# Generation 3 USRP Build Documentation

## Dependencies and Requirements

### Dependencies

The USRP FPGA build system requires a UNIX-like environment with the following dependencies

- [Xilinx Vivado 2018.3](https://www.xilinx.com/support/download/index.html/content/xilinx/en/downloadNav/vivado-design-tools/2018-3.html) (For 7 Series FPGAs)
  - AR#71898 Tactical Patch required for USRP N3xx devices. See note below.
- [Xilinx ISE 14.7](http://www.xilinx.com/support/download/index.html/content/xilinx/en/downloadNav/design-tools/v2012_4---14_7.html) (For all other FPGAs)
- [GNU Make 3.6+](https://www.gnu.org/software/make/)
- [GNU Bash 4.0+](https://www.gnu.org/software/bash/)
- [Python 2.7.x](https://www.python.org/)
- [Doxygen](http://www.stack.nl/~dimitri/doxygen/index.html) (Optional: To build the manual)
- [ModelSim](https://www.mentor.com/products/fv/modelsim/) (Optional: For simulation)

The following USRPs work with the free WebPack versions:
- USRP E310/E312/E313

##### NOTE: AR#71898 Tactical Patch for Vivado 2018.3
The DDR3 Memory Interface Generator (MIG) IP in Vivado 2018.3 has a known issue that affects the generation of the IP in USRP N3xx build and produce the following error:
```
ERROR: [DRC BIVC-1] Bank IO standard Vcc: Conflicting Vcc voltages in bank 34. For example, the following two ports in this bank have conflicting VCCOs:  
ddr3_ck_p[0] (DIFF_SSTL15, requiring VCCO=1.500) and ddr3_addr[15] (LVCMOS18, requiring VCCO=1.800)
```
The [AR#71898 Tactical Path](https://www.xilinx.com/support/answers/71898.html) must be installed to successfully build all supported FPGA images.

### What FPGA does my USRP have?

- USRP B200: Spartan 6 XC6SLX75
- USRP B200mini: Spartan 6 XC6SLX75
- USRP B210: Spartan 6 XC6SLX150
- USRP X300: Kintex 7 XC7K325T (7 Series)
- USRP X310: Kintex 7 XC7K410T (7 Series)
- USRP E310: Zynq-7000 XC7Z020 (7 Series)
- USRP E320: Zynq-7000 XC7Z045 (7 Series)
- USRP N300: Zynq-7000 XC7Z035 (7 Series)
- USRP N310/N320: Zynq-7000 XC7Z100 (7 Series)

### Requirements

- [Xilinx Vivado Release Notes](https://www.xilinx.com/support/documentation/sw_manuals/xilinx2018_3/ug973-vivado-release-notes-install-license.pdf)
- [Xilinx ISE Platform Requirements](http://www.xilinx.com/support/documentation/sw_manuals/xilinx14_7/irn.pdf)

## Build Environment Setup

### Download and Install Xilinx Tools

Download and install Xilinx Vivado or Xilinx ISE based on the target USRP.
- The recommended installation directory is `/opt/Xilinx/` for Linux and `C:\Xilinx` in Windows
- Please check the Xilinx Requirements document above for the FPGA technology used by your USRP device.
- You may need to acquire a synthesis and implementation license from Xilinx to build some USRP designs.
- You may need to acquire a simulation license from Xilinx to run some testbenches

### Download and Install ModelSim (Optional)

Download and install Mentor ModelSim using the link above.
- The recommended installation directory is `/opt/mentor/modelsim` for Linux and `C:\mentor\modelsim` in Windows
- Supported versions are PE, DE, SE, DE-64 and SE-64
- You may need to acquire a license from Mentor Graphics to run ModelSim

### Setting up build dependencies on Ubuntu

You can install all the dependencies through the package manager:

    sudo apt-get install python bash build-essential doxygen

Your actual command may differ.

### Setting up build dependencies on Fedora

You can install all the dependencies through the package manager:

    sudo yum -y install python bash make doxygen

Your actual command may differ.

