SYSTEMS AND METHODS FOR MEMORY RECOVERY USING SECONDARY MEMORY

Notice of Pre-AIA or AIA Status The present application, filed on or after March 16, 2013, is being examined under the first inventor to file provisions of the AIA . Claims 1-20 are pending for examination This office is NON-FINAL Response to Arguments Applicant’s arguments with respect to claim(s) [ 1-20 ] have been considered but are moot because the new ground of rejection does not rely on any reference applied in the prior rejection of record for any teaching or matter specifically challenged in the argument. Claim Rejections - 35 USC § 103 The following is a quotation of 35 U.S.C. 103 which forms the basis for all obviousness rejections set forth in this Office action: A patent for a claimed invention may not be obtained, notwithstanding that the claimed invention is not identically disclosed as set forth in section 102, if the differences between the claimed invention and the prior art are such that the claimed invention as a whole would have been obvious before the effective filing date of the claimed invention to a person having ordinary skill in the art to which the claimed invention pertains. Patentability shall not be negated by the manner in which the invention was made. The factual inquiries for establishing a background for determining obviousness under 35 U.S.C. 103 are summarized as follows: 1. Determining the scope and contents of the prior art. 2. Ascertaining the differences between the prior art and the claims at issue. 3. Resolving the level of ordinary skill in the pertinent art. 4. Considering objective evidence present in the application indicating obviousness or nonobviousness. This application currently names joint inventors. In considering patentability of the claims the examiner presumes that the subject matter of the various claims was commonly owned as of the effective filing date of the claimed invention(s) absent any evidence to the contrary. Applicant is advised of the obligation under 37 CFR 1.56 to point out the inventor and effective filing dates of each claim that was not commonly owned as of the effective filing date of the later invention in order for the examiner to consider the applicability of 35 U.S.C. 102(b)(2)(C) for any potential 35 U.S.C. 102(a)(2) prior art against the later invention. Claim(s) [ 1-3, 5, 6, 8-14, 20 ] are rejected under 35 U.S.C. 103 as being unpatentable over [ Hoekstra et al (US Pub No. 20150318871), hereinafter "Hoekstra", In view of Criss et al. (US Pub No. 201900042358), hereinafter "Criss" ]. As per claim 1, Hoekstra significantly teaches a method for memory recovery, the method comprising (Embodiments of the present invention provide systems and methods for using different error correction codes [Hoekstra PP 0016]): detecting, by a first memory controller, an error associated with a primary memory (Data processing system 100 includes a processor 102, a memory controller 104 with error correction code (ECC) control 116 , non-volatile memory 106 [Hoekstra PP 0017],In process 602, a message containing a memory read access address is received by memory controller 104. Process 604 detects whether one or more errors are encountered or detected [Hoekstra PP 0034]); receiving, by the first memory controller, information comprising a recovery code from a source that is external to the first memory controller via an interface (Information for the codes used for another set of subsection sizes of the memory array can be stored in a secondary memory outside the memory array … The secondary memory can be implemented using a volatile memory device that is external to the NVM where the data is stored. [Hoekstra PP 0016], Memory Controller 104 is coupled to communicate with flash memory 106 , secondary memory 108 , RAM 110 and ROM 112 via one or more buses. [Hoekstra PP 0017], Parity bits associated with correcting error(s) in segments of flash memory 106 of another specified size can be stored in secondary memory 108 . [Hoekstra PP 0018]); Hoekstra does not explicitly teach “and modifying, by the first memory controller, the error on the primary memory based on the information.” However, Criss, in an analogous art, teaches and modifying, by the first memory controller, the error on the primary memory based on the information (Memory controller ECC component 114 detects and corrects these miss-corrections and produces corrected data 206 [Criss PP 0023], all of the bits are sent as SEC corrected data 204 to memory controller 104 where memory controller ECC component 114 checks for inconsistencies between the data and the memory controller ECC check bits and, if required, performs a correction … If the error is correctable by the memory controller ECC component then the original code word can be found and the data is recovered. [Criss PP 0025]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 2, Hoekstra significantly teaches wherein the interface is communicatively coupled to a secondary memory (Memory Controller 104 is coupled to communicate with flash memory 106 , secondary memory 108 , RAM 110 and ROM 112 via one or more buses. [Hoekstra PP 0017]) storing the recovery code (Parity bits associated with correcting error(s) in segments of flash memory 106 of another specified size can be stored in secondary memory 108. [Hoekstra PP 0018]). As per claim 3, Hoekstra significantly teaches further comprising: generating, by the first memory controller, the recovery code (ECC control 116 can provide both error encoding and error decoding functionality. As data is received from memory (e.g., flash memory 106 , RAM 110 or ROM 112 ) or processor 102 , ECC control 116 can generate parity bits, also referred to as error correction bits [Hoekstra PP 0018]); and sending the recovery code to the secondary memory via the interface (Process 508 determines whether the type of ECC selected in process 506 has changed. If a new type of ECC is going to be used, process 510 writes the corresponding information in the error correction bits and elsewhere in a