hw/ip/entropy_src/doc/dv_plan/index.md - 3p/lowrisc/opentitan - Git at Google

 ---
 title: "ENTROPY_SRC DV Plan"
 ---

 ## Goals
 * **DV**
   * Verify all ENTROPY_SRC IP features by running dynamic simulations with a SV/UVM based testbench
   * Develop and run all tests based on the [testplan](#testplan) below towards closing code and functional coverage on the IP and all of its sub-modules
 * **FPV**
   * Verify TileLink device protocol compliance with an SVA based testbench

 ## Current status
 * [Design & verification stage]({{< relref "hw" >}})
   * [HW development stages]({{< relref "doc/project/development_stages" >}})
 * [Simulation results](https://reports.opentitan.org/hw/ip/entropy_src/dv/latest/results.html)

 ## Design features
 For detailed information on ENTROPY_SRC design features, please see the [ENTROPY_SRC HWIP technical specification]({{< relref "hw/ip/entropy_src/doc" >}}).

 ## Testbench architecture
 ENTROPY_SRC testbench has been constructed based on the [CIP testbench architecture]({{< relref "hw/dv/sv/cip_lib/doc" >}}).

 ### Block diagram
 ![Block diagram](entropy_src_tb.svg)

 ### Top level testbench
 Top level testbench is located at `hw/ip/entropy_src/dv/tb/tb.sv`. It instantiates the ENTROPY_SRC DUT module `hw/ip/entropy_src/rtl/entropy_src.sv`.
 In addition, it instantiates the following interfaces, connects them to the DUT and sets their handle into `uvm_config_db`:
 * [Clock and reset interface]({{< relref "hw/dv/sv/common_ifs" >}})
 * [TileLink host interface]({{< relref "hw/dv/sv/tl_agent/README.md" >}})
 * ENTROPY_SRC IOs
 * Interrupts ([`pins_if`]({{< relref "hw/dv/sv/common_ifs" >}})

 ### Common DV utility components
 The following utilities provide generic helper tasks and functions to perform activities that are common across the project:
 * [common_ifs]({{< relref "hw/dv/sv/common_ifs" >}})
 * [dv_utils_pkg]({{< relref "hw/dv/sv/dv_utils/README.md" >}})
 * [csr_utils_pkg]({{< relref "hw/dv/sv/csr_utils/README.md" >}})

 <!--### Compile-time configurations
 TODO-->

 ### Global types & methods
 All common types and methods defined at the package level can be found in
 `entropy_src_env_pkg`. Some of them in use are:
 <!--TODO-->
 ```systemverilog
 ```

 ### TL_agent
 ENTROPY_SRC testbench instantiates (already handled in CIP base env) [tl_agent]({{< relref "hw/dv/sv/tl_agent/README.md" >}})
 which provides the ability to drive and independently monitor random traffic via
 TL host interface into ENTROPY_SRC device.

 ### UVM RAL Model
 The ENTROPY_SRC RAL model is created with the [`ralgen`]({{< relref "hw/dv/tools/ralgen/README.md" >}}) FuseSoC generator script automatically when the simulation is at the build stage.

 It can be created manually (separately) by running `make` in the `hw/` area.

 ### Stimulus strategy
 #### Test sequences
 All test sequences reside in `hw/ip/entropy_src/dv/env/seq_lib`.
 The `entropy_src_base_vseq` virtual sequence is extended from `cip_base_vseq` and serves as a starting point.
 All test sequences are extended from `entropy_src_base_vseq`.
 It provides commonly used handles, variables, functions and tasks that the test sequences can simple use / call.
 Some of the most commonly used tasks / functions are as follows:
 * entropy_src_init:     Initialize the ENTROPY_SRC module from the randomized environment variables in the config.

 #### Functional coverage
 To ensure high quality constrained random stimulus, it is necessary to develop a functional coverage model.
 The following covergroups have been developed to prove that the test intent has been adequately met:
 * common covergroup for interrupts `hw/dv/sv/cip_lib/cip_base_env_cov.sv`: Cover interrupt value, interrupt enable, intr_test, interrupt pin

 ### Self-checking strategy
 #### Scoreboard
 The `entropy_src_scoreboard` is primarily used for end to end checking.
 It creates the following analysis ports to retrieve the data monitored by corresponding interface agents:
 * tl_a_chan_fifo, tl_d_chan_fifo:           These 2 fifos provide transaction items at the end of Tilelink address channel and data channel respectively

 #### Assertions
 * TLUL assertions: The `tb/entropy_src_bind.sv` binds the `tlul_assert` [assertions]({{< relref "hw/ip/tlul/doc/TlulProtocolChecker.md" >}}) to the IP to ensure TileLink interface protocol compliance.
 * Unknown checks on DUT outputs: The RTL has assertions to ensure all outputs are initialized to known values after coming out of reset.

