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writememory

Write data to AXI4 memory-mapped subordinates

    Description

    writememory(mem,addr,data) writes all words specified in data, starting from the address specified in addr and then incrementing the address for each word. The address, addr, must refer to an AXI subordinate memory location controlled by the AXI manager IP on your FPGA board. The AXI manager object, mem, manages the connection between MATLAB® and the AXI manager IP.

    example

    writememory(mem,addr,data,Name,Value) specifies options using one or more name-value arguments.

    Examples

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    This example shows how to read and write the memory locations on an Intel® FPGA board from MATLAB®.

    Before you can use this example, you must have a design running on an FPGA board connected to the MATLAB host machine. The FPGA design must include an AXI manager IP that is customized for your FPGA vendor. The support package installation includes this IP. To include the IP in your project, see the Access FPGA External Memory Using AXI Manager example.

    Create an AXI manager object. The object connects MATLAB with the FPGA board and confirms that the IP is present.

    mem = aximanager('Intel')
    
    mem =
    
       aximanager with properties:
                Vendor: 'Intel'
         JTAGCableName: 'auto'

    Write 10 addresses and then read data from a single location. By default, these functions auto-increment the address for each word of data.

    writememory(mem,140,[10:19]);
    rd_d = readmemory(mem,140,1)
    
    rd_d =
    
       uint32
        10

    Read data from 10 locations.

    rd_d = readmemory(mem,140,10)
    
    rd_d =
    
       1x10 uint32 row vector
        10   11   12   13   14   15   16   17   18   19

    Read data 10 times from the same address by specifying that the AXI manager read all data from the same address (disabling auto-incrementation).

    rd_d = readmemory(mem,140,10,'BurstType','Fixed')
    
    rd_d =
    
       1x10 uint32 row vector
        10   10   10   10   10   10   10   10   10   10

    Write data 10 times to the same address. In this case, the final value stored in address 140 is 29.

    writememory(mem,140,[20:29],'BurstType','Fixed');
    rd_d = readmemory(mem,140,10)
    
    rd_d =
    
       1x10 uint32 row vector
        29   11   12   13   14   15   16   17   18   19

    Specify the address as a hexadecimal value. Specify for the function to cast the read data to a data type other than uint32.

    writememory(mem,0x1c,[0:4:64]);
    rd_d = readmemory(mem,0x1c,16,'OutputDataType',numerictype(0,6,4))
    
    rd_d =
    
       Columns 1 through 10
              0    0.2500    0.5000    0.7500    1.0000    1.2500 ...
                             1.5000    1.7500    2.0000    2.2500
       Columns 11 through 16
         2.5000    2.7500    3.0000    3.2500    3.5000    3.7500
               DataTypeMode: Fixed-point: binary point scaling
                 Signedness: Unsigned
                 WordLength: 6
             FractionLength: 4

    When you no longer need to access the board, release the JTAG connection.

    release(mem);
    

    This example shows how to read and write the memory locations on an AMD® FPGA board from MATLAB®.

    Before you can use this example, you must have a design running on an FPGA board connected to the MATLAB host machine. The FPGA design must include an AXI manager IP that is customized for your FPGA vendor. The support package installation includes this IP. To include the IP in your project, see the Access FPGA Memory Using JTAG-Based AXI Manager example.

    Create an AXI manager object. The object connects MATLAB with the FPGA board and confirms that the IP is present.

    mem = aximanager('AMD')
    
    mem =
    
       aximanager with properties:
                Vendor: 'AMD'
         JTAGCableName: 'auto'

    Write 10 addresses and then read data from a single location. By default, these functions auto-increment the address for each word of data.

    writememory(mem,140,[10:19]);
    rd_d = readmemory(mem,140,1)
    
    rd_d =
    
       uint32
        10

    Read data from 10 locations.

    rd_d = readmemory(mem,140,10)
    
    rd_d =
    
       1x10 uint32 row vector
        10   11   12   13   14   15   16   17   18   19

    Read data 10 times from the same address by specifying that the AXI manager read all data from the same address (disabling auto-incrementation).

    rd_d = readmemory(mem,140,10,'BurstType','Fixed')
    
    rd_d =
    
       1x10 uint32 row vector
        10   10   10   10   10   10   10   10   10   10

    Write data 10 times to the same address. In this case, the final value stored in address 140 is 29.

    writememory(mem,140,[20:29],'BurstType','Fixed');
    rd_d = readmemory(mem,140,10)
    
    rd_d =
    
       1x10 uint32 row vector
        29   11   12   13   14   15   16   17   18   19

    Specify the address as a hexadecimal value. Specify for the function to cast the read data to a data type other than uint32.

