# How to declare and use 1D and 2D byte arrays in Verilog?

How to declare and use 1D and 2D byte arrays in Verilog?

eg. how to do something like

``````byte a_2D[3][3];
byte a_1D[3];

// using 1D
for (int i=0; i< 3; i++)
{
a_1D[i] = (byte)i;
}

// using 2D
for (int i=0; i< 3; i++)
{
for (int j=0; j< 3; j++)
{
a_2D[i][j] = (byte)i*j;
}
}
``````
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Verilog thinks in bits, so `reg [7:0] a[0:3]` will give you a 4x8 bit array (=4x1 byte array). You get the first byte out of this with `a[0]`. The third bit of the 2nd byte is `a[1][2]`.

For a 2D array of bytes, first check your simulator/compiler. Older versions (pre '01, I believe) won't support this. Then `reg [7:0] a [0:3] [0:3]` will give you a 2D array of bytes. A single bit can be accessed with `a[2][0][7]` for example.

``````reg [7:0] a [0:3];
reg [7:0] b [0:3] [0:3];

reg [7:0] c;
reg d;

initial begin

for (int i=0; i<=3; i++) begin
a[i] = i[7:0];
end

c = a[0];
d = a[1][2];

// using 2D
for (int i=0; i<=3; i++)
for (int j=0; j<=3; j++)
b[i][j] = i*j;  // watch this if you're building hardware

end
``````
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Don't the for loops need to be <= 3 rather than < 3? – Ross Aiken May 11 at 23:44

In addition to Marty's excellent Answer, the SystemVerilog specification offers the `byte` data type. The following declares a 4x8-bit variable (4 bytes), assigns each byte a value, then displays all values:

``````module tb;

byte b [4];

initial begin
foreach (b[i]) b[i] = 1 << i;
foreach (b[i]) \$display("Address = %0d, Data = %b", i, b[i]);
\$finish;
end

endmodule
``````

This prints out:

``````Address = 0, Data = 00000001
Address = 1, Data = 00000010
Address = 2, Data = 00000100
Address = 3, Data = 00001000
``````

This is similar in concept to Marty's `reg [7:0] a [0:3];`. However, `byte` is a 2-state data type (0 and 1), but `reg` is 4-state (01xz). Using `byte` also requires your tool chain (simulator, synthesizer, etc.) to support this SystemVerilog syntax. Note also the more compact `foreach (b[i])` loop syntax.

The SystemVerilog specification supports a wide variety of multi-dimensional array types. The LRM can explain them better than I can; refer to IEEE Std 1800-2005, chapter 5.

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