Battery parameter-based power management for suppressing power spikes

What is claimed is: 1. A computer-implemented method comprising: determining, for an upcoming point in time, an available amount of power that a battery of a computing device is capable of providing while maintaining a predefined voltage level, the available amount of power determined based on an open circuit potential, internal resistance, and load current of the battery, the predefined voltage level being a voltage level at or above a hard cutoff voltage level or a soft cutoff voltage level at which the computing device ceases to operate from battery power; determining, for the upcoming point in time, a requisite amount of power that components of the computing device will consume to perform at least a portion of a task at their respective power states; and altering, responsive to determining that the requisite amount of power exceeds the available amount of power, respective power states of one or more of the components at the upcoming point in time effective to enable the battery to maintain the predefined voltage level and the computing device to continue operate while the components consume the requisite amount of power from the battery. 2. The computer-implemented method as described in claim 1 , wherein altering the respective power states of the one or more components comprises altering a sequence in which the task or other tasks of the device are performed effective to reduce, at the upcoming point in time, a respective power state of at least one of the components involved in performing the tasks. 3. The computer-implemented method as described in claim 1 , wherein altering the respective power states of the one or more components comprises reducing a respective power state of at least one of the components. 4. The computer-implemented method as described in claim 3 , wherein reducing the respective power states of the one or more components negatively effects performance of the task and the method further comprises increasing, at another point in time, the respective power states of the one or more components to mitigate the effects on performance of the task. 5. The computer-implemented method as described in claim 4 , wherein the other point in time occurs before or after the upcoming point in time at which the requisite amount of power exceeds the available amount of power. 6. The computer-implemented method as described in claim 1 , wherein determining the available amount of power that the battery is capable of providing further comprises determining a state-of-charge of the battery and determining, based on the state-of-charge, the open circuit potential of the battery or the internal resistance of the battery. 7. The computer-implemented method as described in claim 6 , wherein determining the open circuit potential of the battery based on the state-of-charge comprises accessing, based on the state-of-charge, predetermined information that describes a relationship between the state-of-charge and the open circuit potential of the battery. 8. The computer-implemented method as described in claim 1 , further comprising selecting which of the respective power states of the one or more components to alter based on component interdependencies associated with performing the task. 9. The computer-implemented method as described in claim 1 , further comprising selecting a degree by which to alter the respective power states of the one or more components based on a minimum power state of a respective component at which performance of the task is enabled. 10. A computer-implemented method comprising: receiving a request for a device to perform, in addition to other tasks being performed by the device, an additional task having a particular priority level; determining an available amount of power that a battery of the device can provide while maintaining a predefined voltage level, the available amount of power determined based on an open circuit potential of the battery, internal resistance of the battery, and load current of the battery, the predefined voltage level being a voltage level at or above a hard cutoff voltage level or a soft cutoff voltage level at which the device ceases to operate from battery power; determining that a requisite amount of power that resources of the device will consume to perform the additional task and other tasks exceeds the available amount of power that a battery of the device can provide while maintaining the predefined voltage level; determining which ones of the other tasks have respective priority levels that are lower than the particular priority level of the additional task; identifying which ones of the resources are involved in performing the other tasks having the lower respective priority levels; and altering respective power states of at least some of the resources involved in performing the other tasks having the lower respective priority levels effective to enable the battery to maintain the predefined voltage level and the device to continue to operate while the resources of the device consume the requisite amount of power from the battery to perform the additional task. 11. The computer-implemented method as described in claim 10 , further comprising altering respective power states of resources involved with performing the additional task such that the requisite power does not exceed the available amount of power when the additional task is performed. 12. The computer-implemented method as described in claim 10 , further comprising, prior to altering the respective power states, identifying interdependencies between the resources involved with performing the other tasks having the lower respective priority levels and resources involved with performing the additional task, and wherein altering the respective power states of at least some of the resources alters respective power states of the resources involved in performing the other tasks that are not interdependent with resources involved with performing the additional task. 13. The computer-implemented method as described in claim 10 , wherein altering respective power states of at least some of the resources includes shutting down or idling the resources involved in performing the other tasks having the lower respective priority levels. 14. The computer-implemented method as described in claim 10 , wherein the other tasks having the lower respective priority levels are background tasks of an operating system or application. 15. A system comprising: a battery from which the system draws power to operate; hardware-based resources by which the system performs tasks; a power manager configured to perform operations comprising: determining, for an upcoming point in time, an available amount of power that the battery is capable of providing while maintaining a predefined voltage level, the available amount of power determined based on an open circuit potential of the battery, internal resistance of the battery, and load current of the battery, the predefined voltage being a voltage level at or above a hard cutoff voltage level or a soft cutoff voltage level at which the system ceases to operate from the battery; determining, for the upcoming point in time, a requisite amount of power that the hardware-based resources will consume to perform one of the tasks at the hardware-based resources' respective power states; and altering, responsive to determining that the requisite amount of power exceeds the available amount of power, respective power states of one or more of the hardware-based resources at the upcoming point in time effective to enable the battery to maintain the predefined voltage level and the system t