corresponding entry in secondary memory 108. [Hoekstra PP 0033]). As per claim 5, Hoekstra significantly teaches and storing the recovery code in the secondary memory (Process 508 determines whether the type of ECC selected in process 506 has changed. If a new type of ECC is going to be used, process 510 writes the corresponding information in the error correction bits and elsewhere in a corresponding entry in secondary memory 108. [Hoekstra PP 0033]). Hoekstra does not explicitly teach “further comprising: storing data associated with an application in the primary memory;” However, Criss, in an analogous art, teaches further comprising: storing data associated with an application in the primary memory (At block 808, memory device 102 stores the data bits, the memory controller ECC check bits, and the on-die ECC check bits in memory 112. [Criss PP 0049]); Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 6, Hoekstra significantly teaches wherein the secondary memory is external to the primary memory (Information for the codes used for another set of subsection sizes of the memory array can be stored in a secondary memory outside the memory array …The secondary memory can be implemented using a volatile memory device that is external to the NVM where the data is stored. [Hoekstra PP 0016]). As per claim 8, Hoekstra does not explicitly teach “wherein the primary memory comprises volatile memory.” However, Criss, in an analogous art, teaches wherein the primary memory comprises volatile memory (memory 112 may include volatile types of memory including, but not limited to, RAM, D-RAM, DDR SDRAM, SRAM, T-RAM or Z-RAM. [Criss PP 0020]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 9, Hoekstra does not explicitly teach “wherein: the primary memory comprises parity information; and the first memory controller detects the error based on the parity information.” However, Criss, in an analogous art, teaches wherein: the primary memory comprises parity information (Parity bits used in an ECC scheme impose conditions on the data and the external ECC check bits written to memory 112. [Criss PP 0024]); and the first memory controller detects the error based on the parity information (At block 1002, memory controller 104 receives data bits and the memory controller ECC check bits from memory device 102 … At block 1004, the memory controller, using memory controller ECC component 114, checks the received data bits against the received memory controller ECC check bits and performs corrections as needed. [Criss PP 0055]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 10, Hoekstra significantly teaches wherein the recovery code comprises at least one of a single-bit error correction, double-bit error detection (SECDED) code (During a read access of flash memory 106 , single bit error correction and double bit error detection (SEC-DED) can be performed on each of the memory segments. [Hoekstra PP 0026]), or a triple-bit error correction, quadruple-bit error detection (TECQED) code (error correction bits used in more complex ECC to correct multiple errors can be stored in secondary memory 108. [Hoekstra PP 0018]). As per claim 11, Hoekstra significantly teaches wherein the primary memory comprises a memory module (Data processing system 100 includes a processor 102 , a memory controller 104 with error correction code (ECC) control 116 , non-volatile memory 106 such as flash memory, secondary memory 108 , random access memory (RAM) 110 , read-only memory (ROM) 112 , and peripheral modules 114 . [Hoekstra PP 0017]). As per claim 12, Hoekstra does not explicitly teach “wherein: the primary memory comprises an error correction code (ECC) memory comprising a location for processing detection and/or correction codes; and the method further comprises: generating, by the first memory controller, an error detection code and writing the error detection code to the location for processing detection and/or correction codes.” However, Criss, in an analogous art, teaches wherein: the primary memory comprises an error correction code (ECC) memory comprising a location for processing detection and/or correction codes (At block 808, memory device 102 stores the data bits, the memory controller ECC check bits, and the on-die ECC check bits in memory 112. [Criss PP 0049]); and the method further comprises: generating, by the first memory controller, an error detection code (At block 704, memory controller 104, using memory controller ECC component 114, determines a plurality of memory controller ECC check bits and one or more parity bit(s) for the received data bits. [Criss PP 0048]) and writing the error detection code to the location for processing detection and/or correction codes (At block 808, memory device 102 stores the data bits, the memory controller ECC check bits, and the on-die ECC check bits in memory 112. [Criss PP 0049]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 13, Hoekstra does not explicitly teach “wherein: the primary memory comprises one or more volatile-memory-based chips comprising a parity space; and the method further comprises: generating, by the first memory controller, an error detection code and writing the error detection code to the parity space.” However, Criss, in an analogous art, teaches wherein: the primary memory comprises one or more volatile-memory-based chips comprising a parity space (In some examples, memory 112 may include volatile types of memory including, but not limited to, RAM, D-RAM, DDR SDRAM, SRAM, T-RAM or Z-RAM. [Criss PP 0020], Parity bits used in an ECC scheme impose conditions on the data and the external ECC check bits written to memory 112. [Criss PP 0024]); and the method further comprises: generating, by the first memory controller, an error detection code (At block 704, memory controller 104, using memory controller ECC component 114, determines a plurality of memory controller ECC check bits and one or more parity bit(s) for the received data bits. [Criss PP 0048]) and writing the error detection code to the parity space (At block 808, memory device 102 stores the data bits, the memory controller ECC check bits, and the on-die ECC check bits in memory 112. [Criss PP 0049]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 14, Hoekstra does not explicitly teach “wherein the first memory controller reads at least a data associated with an application and an error detection code from the primary memory.” However, Criss, in an analogous art, teaches wherein the first memory controller reads at least a data associated with an application and an error detection code from the primary memory (At block 902, when reading data from the memory device is requested, memory device 102 gets the data bits, the memory controller ECC check bits, and the on-die ECC check bits from memory 112. [Criss PP 0050], At block 910, memory device sends the data bits and the memory controller ECC check bits to memory controller 104. [Criss PP 0054], At block 1002, memory controller 104 receives data bits and the memory controller ECC check bits from memory device 102. [Criss PP 0055]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 20, Hoekstra significantly teaches a device comprising: an interface to receive a request, from a first memory controller associated with a primary memory (In process 602, a message containing a memory read access address is received by memory controller 104. [Hoekstra PP 0034]) and a secondary memory that is external to the primary memory and that comprises the recovery code (Information for the codes used for another set of subsection sizes of the memory array can be stored in a secondary memory outside the memory array …The secondary memory can be implemented using a volatile memory device that is external to the NVM where the data is stored. [Hoekstra PP 0016]), the secondary memory being communicatively coupled to the interface to send the recovery code from the device to the first memory controller (Memory Controller 104 is coupled to communicate with flash memory 106 , secondary memory 108 , RAM 110 and ROM 112 via one or more buses. [Hoekstra PP 0017]). Hoekstra does not explicitly teach “for information comprising a recovery code for modifyinq an error on the primary memory;” However, Criss, in an analogous art, teaches for information comprising a recovery code for modifyinq an error on the primary memory (memory controller ECC component 114 checks for inconsistencies between the data and the memory controller ECC check bits and, if required, performs a correction … If the error is correctable by the memory controller ECC component then the original code word can be found and the data is recovered. [Criss PP 0025]); Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. Claim(s) [ 4, 7, 15-19 ] are rejected under 35 U.S.C. 103 as being unpatentable over [Hoekstra , In view of Criss, in further view of Kalyanasundharam et al. (US Pub No. 2020226081), hereinafter " Kalyanasundharam"]. As per claim 4, Hoekstra in view of Criss do not explicitly teach “wherein the sending the recovery code via the interface is in accordance with a cache-coherent protocol.” However, Kalyanasundharam, in an analogous art, teaches wherein the sending the recovery code via the interface is in accordance with a cache-coherent protocol (a Cache Coherent Interconnect for Accelerators (CCIX) port … The port controller also includes a remote coherent slave controller to send cache coherency requests over the PCIe communication link using a full set of CCIX protocol memory transaction types. [KALYANASUNDHARAM PP 0012]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra in view of Criss to further incorporate Kalyanasundharam’s teachings of a coherent interconnect/interface, in order to improve memory access (The expanded memory capability may offer expanded memory capacity [Kalyanasundharam’s PP 0017]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 7, Hoekstra in view of Criss do not explicitly teach “wherein: the first memory controller is communicatively coupled, via a data path, to a second memory controller; and the second memory controller converts the recovery code into a format for sending from the interface.” However, Kalyanasundharam, in an analogous art, teaches wherein: the first memory controller is communicatively coupled, via a data path, to a second memory controller (The port controller includes a light-weight memory protocol controller … The port controller also includes a remote coherent slave controller to send cache coherency requests [KALYANASUNDHARAM PP 0014]); and the second memory controller converts the recovery code into a format for sending from the interface (transforming access requests that may include coherency-related requests to a form using only the light-weight set of requests [KALYANASUNDHARAM PP 0032]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra in view of Criss to further incorporate Kalyanasundharam’s teachings of a coherent interconnect/interface, in order to improve memory access (The expanded memory capability may offer expanded memory capacity [Kalyanasundharam’s PP 0017]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 15, Hoekstra in view of Criss do not explicitly teach “wherein the receiving the information from the interface is associated with a higher latency than receiving the information from the primary memory.” However, Kalyanasundharam, in an analogous art, teaches wherein the receiving the information from the interface is associated with a higher latency than receiving the information from the primary memory (Supporting so many commands requires a much larger, more expensive processor than supporting only non-caching commands. Such processors also tend to have a higher latency in responding to commands. [KALYANASUNDHARAM PP 0075]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra in view of Criss to further incorporate Kalyanasundharam’s teachings of a coherent interconnect/interface, in order to improve memory access (The expanded memory capability may offer expanded memory capacity [Kalyanasundharam’s PP 