This document specifies the functionality of the OpenTitan power manager.
The power manager sequences power, clocks, and reset resources of the design through cold boot, low power entry/exit and reset scenarios.
Cold boot, also known as POR (power on reset) is the first reset state of the design. The power manager sequences the design from a freshly reset state to an active state where software can be initialized.
Reset scenarios refer to non-POR events that cause the device to reboot. There are various stimuli that can cause such a reset, ranging from external user input to watchdog timeout. The power manager processes the reset request and brings the device to an appropriate state.
The power manager performs the following functions:
See the below high level block diagram that illustrates the connections between the power manager and various system components. Blocks outlined with a solid magenta line are always on; while blocks outlined with a dashed magenta line are a mix of components that are and those that are not.
{{< incGenFromIpDesc “/hw/top_earlgrey/ip/pwrmgr/data/autogen/pwrmgr.hjson” “hwcfg” >}}
The power manager contains two state machines. One operates on the always-on slow clock (this clock is always running and usually measured in KHz) and is responsible for turning faster clocks on and off and managing the power domains. The other operates on a normal fixed clock (usually measured in MHz) and is responsible for everything else in the power sequence.
The following diagram breaks down the general functionality of both. The state machines are colored based on their clock domains. The green state machine is clocked by the normal fixed domain, while the orange state machine is clocked by the slow domain. Specific request / acknowledge signals are also highlighted in this color scheme to show where the two state machines communicate.
Note, most of the states are transitional states, and only the following state combinations are resting states.
Idle
and fast FSM Active
Low Power
and fast FSM Low Power
The slow FSM Low Power
and fast FSM Active
states specifically are concepts useful when examining reset handling.
The slow clock domain FSM (referred to as the slow FSM from here on) resets to the Reset state. This state is released by por_rst_n
, which is supplied from the reset controller. The por_rst_n
signal is released when the reset controller detects the root power domains (vcaon_pok
from AST) of the system are ready. Please see the ast for more details.
The slow FSM requests the AST to power up the main domain and high speed clocks. Once those steps are done, it requests the fast FSM to begin operation. The slow FSM also handles power isolation controls as part of this process.
Once the fast FSM acknowledges the power-up completion, the slow FSM transitions to Idle
and waits for a power down request. When a power down request is received, the slow FSM turns off AST clocks and power as directed by software configuration. This means the clocks and power are not always turned off, but are rather controlled by software configurations in {{< regref “CONTROL” >}} prior to low power entry . Once these steps are complete, the slow FSM transitions to a low power state and awaits a wake request, which can come either as an actual wakeup, or a reset event (for example always on watchdog expiration).
Since the slow FSM is sparsely encoded, it is possible for the FSM to end up in an undefined state if attacked. When this occurs, the slow FSM sends an invalid
indication to the fast FSM and forcibly powers off and clamps everything.
The clocks are kept on however to allow the fast FSM to operate if it is able to receive the invalid
indication. The slow FSM does not recover from this state until the system is reset by POR.
Unlike escalation resets, the system does not self reset. Instead the system goes into a terminal non-responsive state where a user or host must directly intervene by toggling the power or asserting an external reset input.
The fast clock domain FSM (referred to as fast FSM from here on) resets to Low Power
state and waits for a power-up request from the slow FSM.
Once received, the fast FSM releases the life cycle reset stage (see reset controller for more details). This allows the OTP to begin sensing. Once OTP sensing completes , the life cycle controller is initialized. The initialization of the life cycle controller puts the device into its allowed operating state (see life cycle controller for more details).
Once life cycle initialization is done, the fast FSM enables all second level clock gating (see clock controller for more details) and initiates strap sampling. For more details on what exactly the strap samples, please see here.
Once strap sampling is complete, the system is ready to begin normal operations (note flash_ctrl
initialization is explicitly not done here, please see sections below for more details). The fast FSM acknowledges the slow FSM (which made the original power up request) and releases the system reset stage - this enables the processor to begin operation. Afterwards, the fast FSM transitions to Active
state and waits for a software low power entry request.
A low power request is initiated by software through a combination of WFI and software low power hint in {{< regref “CONTROL” >}}. Specifically, this means if software issues only WFI, the power manager does not treat it as a power down request. The notion of WFI is exported from the processor. For Ibex, this is currently in the form of core_sleeping_o
.
