Multi-modal communication interface

What is claimed is: 1. An integrated circuit comprising: an input/output (IO) supply node to supply a low IO voltage in a low-voltage mode or a high IO voltage in a high-voltage mode; a data input port and a data output port; and alternative low-voltage and high-voltage communication circuits connected between the data input port and the data output port, and to the IO supply node, the low-voltage and high-voltage communication circuits to convey data signals between the data input port and the data output port in the respective low-voltage and high-voltage modes; the low-voltage communication circuit further including: low-voltage transistors defining a critical path for the data signals in the low-voltage mode, each of the low-voltage transistors having first and second current-handling terminals and a control terminal and exhibiting a sensitivity to a destructive voltage less than the high IO voltage between any two of the first and second current-handling terminals and the control terminal; wherein the low-voltage communication circuit is inactive in the high-voltage mode and the first and second current-handling terminals and the control terminals are set to protection voltage levels in the high-voltage mode. 2. The integrated circuit of claim 1 , the low-voltage communication circuit further comprising protection transistors connected to the critical path to set at least a subset of the terminals to the protection voltage levels in the high-voltage mode. 3. The integrated circuit of claim 2 , wherein the low-voltage transistors include low-voltage gate insulators, and at least one of the protection transistors comprises a high-voltage gate insulator thicker than the low-voltage gate insulators. 4. The integrated circuit of claim 1 , wherein the critical path comprises pull-up and pull-down paths. 5. The integrated circuit of claim 4 , wherein the critical path includes a driver having first and second inputs connected to the pull-up and pull-down paths, respectively. 6. The integrated circuit of claim 5 , wherein the driver includes a set of the low-voltage transistors connected in series from the IO supply node. 7. The integrated circuit of claim 6 , wherein the set of the low-voltage transistors forms a pull-up leg in the pull-up path and a pull-down leg in the pull-down path. 8. The integrated circuit of claim 7 , wherein the pull-up leg includes a first pair of the low-voltage transistors connected in series between the IO supply node and the data output port and the pull-down leg includes a second pair of the low-voltage transistors connected in series between a second supply node and the data output port. 9. The integrated circuit of claim 8 , wherein the control terminal of a low-voltage transistor in each of the legs receives a DC control voltage, and wherein at least one of the DC control voltages is different in the high-voltage mode than in the low-voltage mode. 10. The integrated circuit of claim 9 , wherein the at least one of the DC control voltages is set to one of the protection voltage levels in the high-voltage mode. 11. The integrated circuit of claim 9 , wherein the control terminal of one of the two low-voltage transistors in each leg receives alternative DC control voltages. 12. The integrated circuit of claim 9 , wherein another low-voltage transistor in each of the legs is driven by a respective pre-driver to convey the data signals. 13. The integrated circuit of claim 8 , wherein the control terminal of one of the two low-voltage transistors in one of the legs is connected to the IO supply node in the high-voltage mode and conveys the data signals in the low-voltage mode. 14. The integrated circuit of claim 13 , wherein the control terminal of one of the two low-voltage transistors in the other of the legs is connected to a second supply node in the high-voltage mode and conveys the data signals in the low-voltage mode. 15. The integrated circuit of claim 1 , further comprising mode-select circuitry connected to the communication circuits to enable and disable the respective low-voltage and high-voltage communication circuits in the low-voltage mode and to disable and enable the respective low-voltage and high-voltage communication circuits in the high-voltage mode. 16. A driver supporting first and second communication modes, the driver comprising: a first supply node to supply a first core supply voltage; a second supply node to supply a second core supply voltage; a third supply node to alternatively supply first or second input/output (IO) voltages relative to the first core supply voltage, the first IO voltage being supplied in the first communication mode and the second IO voltage, greater than the first IO voltage, being supplied in the second communication mode; a driver amplifier extending between the first and third supply nodes and having first and second driver input nodes and a driver output node; and a first predriver coupled between the first supply node and each of the second and third supply nodes, the first predriver including a first predriver output node coupled to the first driver input node, wherein the first predriver output node transitions between the first core supply voltage and the first IO voltage in the first communication mode and remains at the second IO voltage in the second communication mode. 17. The driver of claim 16 , further comprising: a second predriver coupled between the first supply node and each of the second and third supply nodes, the second predriver including a second predriver output node coupled to the second driver input node, wherein the second predriver output node transitions between the first core supply voltage and the first IO voltage in the first communication mode and remains at the first core supply voltage in the second communication mode. 18. The driver of claim 16 , wherein the driver amplifier includes two pull-down transistors coupled in series between the driver output node and the first supply node and two pull-up transistors coupled in series between the driver output node and the third supply node. 19. The driver of claim 18 , wherein each of the transistors includes a control terminal, and wherein the pull-up and pull-down transistors connected to the driver output node have their control terminals set to the first IO voltage in the second communication mode. 20. The driver of claim 16 , wherein the first predriver includes a thick-oxide transistor coupled between the third supply node and the first predriver output node, and wherein the thick-oxide transistor pulls the first predriver output node to the second IO voltage in the second communication mode. 21. The driver of claim 16 , wherein the driver amplifier is one of a plurality of driver-amplifier slices extending between the first and third supply nodes, and wherein the first and second driver input nodes and the driver output nodes are common to each of the slices. 22. The driver of claim 16 , wherein the first predriver is one of a plurality of predriver slices coupled between the first supply node and each of the second and third supply nodes, and wherein the first predriver output node of the predriver slices are common to each of the predriver slices. 23. A computer-readable medium having stored thereon a data structure defining a driver adapted to transmit output signals in first and second communication modes, the data structure comprising: first data representing a first supply node to supp