AST, also known as the analog sensor top, is the OpenTitan analog and security companion. Within AST are various analog functions (such as clocks, regulators, random number generators) needed to make the device function, as well as physical security sensors necessary to protect the device from physical attacks or manipulation.
At a high level, AST communicates with a number of OpenTitan comportable modules. See diagram below.
In the following sections, each family of connection is briefly described and explained. Note, the analog connections to AST are not shown in the diagram, but will be explained as well.
It complies with OpenTitan names and suffixes with some augmentations.
Clock signals start with clk_*
Inputs and outputs are marked with *_i/o
Analog signals are marked with *_a
Non-core level signals are marked with *_h
Dual and negative polarity signals are marked with *_p/n
sys - system clock, mainly used for high performance and security modules. Up to 100MHz
io - peripheral clock source, mainly used for peripherals and I/O related functionality. Up to 96MHz (divided by 4 by the clock manager)
usb - USB module source clock. 48MHz
aon - Always-on domain clock. The only active clock while chip is in deep-sleep power state, 200KHz
async - when listed as async, it means it does not matter what domain drives the signal
Input clocks: Each functional interface has a dedicated clock named after the interface.
The information below augments the Interface Signals Table. For further details, see the corresponding signals description in the table.
Note: Power signals may not appear in the verilog files, however, they are described for completeness.
AST has four external power supplies VCC, AVCC, VIOA and VIOB. VCC is the main supply, AVCC is an analog VCC supply. VIOA and VIOB are two additional I/O supplies.
The core supplies are generated from the VCC supply. There are two core supply domains: VCMAIN and VCAON. VCAON, as its name implies, is the always-on core supply used to power components that stay active during device low power states. VCMAIN on the other hand, powers most chip logic such as RISC-V processor, crypto modules and almost all memories and peripherals. The VCMAIN supply can be turned off when requested, VCAON on the other hand, is active whenever VCC is active. AST core logic is powered by VCAON.
VCMAIN is the only supply that can be directly influenced by OpenTitan. The power manager can request VCMAIN to shutdown through main_pd_ni. The state of VCMAIN is reflected by the vcmain_pok_o signal.
IO power state is reflected to OpenTitan by vioa_pok_o and viob_pok_o signals
On VCC power-down detection, ‘flash_power_ready_h_o’, is immediately negated. In addition, SYS clock, IO clock and USB clock are stopped. This means that negation of the VCC supply always triggers the flash brown-out (BOR) protection circuitry.
When entering deep-sleep mode, ‘flash_power_down_h_o’ is asserted before negating VCMAIN until VCMAIN is back up.
The AST supports the generation of the root reset for the reset manager. It is driven by ‘vcaon_pok_o’ which is generated inside AST. The ‘vcaon_pok_o’ is activated when the following conditions are met: VCC is detected, internal voltage regulator is active and ‘por_ni’ reset input is inactive. ‘por_ni’ is driven by an external chip reset pin. The following table and diagrams describe the AST sub-modules resets.
Components | Reset by | Comments |
---|---|---|
Regulators, ‘power-OK’ logic and always-on clock | self-start / vcaon_pok_o | These circuits come to life shortly after VCC crosses its detection threshold. vcaon_pok_o serves as their register configuration reset. |
System/USB/IO clock generators | vcmain_pok_o | vcmain_pok_o is also fed by vcaon_pok_o and por_ni. |
Interface functions | Input reset | Per the corresponding interface clock domain reset input. |
AST generates four clocks: System clock, IO clock, USB clock and Always-on clock. Most clocks have ‘enable’ inputs and a corresponding ‘valid’ output. When the enable is de-asserted, the corresponding clock stops and valid is dropped to 0. When the enable is asserted, the clocks begin outputting in a ‘glitchless’ manner and the valid is raised to 1. Unless noted otherwise, clocks duty cycle is 50% +/-5%. At boot time, clocks start toggling at a different (typically slower) frequency than their target. They are configured to their target frequency by the ROM code. Once configured, their frequency is maintained within +/-3% of their target as long as the chip remains in its intended operating conditions until the next boot.
The OpenTitan power and clock managers are responsible for manipulating the enables and observing the valids to know when clocks can be safely released to the system.
The USB clock requires an accuracy that cannot be achieved by the AST clocks natively. As a result, information from USB frames are used to calibrate the clock.
The root clocks and resets are generated inside AST. However, the clocks go through gating and optional division in the OpenTitan top level and propagate back into AST as feedback clocks, each with associated synchronized reset de-assertion to ensure it can synchronize with the various comportable modules. The input resets are used for the different AST interface functions. For further details about AST resets, see Resets section.
Note: There are several reasons for routing leaf clocks back into AST instead of using the root clocks directly
The leaf clocks may be divided down from the root clock and that frequency is used to drive the interface. For example, clk_src_io_clk_o is 96MHz, but comportable modules use either 48MHz or 24MHz.
The leaf clocks and root clocks have very different clock tree depths and may be difficult for timing closure if they interacted directly.
Decouple AST internal design from OpenTitan top-level interfaces clock and reset selection.
AST registers can be accessed via TL-UL interface. These registers are used for test and calibration purposes and are not required for runtime operation. See the Interface Signals Table for more details.