In response to the low power entry request, the fast FSM disables all second level clock gating. Before proceeding, the fast FSM explicitly separates the handling between a normal low power entry and a reset request.
For low power entry, there are two cases, fall through handling and abort handling. If none of these exception cases are matched for low power entry, the fast FSM then asserts appropriate resets as necessary and requests the slow FSM to take over.
For reset requests, fall through and aborts are not checked and the system simply resets directly. Note in this scenario the slow FSM is not requested to take over.
Since the fast FSM is sparsely encoded, it is possible for the FSM to end up in an undefined state if attacked. When this occurs, the fast FSM forcibly disables all clocks and holds the system in reset.
The fast FSM does not recover from this state until the system is reset by POR.
The power manager coordinates the start up ROM check with rom_ctrl
.
After every reset, the power manager sends an indication to the rom_ctrl
to begin performing integrity checks. When the rom_ctrl
checks are finished, a done
and good
indication are sent back to the power manager.
If the device is in life cycle test states (TEST_UNLOCKED
or RMA
), the good
signal is ignored and the ROM contents are always allowed to execute.
If the device is not in one of the test states, the good
signal is used to determine ROM execution. If good
is true, ROM execution is allowed. If good
is false, ROM execution is disallowed.
A low power entry fall through occurs when some condition occurs that immediately de-assert the entry conditions right after the software requests it.
This can happen if right after software asserts WFI, an interrupt is shown to the processor, thus breaking it out of its currently stopped state. Whether this type of fall through happens is highly dependent on how the system handles interrupts during low power entry - some systems may choose to completely silence any interrupt not related to wakeup, others may choose to leave them all enabled. The fall through handle is specifically catered to the latter category.
For a normal low power entry, the fast FSM first checks that the low power entry conditions are still true. If the entry conditions are no longer true, the fast FSM “falls through” the entry handling and returns the system to active state, thus terminating the entry process.
If the entry conditions are still true, the fast FSM then checks there are no ongoing non-volatile activities from otp_ctrl
, lc_ctrl
and flash_ctrl
. If any module is active, the fast FSM “aborts” entry handling and returns the system to active state, thus terminating the entry process.
There are 4 reset requests in the system
Flash brownout is handled separately and described in flash handling section below.
Peripheral requested resets such as watchdog are handled directly by the power manager, while the non-debug module reset is handled by the reset controller. This separation is because the non-debug reset does not affect the life cycle controller, non-volatile storage controllers and alert states. There is thus no need to sequence its operation like the others.
The power controller only observes reset requests in two states - the slow FSM Low Power
state and the fast FSM Active
state. When a reset request is received during slow FSM Low Power
state, the system begins its usual power up sequence even if a wakeup has not been received.
When a reset request is received during fast FSM Active
state, the fast FSM asserts resets and transitions back to its Low Power
state. The normal power-up process described above is then followed to release the resets. Note in this case, the slow FSM is “not activated” and remains in its Idle
state.
In additional to external requests, the power manager maintains 2 internal reset requests:
Alert escalation resets in general behave similarly to peripheral requested resets. However, peripheral resets are always handled gracefully and follow the normal FSM transition.
Alert escalations can happen at any time and do not always obey normal rules. As a result, upon alert escalation, the power manager makes a best case effort to transition directly into reset handling.
This may not always be possible if the escalation happens while the FSM is in an invalid state. In this scenario, the pwrmgr keeps everything powered off and silenced and requests escalation handling if the system ever wakes up.
Under normal behavior, the power manager can receive escalation requests from the system and handle them appropriately. However, if the escalation clock or reset are non-functional for any reason, the escalation request would not be serviced.
To mitigate this, the power manager actively checks for escalation interface clock/reset timeout. This is done by a continuous request / acknowledge interface between the power manager‘s local clock/reset and the escalate network’s clock/reset.
If the request / acknowledge interface does not respond within 128 power manager clock cycles, the escalate domain is assumed to be off. When this happens, the power manager creates a local escalation request that behaves identically to the global escalation request.
If the main power ever becomes unstable (the power okay indication is low even though it is powered on), the power manager requests an internal reset. This reset behaves similarly to the escalation reset and transitions directly into reset handling.
Note that under normal low power conditions, the main power may be be turned off. As a result of this, the main power unstable checks are valid only during states that power should be on and stable. This includes any state where power manager has requested the power to be turned on.
