Hybrid RC/crystal oscillator

The invention claimed is: 1. An oscillator, comprising: a tunable oscillator communicatively coupled with a first pin, the tunable oscillator configured to drive an output signal through the first pin to an external resonant element; a phase detector circuit communicatively coupled with an output of the tunable oscillator and an input to the oscillator; and an oscillator controller circuit configured to adjust frequency of the tunable oscillator based upon phase detection between output of the tunable oscillator and an output of the external resonant element received at the input to the oscillator, wherein the oscillator controller circuit is configured to use the output of the external resonant element to adjust frequency of the tunable oscillator during the entire operation of the tunable oscillator. 2. The oscillator of claim 1 , further comprising a second pin communicatively coupled to input to the oscillator, wherein: the phase detector circuit is configured to receive input to the oscillator through the second pin. 3. The oscillator of claim 1 , wherein the phase detector circuit is configured to receive input to the oscillator through the first pin. 4. The oscillator of claim 1 , wherein: the tunable oscillator is configured to issue output through a driver circuit at the first pin; and the phase detector circuit is configured to receive input to the oscillator through the first pin; the driver circuit is configured to issue the output at the first pin as a current source and to detect voltage on the first pin as the input to the oscillator. 5. The oscillator of claim 1 , wherein the oscillator controller circuit is further configured to output a crystal oscillator status based upon input to the oscillator, wherein the status is configured to denote whether the oscillator is searching for a frequency, whether the oscillator has a locked frequency, and whether the oscillator has lost a locked frequency. 6. The oscillator of claim 1 , wherein the oscillator controller circuit is further configured to maintain output of the tunable oscillator based upon a determination that an external resonant element has failed to generate a usable input to the oscillator. 7. The oscillator of claim 1 , wherein the oscillator controller circuit is further configured to adjust output of the tunable oscillator based upon a determination that a phase lock has been achieved between output of the tunable oscillator and the input to the oscillator. 8. The oscillator of claim 1 , wherein the oscillator controller circuit is further configured to maintain output of the tunable oscillator based upon a determination that a phase lock between output of the tunable oscillator and the input to the oscillator has been lost. 9. The oscillator of claim 1 , further comprising a frequency multiplier circuit coupled between the tunable oscillator and the first pin, wherein an output of the frequency multiplier is coupled with the phase detector circuit to provide the output of the tunable oscillator. 10. A microcontroller, comprising: a processor; one or more peripheral circuits; and an oscillator, comprising: a tunable oscillator communicatively coupled with a first pin, the tunable oscillator configured to drive an output signal through the first pin to an external resonant element and to one or more of the peripheral circuits; a phase detector circuit communicatively coupled with an output of the tunable oscillator and an input to the oscillator; and an oscillator controller circuit configured to adjust frequency of the tunable oscillator based upon phase detection between output of the tunable oscillator and output of the external resonant element received at the input to the oscillator, wherein the oscillator controller circuit is configured to use the output of the external resonant element to adjust frequency of the tunable oscillator during the entire operation of the tunable oscillator. 11. The microcontroller of claim 10 , further comprising a second pin communicatively coupled to input to the oscillator, wherein: the phase detector circuit is configured to receive input to the oscillator through the second pin. 12. The phase detector circuit is configured to receive input to the oscillator through the first pin. 13. The microcontroller of claim 10 , wherein: the tunable oscillator is configured to issue output through a driver circuit at the first pin; and the phase detector circuit is configured to receive input to the oscillator through the first pin; the driver circuit is configured to issue the output at the first pin as a current source and to detect voltage on the first pin as the input to the oscillator. 14. The microcontroller of claim 10 , wherein the oscillator controller circuit is further configured to output a crystal oscillator status based upon input to the oscillator, wherein the status is configured to denote whether the oscillator is searching for a frequency, whether the oscillator has a locked frequency, and whether the oscillator has lost a locked frequency. 15. The microcontroller of claim 10 , wherein the oscillator controller circuit is further configured to maintain output of the tunable oscillator based upon a determination that an external resonant element has failed to generate a usable input to the oscillator. 16. The microcontroller of claim 10 , wherein the oscillator controller circuit is further configured to adjust output of the tunable oscillator based upon a determination that a phase lock has been achieved between output of the tunable oscillator and the input to the oscillator. 17. The microcontroller of claim 10 , wherein the oscillator controller circuit is further configured to maintain output of the tunable oscillator based upon a determination that a phase lock between output of the tunable oscillator and the input to the oscillator has been lost. 18. The microcontroller of claim 10 , further comprising a frequency multiplier circuit coupled between the tunable oscillator and the first pin, wherein an output of the frequency multiplier is coupled with the phase detector circuit to provide the output of the tunable oscillator. 19. A system, comprising: a semiconductor device, comprising a first external pin and an internal oscillator; and an external resonant element coupled to the semiconductor device at least through the first external pin; wherein the internal oscillator comprises: a tunable oscillator communicatively coupled with the first pin and configured to provide an oscillation signal to a portion of the semiconductor device; a phase detector circuit communicatively coupled with an output of the tunable oscillator and an input to the internal oscillator; and an oscillator controller circuit configured to adjust frequency of the tunable oscillator based upon phase detection between output of the tunable oscillator and output of the external resonant element received at the input to the internal oscillator, wherein the oscillator controller circuit is configured to use the output of the external resonant element to adjust frequency of the tunable oscillator during the entire operation of the tunable oscillator. 20. A method, comprising: with a tunable oscillator communicatively coupled with a first pin of an oscillator, driving an output signal through the first pin to an external resonant element; detecting phases with a phase detector circuit communicatively coupled with an output of the tunable oscillator and an input to the internal oscillator; and w