Comparator with controlled current supply capacity

What is claimed is: 1. A comparator, comprising: an input-stage circuit configured to set, in a first operating state, two voltage signals in a first voltage state, and to change, in a second operating state, the two voltage signals from the first voltage state to a second voltage state at respective different speeds whose difference is responsive to a difference between voltage levels of two input signals; a latch-stage circuit that includes two field effect transistors and two inverters, the two field effect transistors receiving the two voltage signals at respective control nodes thereof and disposed between two respective output nodes and a node of a predetermined potential, the two inverters being cross-coupled between the two output nodes, and the two inverters being placed in an inactive state in the first operating state and placed in an active state in the second operating state; a control circuit configured to control current supply capacities in two paths through which drive voltages are applied to the two inverters separately from each other; and a switch circuit configured to connect two nodes to each other in the first operating state and to disconnect the two nodes from each other in the second operating state, the two nodes being nodes at which the two inverters receive the drive voltages, respectively, the switch circuit being situated in a connecting path between the two nodes and not situated in either of the two paths for supplying the drive voltages, the connecting path being not for supplying any one of the drive voltages, wherein the control circuit is configured to cause the current supply capacities in the two paths to be different from each other during at least part of a period of the second operating state. 2. The comparator as claimed in claim 1 , wherein the control circuit includes a plurality of field effect transistors connected in parallel to each other in each of the two paths. 3. The comparator as claimed in claim 2 , wherein the control circuit is configured to apply, to control nodes of the field effect transistors, signals each of which is a logical product between a control signal and a clock signal that defines a period of the first operating state and the period of the second operating state. 4. The comparator as claimed in claim 1 , wherein the control circuit includes two switch circuits disposed in the two paths, respectively, and configured to change the two switch circuits from a nonconductive state to a conductive state at different timings, so that points in time at which electric currents start flowing in the two paths are made different from each other. 5. The comparator as claimed in claim 1 , wherein the control circuit includes two variable resistance elements disposed in the two paths, respectively, and configured to make resistance values of the two variable resistance elements different from each other, so that the current supply capacities in the two paths are made different from each other. 6. An electronic circuit, comprising: a comparator; and a circuit configured to receive an output of the comparator, wherein the comparator includes: an input-stage circuit configured to set, in a first operating state, two voltage signals in a first voltage state, and to change, in a second operating state, the two voltage signals from the first voltage state to a second voltage state at respective different speeds whose difference is responsive to a difference between voltage levels of two input signals; a latch-stage circuit that includes two field effect transistors and two inverters, the two field effect transistors receiving the two voltage signals at respective control nodes thereof and disposed between two respective output nodes and a node of a predetermined potential, the two inverters being cross-coupled between the two output nodes, and the two inverters being placed in an inactive state in the first operating state and placed in an active state in the second operating state; a control circuit configured to control current supply capacities in two paths through which drive voltages are applied to the two inverters separately from each other; and a switch circuit configured to connect two nodes to each other in the first operating state and to disconnect the two nodes from each other in the second operating state, the two nodes being nodes at which the two inverters receive the drive voltages, respectively, the switch circuit being situated in a connecting path between the two nodes and not situated in either of the two paths for supplying the drive voltages, the connecting path being not for supplying any one of the drive voltages, wherein the control circuit is configured to cause the current supply capacities in the two paths to be different from each other during at least part of a period of the second operating state. 7. A method of controlling a double-tail comparator which includes an input stage and an output latch stage, the method comprising: making current supply capacities in two paths different from each other, the two paths being paths through which drive voltages are applied to two inverters separately from each other, the two inverters being cross-coupled between two output nodes of the output latch stage; connecting two nodes to each other through a connecting path during an inactive state of the output latch stage, and disconnecting the connecting path between the two nodes during an active state of the output latch stage, the two nodes being nodes at which the two inverters receive the drive voltages, respectively, the connecting path being not for supplying any one of the drive voltages.