All other states in the slow / fast FSM are considered transitional states. Resets are not observed in other states because the system will always be transitioning towards one of the steady states (the system is in the process of powering down or powering up). Once a steady state is reached, reset requests are then observed and processed.
There are three ways in which the device is reset:
sleep_req
in the state diagram)The power manager does not handle the non-debug-module request (please see reset controller). For the remaining two reset causes, the power manager handles only 1 pathway at a time (see state diagrams). This means if reset request and low power entry collide, the power manager will handle them on a first come first served basis. When the handling of the first is completed, the power manager handles the second pending request if it is still present.
This is done because low power resets and peripheral requested resets lead to different behaviors. When the power manager commits to handling a specific request, it informs the reset manager why it has reset the processor.
For example, assume a low power entry request arrives slightly ahead of reset requests. The power manager will:
Active
state by using the reset request as a wakeup indicator.Active
state, reset the system and begin normal power-up routines again.If reset requests arrive slightly ahead of a low power entry request, then power manager will:
Active
state, if the low power entry request is still present, transition to low power state.Active
state and awaits software instructions.Ultimately when control is returned to software, it may see two reset reasons and must handle them accordingly.
Similar to reset handling, wakeup signals are only observed during slow FSM Low Power
; however their recording is continuous until explicitly disabled by software.
Wakeup recording begins when the fast FSM transitions out of Active
state and continues until explicitly disabled by software. This ensures wakeup events are not missed until software has set up the appropriate peripherals.
The software is also able to enable recording during Active
state if it chooses to do so. The recording enables are OR’d together for hardware purposes.
For the section below, flash macro refers to the proprietary flash storage supplied by a vendor. flash_ctrl
, on the other hand, refers to the open source controller that manages access to the flash macro.
The AST automatically takes the flash macro out of power down state as part of the power manager's power up request.
Once flash macro is powered up and ready, an indication is sent to the flash_ctrl
.
Once the boot ROM is allowed to execute, it is expected to further initialize the flash_ctrl
and flash macro prior to using it. This involves the following steps:
flash_ctrl
register to ensure flash macro has powered up and completed internal initialization.flash_ctrl
seed reading and scrambling.Before the device enters low power, the pwrmgr first checks to ensure there are no ongoing transactions to the flash macro. When the device enters deep sleep, the flash macro is automatically put into power down mode by the AST. The AST places the flash macro into power down through direct signaling between AST and flash macro, the pwrmgr is not directly involved.
When the device exits low power state, it is the responsibility of the boot ROM to poll for flash macro and flash_ctrl
power-up complete similar to the above section.
When the external supply of the device dips below a certain threshold during a non-volatile flash macro operation (program or erase), the flash macro requires the operation to terminate in a pre-defined manner. This sequence will be exclusively handled by the AST.
The power manager is unaware of the difference between POR and flash brownout. Because of this, the software also cannot distinguish between these two reset causes.
This section details the various low power modes supported by OpenTitan.
This is the lowest power mode of the device (outside of full power down or device held in reset). During this state:
This is a fast low power mode of the device that trades-off power consumption for resume latency. During this state:
When performing TAP debug, it is important for the debugging software to prevent the system from going to low power. If the system enters low power during live debug, the debug session will be broken. There is currently no standardized way to do this, so it is up to the debugging agent to perform the correct steps.
The process in which the power manager is used is highly dependent on the system's topology. The following proposes one method for how this can be done.
Assume first the system has the power states described above.
Once low power is initiated, the system may exit due to several reasons.
In both fall through exit and aborted entry, the power manager does not actually enter low power. Instead the low power entry is interrupted and the system restored to active state.
There are two separate cases for low power exit. One is exiting from deep sleep, and the other is exiting from normal sleep.
When exiting from deep sleep, the system begins execution in ROM.
The handling for fall-through and abort are similar to normal sleep exit. Since in these scenarios the system was not reset, software continues executing the instruction after the wait-for-interrupt invocation.
For an in-depth discussion, please see power management programmers model for additional details.
{{< dif_listing “sw/device/lib/dif/dif_pwrmgr.h” >}}
{{< incGenFromIpDesc “/hw/top_earlgrey/ip/pwrmgr/data/autogen/pwrmgr.hjson” “registers” >}}