In PROD*/DEV Lifecycle states, the ROM code must copy all AST REGA registers values from OTP to AST. During other Lifecycle states, the ROM code may also copy all AST REGA registers. It is recommended for the ROM code to condition the copy by a digest verification of the register values. If such a digest is too complicated, a simple tag can be used to condition the copy instead. The AST register copy operation must be performed in order and must include all REGA registers (starting from REGA0 and ending at the last REGA). AST sets the ast_init_done_o signal after the copy completion.
After the copy, ROM code can either poll for ast_init_done_o assertion with 100 us timeout (in practice, it should take way less) or ignore it and let the next SW layers handle it. It is recommended to set an OTP field for determining the ROM code action.
The boot code is expected to check all AST output alert signals before handing over the control to the next code layer (ROM_EXT). The ROM code response per alert should be defined in a dedicated OTP space. Recommended response types (per alert):
Do nothing and don't clear the event
Do nothing (continue to the next SW layer) and clear the event
Log the event in some NV space and halt
Halt immediately
Note that in TEST_UNLOCK*/RMA state, the booter should always act per #1 regardless of the OTP setting.
It is recommended to redundantly code the OTP fields that control the ROM code branching and also to protect the branching code from fault injection.
AST contains an analog to digital converter that can be used to sample various input signals. For OpenTitan this will primarily be used for debug cable detection. To activate the ADC, the corresponding comportable module must first activate the ADC through ‘adc_pd_i’. Once activated, it should select the channel to sample. Channel transition from zero to non-zero value starts the ADC conversion. The ADC output is synchronous to the ADC controller.
Activate the ADC by negating ‘adc_pd_i’
Wait 30 uS for the ADC to wake up.
Select an analog channel to measure by setting the corresponding bit in ‘adc_chnsel_i’ bus. This triggers a measurement.
Wait until ‘adc_d_val’ is set and read the result via ‘adc_d_o’
Clear ‘adc_chnsel_i’ bus to 0. Note that adc_chnsel must be cleared to 0 before a new channel is selected.
Repeat steps 3-5 if more channels or more measurements are required
Deactivate the ADC by setting ‘adc_pd_i’ to save power.
{{< wavejson >}} { signal: [ {node: ‘.a..b........’, phase:0.2}, {name: ‘adc_pd_i’ , wave: ‘10|..|.....|....|..1’}, {name: ‘clk_ast_adc_i’, wave: ‘p.|..|.....|....|...’}, {name: ‘adc_chnsel_i’ , wave: ‘0.|.3|..04.|....|0..’}, {name: ‘adc_d_val_o’ , wave: ‘0.|..|.1.0.|.1..|.0.’}, {name: ‘adc_d_o’ , wave: ‘x.|..|.3.x.|.4..|.x.’, data: [‘ch0’, ‘ch1’, ‘ch1’]}, ], edge: [ ‘a<->b wakeup time’, ] } {{< /wavejson >}}
AST contains a random number generator that outputs random number bitstreams whenever it is enabled. After enabled by the comportable controller through ‘rng_en_i’, the AST begins generating multiple independent four random bit streams. rng_b_o bit streams are valid and can be sampled whenever ‘rng_val_o’ is asserted according to the following diagram.
{{< wavejson >}} {signal: [ {name: ‘clk’ , wave: ‘p.|......|......|......’}, {name: ‘rng_enable’ , wave: ‘01|......|......|......’}, {name: ‘rng_valid’ , wave: ‘0.|..10..|..10..|..10..’}, {name: ‘rng_b’ , wave: ‘x.|..3...|..4...|..5.....’, data: [‘es0’,‘es1’,‘es2’]}, ]} {{< /wavejson >}}
The expected rng_b_o valid output rate is about 50KHz. For more information on the RNG interface, please see the OpenTitan entropy source module.
AST consumes entropy for defensive purposes. However, AST does not consume its raw entropy directly. Instead, AST receives entropy from the Entropy Distribution Network (EDN). Note that entropy_ack and entropy_i are packed into enropy_rsp_i in the interface. Also note that once entropy_req_o is set, it will remain set until ack or until reset.
{{< wavejson >}} {signal: [
{name: ‘clk_ast_es_i’ , wave: ‘p.|..........’},
{name: ‘entropy_req_o’ , wave: ‘01|.0.1.....0’},
{name: ‘entropy_ack_i’ , wave: ‘0.|10.1.01..0’},
{name: ‘entropy_i’ , wave: ‘xx|2x.22x222x’},
] } {{< /wavejson >}}
AST's sensors and detectors, when triggered, output alert events to a sensor controller. The event signals are level until acknowledged by the controller. Further, the events are differentially encoded to ensure they cannot be hard-wired or faulted to either ‘1’ or ‘0’.
Inside the sensor controller, the events are then converted into alerts as part of the wider OpenTitan alert handling system.
Outgoing alert events are level. Incoming event ack signals clear the alert event (similar to an interrupt). Outgoing alert events should be OR'd inside the sensor or power manager (depending on what level of deep sleep support is needed) to generate wakeup, that way AST does not need to do any additional handling for wakeups during low power mode.
The AST defines each alert signal in both positive (P) and negative (N) polarity (see ast_dif_t typedef with ‘p’ and ‘n’ signals), however, the P and N signals are not necessarily fully differential, for example, at times, it might occur that both P and N are at the same value. For alert_o case, the correct way to treat it is to propagate an alert signal if either P is high or N is low.
Most countermeasure enablement is controlled by Nuvoton via the registers interface. Clock jitter is an exception because there is a reasoning for dynamically turning it on and off (security/performance tradeoff). Unless stated otherwise, countermeasures are active in all modes but deep-sleep.