    writememory(mem,0x1c,[0:4:64]);
    rd_d = readmemory(mem,0x1c,16,'OutputDataType',numerictype(0,6,4))
    
    rd_d =
    
       Columns 1 through 10
              0    0.2500    0.5000    0.7500    1.0000    1.2500 ...
                             1.5000    1.7500    2.0000    2.2500
       Columns 11 through 16
         2.5000    2.7500    3.0000    3.2500    3.5000    3.7500
               DataTypeMode: Fixed-point: binary point scaling
                 Signedness: Unsigned
                 WordLength: 6
             FractionLength: 4

    When you no longer need to access the board, release the JTAG connection.

    release(mem);
    

    Input Arguments

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    Connection to the AXI manager IP on your FPGA board, specified as an aximanager object.

    Starting address for the write operation, specified as a nonnegative integer multiple of 4 or hexadecimal value multiple of 4. The function supports the address width of 32, 40, and 64 bits. The function casts the address to the uint32 or uint64 data type, according to the AXI manager IP address width. The address must refer to an AXI subordinate memory location controlled by the AXI manager IP on your FPGA board.

    Memory-Mapping Guidelines

    • If the AXI manager IP data width is 32 bits, the memory is 4 bytes aligned, and addresses have 4-byte increments (0x0, 0x4, 0x8). In this case, 0x1 is an illegal address and emits an error.

    • If the AXI manager IP data width is 64 bits, the memory is 8 bytes aligned, and addresses have 8-byte increments (0x0, 0x8, 0x10). In this case, 0x1 and 0x4 are illegal and emit errors.

    • If the AXI manager IP data width is 32 bits and you set the 'BurstType' argument to 'Increment', the address has 4-byte increments.

    • If the AXI manager IP data width is 64 bits and you set the 'BurstType' argument to 'Increment', the address has 8-byte increments.

    • If the AXI manager IP data width is 32 bits and the input data is half, the function writes data to the lower 2 bytes and pads the higher 2 bytes with zeros.

    • If the AXI manager IP data width is 64 bits and the input data is half, the function writes data to the lower 2 bytes and pads the higher 6 bytes with zeros.

    • Do not use a 64-bit AXI manager for accessing 32-bit registers.

    Example: 64, specifies a starting address of 64.

    Data Types: uint32 | uint64

    Data words to write, specified as a scalar or vector. By default, the function writes the data to a contiguous address block, incrementing the address for each operation. To disable address incrementation and write each data value to the same location, set the 'BurstType' argument to 'Fixed'.

    Before sending the write request to the FPGA, the function typecasts the input data to the uint32, int32, uint64, or int64 data type. The type conversion follows these rules:

    • If the input data is double, then the data is typecast to int32 or int64, depending on the AXI manager IP data width.

    • If the input data is single, then the data is typecast to uint32 or uint64, depending on the AXI manager IP data width.

    • If the input data is half, then the data is typecast to uint16 and packed to uint32 or uint64, depending on the AXI manager IP data width.

    • If the bit width of the input data type is less than the AXI manager IP data width, then the data is sign-extended to the width of the AXI manager IP data width.

    • If the bit width of the input data type is greater than the AXI manager IP data width, then the data is typecast to int32, uint32, int64, uint64. The data is typecast to match the AXI manager IP data width and the signedness of the original data type.

    • If the input data is a fixed-point data type, then the function writes the stored integer value of the data.

    When you specify a large operation size, such as writing a block of DDR memory, the function automatically breaks the operation into multiple bursts, using the maximum supported burst size of 256 words.

    Example: [1:100] specifies 100 contiguous memory locations.

    Data Types: uint8 | int8 | uint16 | int16 | half | uint32 | int32 | single | uint64 | int64 | double | fi

    Name-Value Arguments

    Specify optional pairs of arguments as Name1=Value1,...,NameN=ValueN, where Name is the argument name and Value is the corresponding value. Name-value arguments must appear after other arguments, but the order of the pairs does not matter.

    Before R2021a, use commas to separate each name and value, and enclose Name in quotes.

    Example: 'BurstType','Fixed' directs the AXI manager to write all data to the same address.

    AXI4 burst type, specified as one of these options:

    • 'Increment' — The AXI manager writes a vector of data to contiguous memory spaces, starting with the specified address.

    • 'Fixed' — The AXI manager writes all data to the same address.

    Note

    The 'Fixed' burst type is not supported for the PCI Express® interface. Use the 'Increment' burst type instead.

    Version History

    Introduced in R2017a

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