For detailed information on HMAC design features, please see the [HMAC design specification]({{< relref “..” >}}).
HMAC testbench has been constructed based on the [CIP testbench architecture]({{< relref “hw/dv/sv/cip_lib/doc” >}}).
Top level testbench is located at hw/ip/hmac/dv/tb/tb.sv
. It instantiates the HMAC DUT module hw/ip/hmac/rtl/hmac.sv
. In addition, it instantiates the following interfaces and sets their handle into uvm_config_db
:
pins_if
]({{< relref “hw/dv/sv/common_ifs” >}}))pins_if
]({{< relref “hw/dv/sv/common_ifs” >}}))The following utilities provide generic helper tasks and functions to perform activities that are common across the project:
All common types and methods defined at the package level can be found in env/hmac_env_pkg
. Some of them in use are:
parameter uint32 HMAC_MSG_FIFO_DEPTH = 16; parameter uint32 HMAC_MSG_FIFO_DEPTH_BYTES = HMAC_MSG_FIFO_DEPTH * 4; parameter uint32 HMAC_MSG_FIFO_SIZE = 2048;
HMAC instantiates (handled in CIP base env) [tl_agent]({{< relref “hw/dv/sv/tl_agent/doc” >}}) which provides the ability to drive and independently monitor random traffic via TL host interface into HMAC device.
The HMAC RAL model is created with the [ralgen
]({{< relref “hw/dv/tools/ralgen/doc” >}}) FuseSoC generator script automatically when the simulation is at the build stage.
It can be created manually by invoking [regtool
]({{< relref “util/reggen/doc” >}}):
To check the correctness of the output for SHA256 and HMAC, the testbench uses the C reference model. Messages and keys generated by constrained random test sequences are passed on to the reference model. Then the hmac scoreboard will compare the reference model's expected digest data with the DUT output.
All test sequences reside in hw/ip/hmac/dv/env/seq_lib
. The hmac_base_vseq
virtual sequence is extended from cip_base_vseq
and serves as a starting point. All test sequences are extended from hmac_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:
hmac_init
: initialize hmac settings including configurations and interrupte enablescsr_rd_digest
: read digest values from the CSR registerswr_key
: write key values into the CSR registerswr_msg
: write messages into the hmac_msg_fifocompare_digest
: compare the read digest result with the expected valuesBesides contrained random test sequences, hmac test sequences also includes [standard SHA256 and HMAC test vectors]({{< relref “hw/dv/sv/test_vectors/doc.md” >}}) from NIST and IETF. The standard test vectors provide messages, keys (for HMAC only), and expected results. The expected results are used to cross verify both the DUT and DPI-C model outputs.
To ensure high quality constrained random stimulus, it is necessary to develop functional coverage model. The following covergroups have been developed to prove that the test intent has been adequately met:
cfg_cg
: Covers configuration registers in HMACintr_cg
: Covers interrupt registers in HMACstatus_cg
: Covers status registers in HMACmsg_len_cg
: Covers streamed-in message length in HMACThe hmac_scoreboard
is primarily used for end to end checking. It creates the following analysis ports to retrieve the data monitored by corresponding interface agents:
Hmac scoreboard monitors all hmac valid CSR registers, hmac msg_fifo (addr: 'h800 to 'hfff), and interrupt pins.
For a write transaction, during the address channel, CSR values are updated in RAL. Msg_fifo values are updated to an internal msg queue. Once the data finishes streaming, hmac scoreboard will input the msg queue to the C model and calculate the expected output, then update the corresponding RAL registers.
For a read transaction, during the address channel, for status related CSRs (such as fifo_full, fifo_empty, etc), hmac will predict its value according to the cycle accurate model. During the data channel, hmac scoreboard will compare the read data with expected data in RAL.
Hmac scoreboard contains a cycle accurate checking to model the hmac internal message fifo. It has two pointers(hmac_wr_cnt
and hmac_wr_cnt
) to simulate the read and write of the hmac internal message fifo. These two pointers are updated at the negedge of the clock cycle to avoid glitch. Read pointer is incremented one clock cycle after the write pointer (except if HMAC is enabled, then read will first wait 80 clock cycles for the key padding). Hmac fifo full is asserted when hmac_wr_cnt - hmac_wr_cnt == 16
. Hmac fifo depth is checked against the difference between hmac_wr_cnt
and hmac_rd_cnt
.
tb/hmac_bind.sv
binds the tlul_assert
[assertions]({{< relref “hw/ip/tlul/doc/TlulProtocolChecker.md” >}}) to hmac to ensure TileLink interface protocol compliance.We are using our in-house developed [regression tool]({{< relref “hw/dv/tools/doc” >}}) 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 smoke test:
$ $REPO_TOP/util/dvsim/dvsim.py $REPO_TOP/hw/ip/hmac/dv/hmac_sim_cfg.hjson -i hmac_smoke
{{< incGenFromIpDesc “../../data/hmac_testplan.hjson” “testplan” >}}