1 is full
$q_full(queue1, status);
// if full then show message and remove one item
if (status) begin
  $display("Queue is full”);
  $q_remove(queue1, 1, info, status);
end
// add a new item to queue1
$q_add(queue1, 1, info, status);
// show message if there was an error
if (status)
  $display("Error %d”,status);
end
end

This example shows how to add a new element to the queues.

Important Notes

  • The status parameter value should be checked after all operations on the queue.

Specify Block

Formal Definition

Allows a specific delay across a module.

Simplified Syntax

specify

  specparam declaration ;

  path declaration ;

  system timing check ;

endspecify

Description

The Specify block was designed to define a delay across a module. It starts with specify and ends with the endspecify keyword. Inside the block the user can specify: specparamdeclaration, path declaration or system timing check.

The syntax of specparam declaration is the same as that of the parameter declaration. After the specparam keyword the user can specify any number of parameters but only constant expressions are allowed on the right-hand sides of parameter assignments. A comma can separate the assignments, and the last statement ends with a semicolon. A previously declared specparameter can be used to declare the new specparameters. Unlike parameters, specparams cannot be overwritten, nor can they be used outside of a specify block.

Examples

Example 1

module ...
...
specify
  (In => Out) = (10);
endspecify
...
endmodule

A specify block with only a path declaration. Delay between input In and output Out is 10 time units.

Example 2

module ...
...
specify
  specparam TRise = 10,
  TFall = 15;
  (In => Out) = (TRise, TFall) ;
endspecify
...
endmodule

Specparam declaration with two parameters TRise and TFall to specify delays on rising transition and falling transition.

Example 3

module ...
...
specify
  specparam TRise = 10,
  TFall = 15;
  (In => Out) = (TRise, TFall) ;
  $setup(Data_in, posedge Clock, TRise) ;
endspecify
...
endmodule

The full specify block with specparam declaration, path declaration and system timing check task.

Important Notes

· Specify blocks have to be inside the module declaration location.

· Specparams are not visible outside of the Specify blocks.

· The defparam keyword cannot be used to override a specparam value.


State Dependent Path

Formal Definition

State Dependent Path is a path that occurs only when the condition is met.

Simplified Syntax

if (condition) simple_module_path;

if (condition) edge_sensitive_path;

ifnone simple_module_path;

Description

Generally, state dependent path is comprised of three parts. A condition that enables the module path, a module path description and a delay that applies to the module path.

The condition is an expression using scalars or vectors of any type. It can also be part-selects or bit-selects of a vector. Constant numbers and specparams can be used in the condition expression. The result of the conditional expression can be one bit or multiple bits. If it is more than one bit, the least significant bit represents the result.

When no edge transition is specified for the inputs, it is called the simple state-dependent path. Example 1 shows the simple-dependent path.

If any edge transition is specified for the input, then it is called an edge-sensitive state-dependent path. Different delays can be used to the same path if the following rules are followed:

a. A declaration must be unique and should use an edge or a conditional expression or both.

b. The port for which the delay is specified must be referenced in exactly the same way. You cannot mix part select, bit-select and complete ports.

Examples

Example 1

module example1 (cond, in_1, in_2, out);
input in_1, in_2, cond ;
output out ;
and (out, in_1, in_2) ;
specify
  specparam TRise1 = 5,
  TFall1 = 5,
  TRise2 = 7,
  TFall2 = 7;
  if (cond) ( in_1, in_2 *> out ) = (TRise1, TFall1);
  if (~cond) ( in_1, in_2 *> out ) = (TRise2, TFall2);
endspecify
endmodule

If a conditional expression 'cond' is true, TRise1 and TFall1 will be assigned to a path as delays. When the conditional expression 'cond' is false, TRise2 and TFall2 will be used as the path delays.

Important Notes

· When a conditional expression evaluates to x or z, it should be treated as true.


Simulation Time Functions

Formal Definition

The simulation time function provides an access to current simulation time.

Simplified Syntax

$time ;

$stime ;

$realtime ;

Description

When the $time system function is called, it returns the current time as a 64-bit integer value. However, this value is scaled to the `timescale unit. (See Timescale chapter)

The $stime system function returns current time as a 32-bit unsigned integer value. If the current simulation time is too large and the value does not fit in 32 bits, the function only returns the 32 low order bits of the value. The returned value is also scaled to the `timescale.

The $realtime system function returns a value as a real number. As with the other time tasks, the returned value is scaled to the `timescale.

Examples

Example 1

integer cur_time ;
cur_time = $time ;

Example 2

integer cur_time ;
cur_time = $stime ;

Example 3

real cur_time ;
cur_time = $realtime ;

Example 4

$display($time, "is current time.");

Important Notes

· $time, $stime, $realtime are functions which return specific values. If you are using these functions you have to declare registers that can support the returned value.