Abstract: Provided are polynucleotides comprising nucleic acid sequences encoding chimeric antigen receptors having the hinge, transmembrane region, and/or intracellular domain of LILRB1, or functional fragments or variants thereof. Also provided herein are vectors and immune cells comprising said polynucleotides.

Abstract: Provided are chimeric antigen receptors having the hinge, transmembrane region, and/or intracellular domain of LILRB1, or functional fragments or variants thereof. Also provided herein are cells comprising the LILRB1 based receptors, and methods of making and using same.

Abstract: Provided are chimeric antigen receptors having the hinge, transmembrane region, and/or intracellular domain of LILRB1, or functional fragments or variants thereof. Also provided herein are cells comprising the LILRB1 based receptors, and methods of making and using same.

Abstract: Provided are chimeric antigen receptors having the hinge, transmembrane region, and/or intracellular domain of LILRB1, or functional fragments or variants thereof. Also provided herein are cells comprising the LILRB1 based receptors, and methods of making and using same.

Abstract: Provided are chimeric antigen receptors having the hinge, transmembrane region, and/or intracellular domain of LILRB1, or functional fragments or variants thereof. Also provided herein are cells comprising the LILRB1 based receptors, and methods of making and using same.

Abstract: Provided are chimeric antigen receptors having the hinge, transmembrane region, and/or intracellular domain of LILRB1, or functional fragments or variants thereof. Also provided herein are cells comprising the LILRB1 based receptors, and methods of making and using same.

Abstract: A synchronized JAVA debugger maintains synchronization between a JAVA source file in the debugger current working directory and a corresponding JAVA stored procedure in a database to be debugged. The debugger includes fetching module, storage module, display module, and execution module. The fetching module fetches a corresponding JAVA source file for a JAVA stored procedure from a database. The display module displays a recompile option, as a button, menu, or command line interface. In response to selection of the recompile option in the user interface, the execution module terminates the debugging session, sends a modified JAVA source file to the remote target JAVA Virtual Machine (JVM) and instructs the remote JVM to recompile the JAVA stored procedure using the modified JAVA source file before a new debugging session is started. Communication between the debugger and the remote database is by sending and receiving JAVA Debug Wire Protocol (JDWP) command packets.

Abstract: A client debugger application or a virtual machine includes a receiving module configured to receive a command packet of a debugging protocol from a computer. The command packet includes an identifier (ID) field. The client debugger application or the virtual machine also includes a parsing module configured to parse an ID from the ID field. One byte of the ID field doubles as a command set value and another byte of the ID field doubles as a command value. The client debugger application or the virtual machine further includes a debugging module configured to use the parsed ID, command set value and command value to perform at least one debugging operation.

Abstract: Embodiments of the invention provide systems and methods for optimizing handling of breakpoints in a debugger agent. Embodiments generate an additional modified bytecode copy that includes location indexes associated with breakpoint requests at the breakpoint locations. The location indexes may correspond to a location in a data structure in which the breakpoint information (e.g., request identifier and associated location information) is stored. The location index identified by the additional bytecode copy for a breakpoint may then be used to directly access the appropriate location in the data structure for generating a desired reply packet. Thus, the location index may effectively allow the debugger agent to generate the reply packet without searching through a complex data structure for the relevant request information.

Abstract: Embodiments of the invention provide systems and methods for optimizing handling of breakpoints in a debugger agent. Embodiments generate an additional modified bytecode copy that includes location indexes associated with breakpoint requests at the breakpoint locations. The location indexes may correspond to a location in a data structure in which the breakpoint information (e.g., request identifier and associated location information) is stored. The location index identified by the additional bytecode copy for a breakpoint may then be used to directly access the appropriate location in the data structure for generating a desired reply packet. Thus, the location index may effectively allow the debugger agent to generate the reply packet without searching through a complex data structure for the relevant request information.

Abstract: A client debugger application or a virtual machine includes a receiving module configured to receive a command packet of a debugging protocol from a computer. The command packet includes an identifier (ID) field. The client debugger application or the virtual machine also includes a parsing module configured to parse an ID from the ID field. One byte of the ID field doubles as a command set value and another byte of the ID field doubles as a command value. The client debugger application or the virtual machine further includes a debugging module configured to use the parsed ID, command set value and command value to perform at least one debugging operation.

Abstract: A synchronized Java debugger includes a fetching module configured to fetch a corresponding Java source file for a Java stored procedure from a database when the synchronized Java debugger is to be run. The synchronized Java debugger also includes a storage module configured to store the Java source file in a current working directory to be used by the synchronized Java debugger when the synchronized Java debugger is run and an execution module configured to run the synchronized Java debugger. The synchronized Java debugger further includes a display module configured to display execution control based on the Java source file during debugging. The synchronized Java debugger is configured to use the Java source file to maintain synchronization between the Java source file in the current working directory of the synchronized Java debugger and a corresponding Java class file stored in the database.

Abstract: A torque sensor, which is for an electric power steering system that has an output shaft for rotating in response to rotation of an input shaft, may include a first rotor for rotating with the input shaft, a second rotor for rotating with the output shaft, a first pinion gear mounted for rotating in response to rotation of the first rotor, a first magnet mounted for rotating with the first pinion gear, a second pinion gear mounted for rotating in response to rotation of the second rotor, a second magnet mounted for rotating with the second pinion gear, a first sensor positioned for sensing an angular position of the first magnet, and a second sensor positioned for sensing an angular position of the second magnet. The first rotor and the second rotor are mounted so that there can be relative rotation between the first rotor and the second rotor.