### Setting up build dependencies on Windows (using Cygwin)

**NOTE**: Windows is only supported with Vivado. The build system does not support Xilinx ISE in Windows.

Download the latest version on [Cygwin](https://cygwin.com/install.html) (64-bit is preferred on a 64-bit OS)
and install it using [these instructions](http://x.cygwin.com/docs/ug/setup-cygwin-x-installing.html).
The following additional packages are also required and can be selected in the GUI installer

    python patch patchutils bash make doxygen

## Build Instructions (Xilinx Vivado only)

### Makefile based Builder

- Navigate to `usrp3/top/{project}` where project is:
  + x300: For USRP X300 and USRP X310
  + e31x: For USRP E310
  + e320: For USRP E320
  + n3xx: For USRP N300/N310/N320

- To add vivado to the PATH and to setup up the Ettus Xilinx build environment run
  + `source setupenv.sh` (If Vivado is installed in the default path /opt/Xilinx/Vivado) _OR_
  + `source setupenv.sh --vivado-path=<VIVADO_PATH>` (where VIVADO_PATH is a non-default installation path)

- To build a binary configuration bitstream run `make <target>`
  where the target is specific to each product. To get a list of supported targets run
  `make help`.

- The build output will be specific to the product and will be located in the
  `usrp3/top/{project}/build` directory. Run `make help` for more information.

### Environment Utilies

The build environment also defines many ease-of-use utilites. Please use the \subpage md_usrp3_vivado_env_utils "Vivado Utility Reference" page for
a list and usage information

## Build Instructions (Xilinx ISE only)

### Makefile based Builder

- To add xtclsh to the PATH and to setup up the Xilinx build environment run
  + `source <install_dir>/Xilinx/14.7/ISE_DS/settings64.sh` (64-bit platform)
  + `source <install_dir>/Xilinx/14.7/ISE_DS/settings32.sh` (32-bit platform)

- Navigate to `usrp3/top/{project}` where project is:
  + b200: For USRP B200 and USRP B210
  + b200mini: For USRP B200mini

- To build a binary configuration bitstream run `make <target>`
  where the target is specific to each product. To get a list of supported targets run
  `make help`.

- The build output will be specific to the product and will be located in the
  `usrp3/top/{project}/build` directory. Run `make help` for more information.

## Targets and Outputs

### B2x0 Targets and Outputs

#### Supported Targets
- B200:  Builds the USRP B200 design.
- B210:  Builds the USRP B210 design.

#### Outputs
- `build/usrp_<product>_fpga.bit` : Configuration bitstream with header
- `build/usrp_<product>_fpga.bin` : Configuration bitstream without header
- `build/usrp_<product>_fpga.syr` : Xilinx system report
- `build/usrp_<product>_fpga.twr` : Xilinx timing report

### X3x0 Targets and Outputs

#### Supported Targets
- X310_1G:  USRP X310. 1GigE on both SFP+ ports. DRAM TX FIFO (experimental!).
- X300_1G:  USRP X300. 1GigE on both SFP+ ports. DRAM TX FIFO (experimental!).
- X310_HG:  USRP X310. 1GigE on SFP+ Port0, 10Gig on SFP+ Port1. DRAM TX FIFO (experimental!).
- X300_HG:  USRP X300. 1GigE on SFP+ Port0, 10Gig on SFP+ Port1. DRAM TX FIFO (experimental!).
- X310_XG:  USRP X310. 10GigE on both SFP+ ports. DRAM TX FIFO (experimental!).
- X300_XG:  USRP X300. 10GigE on both SFP+ ports. DRAM TX FIFO (experimental!).
- X310_HA:  USRP X310. 1GigE on SFP+ Port0, Aurora on SFP+ Port1. DRAM TX FIFO.
- X300_HA:  USRP X300. 1GigE on SFP+ Port0, Aurora on SFP+ Port1. DRAM TX FIFO.
- X310_XA:  USRP X310. 10GigE on SFP+ Port0, Aurora on SFP+ Port1. DRAM TX FIFO.
- X300_XA:  USRP X300. 10GigE on SFP+ Port0, Aurora on SFP+ Port1. DRAM TX FIFO.
- X310_RFNOC_HG:  USRP X310. 1GigE on SFP+ Port0, 10Gig on SFP+ Port1. RFNoC CEs enabled
- X300_RFNOC_HG:  USRP X300. 1GigE on SFP+ Port0, 10Gig on SFP+ Port1. RFNoC CEs enabled
- X310_RFNOC_XG:  USRP X310. 10GigE on both SFP+ ports. RFNoC CEs enabled.
- X300_RFNOC_XG:  USRP X300. 10GigE on both SFP+ ports. RFNoC CEs enabled.
- X310_RFNOC_HLS_HG:  USRP X310. 1GigE on SFP+ Port0, 10Gig on SFP+ Port1. RFNoC CEs enabled + Vivado HLS
- X300_RFNOC_HLS_HG:  USRP X300. 1GigE on SFP+ Port0, 10Gig on SFP+ Port1. RFNoC CEs enabled + Vivado HLS

