Parallel multi-qubit operations on a universal ion trap quantum computer

What is claimed is: 1. A method of performing quantum operations in a trapped-ion quantum system, comprising: implementing two parallel gates of a quantum circuit, each of the two parallel gates being a multi-qubit gate, each of the two parallel gates being implemented using a different set of ions of a plurality of ions in an ion trap, the two parallel gates including a first multi-qubit gate implemented using a first set of ions and a second multi-qubit gate implemented using a second set of ions, the first set of ions and the second set of ions being entangled sets and any remaining sets of ions of the plurality of ions in the ion trap are not entangled sets, wherein implementing the two parallel gates includes generating a first optical pulse sequence having multiple segments and applying first beams to the first set of ions that are based on the first optical pulse sequence to implement the first multi-qubit gate, and wherein implementing the two parallel gates includes generating a second optical pulse sequence having multiple segments and applying second beams to the second set of ions that are based on the second optical pulse sequence to implement the second multi-qubit gate; and simultaneously performing operations on the two parallel gates as part of the quantum operations. 2. The method of claim 1 , wherein: ions in the first set of ions are located in any positions in the ion trap, and ions in the second set of ions are located in any remaining positions in the ion trap. 3. The method of claim 1 , wherein the generating of the first and second optical pulse sequences includes retrieving stored information to generate the first and second optical pulse sequences. 4. The method of claim 1 , wherein the two parallel gates are both XX gates. 5. The method of claim 1 , wherein the two parallel gates are both CNOT gates. 6. The method of claim 1 , wherein the two parallel gates have different amounts of entanglement. 7. The method of claim 6 , wherein: the first multi-qubit gate is a fully-entangling gate and the second multi-qubit gate is a partially-entangling gate. 8. The method of claim 6 , wherein the two parallel gates include a fully-entangling X ⁢ X ⁡ ( π 4 ) gate and a partially-entangling X ⁢ X ⁡ ( π 8 ) gate. 9. The method of claim 1 , wherein the quantum circuit is a quantum full adder circuit. 10. A trapped-ion quantum information processing (QIP) system configured to perform quantum operations, comprising: an algorithms component configured to implement two parallel gates of a quantum circuit, each of the two parallel gates being a multi-qubit gate, each of the two parallel gates being implemented using a different set of ions of a plurality of ions in an ion trap, the two parallel gates including a first multi-qubit gate implemented using a first set of ions and a second multi-qubit gate implemented using a second set of ions, the first set of ions and the second set of ions being entangled sets and any remaining sets of ions of the plurality of ions in the ion trap are not entangled sets; an optical controller, wherein the algorithms component is configured to provide instructions to the optical controller and the optical controller is configured to generate, based on the instructions, a first optical pulse sequence having multiple segments and applying first beams to the first set of ions that are based on the first optical pulse sequence to implement the first multi-qubit gate, wherein the optical controller is further configured to generate, based on the instructions, a second optical pulse sequence having multiple segments and applying second beams to the second set of ions that are based on the second optical pulse sequence to implement the second multi-qubit gate; and wherein operations on the two parallel gates are simultaneously performed as part of the quantum operations. 11. The trapped-ion QIP system of claim 10 , wherein: ions in the first set of ions are located in any positions in the ion trap, and ions in the second set of ions are located in any remaining positions in the ion trap. 12. The trapped-ion QIP system of claim 10 , wherein the optical controller is further configured to generate the first and second optical pulse sequences by retrieving, based on the instructions, stored information to generate the first and second optical pulse sequences. 13. The trapped-ion QIP system of claim 10 , wherein the two parallel gates are both XX gates. 14. The trapped-ion QIP system of claim 10 , wherein the two parallel gates are both CNOT gates. 15. The trapped-ion QIP system of claim 10 , wherein the two parallel gates have different amounts of entanglement. 16. The trapped-ion QIP system of claim 15 , wherein: the first multi-qubit gate is a fully-entangling gate and the second multi-qubit gate is a partially-entangling gate. 17. The trapped-ion QIP system of claim 15 , wherein the two parallel gates include a fully-entangling X ⁢ X ⁡ ( π 4 ) gate and a partially-entangling X ⁢ X ⁡ ( π 8 ) gate. 18. The trapped-ion QIP system of claim 10 , wherein the quantum circuit is a quantum full adder circuit. 19. A computer-readable storage medium storing code with instructions executable by a processor for performing quantum operations in a trapped-ion quantum information processing (QIP) system, comprising: code for implementing two parallel gates of a quantum circuit, each of the two parallel gates being a multi-qubit gate, each of the two parallel gates being implemented using a different set of ions of a plurality of ions in an ion trap, the two parallel gates including a first multi-qubit gate implemented using a first set of ions and a second multi-qubit gate implemented using a second set of ions, the first set of ions and the second set of ions being entangled sets and any remaining sets of ions of the plurality of ions in the ion trap are not entangled sets, wherein the code for implementing the two parallel gates includes code for generating a first optical pulse sequence having multiple segments and for applying, to the first set of ions, first beams based on the first optical pulse sequence to implement the first multi-qubit gate; wherein the code for implementing the two parallel gates includes code for generating a second optical pulse sequence having multiple segments and for appl