0017]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 16, Hoekstra significantly teaches A device comprising: a primary memory (Data processing system 100 includes … non-volatile memory 106 such as flash memory [Hoekstra PP 0017]); a first memory controller to generate a recovery code and communicatively coupled to the primary memory (Data processing system 100 includes a processor 102 , a memory controller 104 with error correction code (ECC) control 116 [Hoekstra PP 0017], ECC control 116 can provide both error encoding and error decoding functionality. As data is received from memory or processor 102 , ECC control 116 can generate parity bits, also referred to as error correction bits [Hoekstra PP 0018]), Hoekstra does not explicitly teach “the recovery code for modifying an error on the primary memory; and a second memory controller to convert the recovery code to a format for sending from an interconnection protocol.” However, Criss, in an analogous art, teaches the recovery code for modifying an error on the primary memory (memory controller ECC component 114 checks for inconsistencies between the data and the memory controller ECC check bits and, if required, performs a correction … If the error is correctable by the memory controller ECC component then the original code word can be found and the data is recovered. [Criss PP 0025]); Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. Hoekstra in view of Criss do not explicitly teach “and a second memory controller to convert the recovery code to a format for sending from an interconnection protocol.” However, Kalyanasundharam, in an analogous art, teaches and a second memory controller to convert the recovery code to a format for sending from an interconnection protocol (The port controller includes a light-weight memory protocol controller … The port controller also includes a remote coherent slave controller [KALYANASUNDHARAM PP 0012], transforming access requests that may include coherency-related requests to a form using only the light-weight set of requests [KALYANASUNDHARAM PP 0032]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra in view of Criss to further incorporate Kalyanasundharam’s teachings of a coherent interconnect/interface, in order to improve memory access (The expanded memory capability may offer expanded memory capacity [Kalyanasundharam’s PP 0017]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 17, Hoekstra does not explicitly teach “wherein the first memory controller: receives information comprising the recovery code from the second memory controller; and modifies an error on the primary memory based on the information.” However, Criss, in an analogous art, teaches and modifies an error on the primary memory based on the information (memory controller ECC component 114 checks for inconsistencies between the data and the memory controller ECC check bits and, if required, performs a correction … If the error is correctable by the memory controller ECC component then the original code word can be found and the data is recovered. [Criss PP 0025]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. Hoekstra in view of Criss do not explicitly teach “wherein the first memory controller: receives information comprising the recovery code from the second memory controller;” However, Kalyanasundharam, in an analogous art, teaches wherein the first memory controller: receives information comprising the recovery code from the second memory controller (at the remote coherent slave controller, memory access requests are received over the on-chip interconnect fabric [KALYANASUNDHARAM PP 0013]); Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra in view of Criss to further incorporate Kalyanasundharam’s teachings of a coherent interconnect/interface, in order to improve memory access (The expanded memory capability may offer expanded memory capacity [Kalyanasundharam’s PP 0017]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 18, Hoekstra does not explicitly teach “wherein the primary memory comprises volatile memory.” However, Criss, in an analogous art, teaches wherein the primary memory comprises volatile memory (In some examples, memory 112 may include volatile types of memory including, but not limited to, RAM, D-RAM, DDR SDRAM, SRAM, T-RAM or Z-RAM. [Criss PP 0020]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. As per claim 19, Hoekstra does not explicitly teach “wherein the primary memory comprises one or more volatile-memory-based chips comprising at least one of a parity space or a location for processing detection and/or correction codes.” However, Criss, in an analogous art, teaches wherein the primary memory comprises one or more volatile-memory-based chips (In some examples, memory 112 may include volatile types of memory including, but not limited to, RAM, D-RAM, DDR SDRAM, SRAM, T-RAM or Z-RAM. [Criss PP 0020]) comprising at least one of a parity space or a location for processing detection and/or correction codes (Parity bits used in an ECC scheme impose conditions on the data and the external ECC check bits written to memory 112. [Criss PP 0024]). Therefore, it would have been obvious for one of ordinary skill in the at before the effective filing date of the claimed invention to have modified the memory system disclosed by Hoekstra to incorporate Criss’s teachings of improved error correction, in order to improve reliability and correction performance (improved error detection and correction capabilities may be provided. [Criss PP 0017], increase the reliability of HBM3 or similar memory devices and reduce the cost and latency of error corrections. [Criss PP 0018]). Applying these teachings would have been a predictable variation for someone of ordinary skill in the art. Conclusion Any inquiry concerning this communication or earlier communications from the examiner should be directed to KAREEM FUAD ALHWAMDEH whose telephone number is (571)272-5501. The examiner can normally be reached Mon-Fri 7:30-5:00. 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