#### Outputs
- `build/usrp_<product>_fpga_<image_type>.bit` :    Configuration bitstream with header
- `build/usrp_<product>_fpga_<image_type>.bin` :    Configuration bitstream without header
- `build/usrp_<product>_fpga_<image_type>.lvbitx` : Configuration bitstream for PCIe (NI-RIO)
- `build/usrp_<product>_fpga_<image_type>.rpt` :    System, utilization and timing summary report

### E310 Targets and Outputs

#### Supported Targets
- E310_SG1 or E310 :  Builds the USRP E310 speed grade 1.
- E310_SG3 or E310_sg3:  Builds the USRP E310 speed grade 3.
- E310_SG1_RFNOC or E310_RFNOC:  Builds the USRP E310 RFNoC image for speed grade 1.
- E310_SG3_RFNOC or E310_RFNOC_sg3:  Builds the USRP E310 RFNoC image for speed grade 3.

#### Outputs
- `build/usrp_<product>_fpga.bit` : Configuration bitstream with header
- `build/usrp_<product>_fpga.dts` : Device tree overlay
- `build/usrp_<product>_fpga.rpt` : System, utilization and timing summary report

### E320 Targets and Outputs

#### Supported Targets
- E320_1G: 1GigE on SFP+ Port.
- E320_XG: 10GigE on SFP+ Port.
- E320_AA: Aurora on SFP+ Port.
- E320_RFNOC_1G: 1GigE on SFP+ Port. RFNOC CEs enabled.
- E320_RFNOC_XG: 10GigE on SFP+ Port. RFNOC CEs enabled.
- E320_RFNOC_AA: Aurora on SFP+ Port. RFNOC CEs enabled.

#### Outputs
- `build/usrp_<product>_fpga.bit` : Configuration bitstream with header
- `build/usrp_<product>_fpga.dts` : Device tree overlay
- `build/usrp_<product>_fpga.rpt` : System, utilization and timing summary report

### N3XX Targets and Outputs

#### Supported Targets

The targets depend on the actual hardware the FPGA image is being deployed to.
Unlike the X300 Series, the daughterboards are an integral part of the module
and not meant to be removed. Therefore, the target is specific to the
combination of motherboard and daughterboards.

- N300_AA: Aurora on both SFP+ ports
- N300_HA: 1GigE on SFP0, Aurora on SFP1
- N300_HG: 1GigE on SFP0, 10GigE on SFP1
- N300_WX: White Rabbing on SFP0, 10GigE on SFP1
- N300_XA: 10GigE on SFP0, Aurora on SFP1
- N300_XG: 10GigE on both SFP+ ports
- N310_AA: Aurora on both SFP+ ports
- N310_HA: 1GigE on SFP0, Aurora on SFP1
- N310_HG: 1GigE on SFP0, 10GigE on SFP1
- N310_WX: White Rabbing on SFP0, 10GigE on SFP1
- N310_XA: 10GigE on SFP0, Aurora on SFP1
- N310_XG: 10GigE on both SFP+ ports
- N320_AQ: 10GigE on both SFP+ ports, Aurora on QSFP+ ports
- N320_HG: 1GigE on SFP0, 10GigE on SFP1
- N320_XG: 10GigE on both SFP+ ports
- N320_XQ: White Rabbit on SFP0, 10 GigE on QSFP0 and QSFP1

For the N320 targets see also the N320 manual page on the UHD manual.

All targets also support an RFNOC version (e.g. `N300_RFNOC_XG`), which enables
custom selection of RFNoC blocks.


#### Outputs
- `build/usrp_<product>_fpga.bit` : Configuration bitstream with header
- `build/usrp_<product>_fpga.dts` : Device tree overlay
- `build/usrp_<product>_fpga.rpt` : System, utilization and timing summary report

### Additional Build Options

It is possible to make a target and specific additional options in the form VAR=VALUE in
the command. For example: `make B210 PROJECT_ONLY=1`

Here are the supported options:

- `PROJECT_ONLY=1` : Only create a Xilinx project for the specified target(s). Useful for use with the ISE GUI. (*NOTE*: this option is only valid for Xilinx ISE)
- `EXPORT_ONLY=1` :  Export build targets from a GUI build to the build directory. Requires the project in build-\*_\* to be built. (*NOTE*: this option is only valid for Xilinx ISE)
- `GUI=1` : Run the Vivado build in GUI mode instead of batch mode. After the build is complete, Vivado provides an option to save the fully configured project for customization (*NOTE*: this option is only valid for Xilinx Vivado)