 ## Building and running tests
 We are using our in-house developed [regression tool]({{< relref "hw/dv/tools/README.md" >}}) for building and running our tests and regressions.
 Please take a look at the link for detailed information on the usage, capabilities, features and known issues.
 Here's how to run a basic sanity test:
 ```console
 $ cd hw/ip/entropy_src/dv
 $ make TEST_NAME=entropy_src_sanity
 ```

 ## Testplan
 {{< testplan "hw/ip/entropy_src/data/entropy_src_testplan.hjson" >}}
	---
	title: "ENTROPY_SRC DV Plan"
	---

	## Goals
	* DV
	* Verify all ENTROPY_SRC IP features by running dynamic simulations with a SV/UVM based testbench
	* Develop and run all tests based on the [testplan](#testplan) below towards closing code and functional coverage on the IP and all of its sub-modules
	* FPV
	* Verify TileLink device protocol compliance with an SVA based testbench

	## Current status
	* [Design & verification stage]({{< relref "hw" >}})
	* [HW development stages]({{< relref "doc/project/development_stages" >}})
	* [Simulation results](https://reports.opentitan.org/hw/ip/entropy_src/dv/latest/results.html)

	## Design features
	For detailed information on ENTROPY_SRC design features, please see the [ENTROPY_SRC HWIP technical specification]({{< relref "hw/ip/entropy_src/doc" >}}).

	## Testbench architecture
	ENTROPY_SRC testbench has been constructed based on the [CIP testbench architecture]({{< relref "hw/dv/sv/cip_lib/doc" >}}).

	### Block diagram
	![Block diagram](entropy_src_tb.svg)

	### Top level testbench
	Top level testbench is located at `hw/ip/entropy_src/dv/tb/tb.sv`. It instantiates the ENTROPY_SRC DUT module `hw/ip/entropy_src/rtl/entropy_src.sv`.
	In addition, it instantiates the following interfaces, connects them to the DUT and sets their handle into `uvm_config_db`:
	* [Clock and reset interface]({{< relref "hw/dv/sv/common_ifs" >}})
	* [TileLink host interface]({{< relref "hw/dv/sv/tl_agent/README.md" >}})
	* ENTROPY_SRC IOs
	* Interrupts ([`pins_if`]({{< relref "hw/dv/sv/common_ifs" >}})

	### Common DV utility components
	The following utilities provide generic helper tasks and functions to perform activities that are common across the project:
	* [common_ifs]({{< relref "hw/dv/sv/common_ifs" >}})
	* [dv_utils_pkg]({{< relref "hw/dv/sv/dv_utils/README.md" >}})
	* [csr_utils_pkg]({{< relref "hw/dv/sv/csr_utils/README.md" >}})

	<!--### Compile-time configurations
	TODO-->

	### Global types & methods
	All common types and methods defined at the package level can be found in
	`entropy_src_env_pkg`. Some of them in use are:
	<!--TODO-->
	```systemverilog
	```

	### TL_agent
	ENTROPY_SRC testbench instantiates (already handled in CIP base env) [tl_agent]({{< relref "hw/dv/sv/tl_agent/README.md" >}})
	which provides the ability to drive and independently monitor random traffic via
	TL host interface into ENTROPY_SRC device.

	### UVM RAL Model
	The ENTROPY_SRC RAL model is created with the [`ralgen`]({{< relref "hw/dv/tools/ralgen/README.md" >}}) FuseSoC generator script automatically when the simulation is at the build stage.

	It can be created manually (separately) by running `make` in the `hw/` area.

	### Stimulus strategy
	#### Test sequences
	All test sequences reside in `hw/ip/entropy_src/dv/env/seq_lib`.
	The `entropy_src_base_vseq` virtual sequence is extended from `cip_base_vseq` and serves as a starting point.
	All test sequences are extended from `entropy_src_base_vseq`.
	It provides commonly used handles, variables, functions and tasks that the test sequences can simple use / call.
	Some of the most commonly used tasks / functions are as follows:
	* entropy_src_init: Initialize the ENTROPY_SRC module from the randomized environment variables in the config.

	#### Functional coverage
	To ensure high quality constrained random stimulus, it is necessary to develop a functional coverage model.
	The following covergroups have been developed to prove that the test intent has been adequately met:
	* common covergroup for interrupts `hw/dv/sv/cip_lib/cip_base_env_cov.sv`: Cover interrupt value, interrupt enable, intr_test, interrupt pin

	### Self-checking strategy
	#### Scoreboard
	The `entropy_src_scoreboard` is primarily used for end to end checking.
	It creates the following analysis ports to retrieve the data monitored by corresponding interface agents:
	* tl_a_chan_fifo, tl_d_chan_fifo: These 2 fifos provide transaction items at the end of Tilelink address channel and data channel respectively

	#### Assertions
	* TLUL assertions: The `tb/entropy_src_bind.sv` binds the `tlul_assert` [assertions]({{< relref "hw/ip/tlul/doc/TlulProtocolChecker.md" >}}) to the IP to ensure TileLink interface protocol compliance.
	* Unknown checks on DUT outputs: The RTL has assertions to ensure all outputs are initialized to known values after coming out of reset.

	## Building and running tests
	We are using our in-house developed [regression tool]({{< relref "hw/dv/tools/README.md" >}}) for building and running our tests and regressions.
	Please take a look at the link for detailed information on the usage, capabilities, features and known issues.
	Here's how to run a basic sanity test:
	```console
	$ cd hw/ip/entropy_src/dv
	$ make TEST_NAME=entropy_src_sanity
	```

	## Testplan
	{{< testplan "hw/ip/entropy_src/data/entropy_src_testplan.hjson" >}}