Searched hist:13516 (Results 1 - 21 of 21) sorted by relevance
| /gem5/src/systemc/ext/tlm_core/1/ | ||
| H A D | README.txt | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/systemc/ext/tlm_core/2/ | ||
| H A D | README.txt | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/systemc/tlm_core/2/generic_payload/ | ||
| H A D | SConscript | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | gp.cc | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | phase.cc | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/systemc/tlm_core/2/quantum/ | ||
| H A D | SConscript | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | global_quantum.cc | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/systemc/ext/tlm_utils/ | ||
| H A D | tlm_quantumkeeper.h | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/systemc/ext/ | ||
| H A D | tlm | 13516:315f10e2567b Tue Dec 11 02:02:00 EST 2018 Gabe Black <gabeblack@google.com> systemc: Remove redundant tlm_ prefixes from file names. We already know those files belong to tlm because of the directory they're in. Removing the prefix makes the paths of the headers less enormously long. Change-Id: I869e58fae904162f353bb31f4c0919fba08dffa6 Reviewed-on: https://gem5-review.googlesource.com/c/15059 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/base/ | ||
| H A D | refcnt.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/cpu/o3/probe/ | ||
| H A D | elastic_trace.cc | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/cpu/ | ||
| H A D | base_dyn_inst_impl.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | base_dyn_inst.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| /gem5/src/cpu/o3/ | ||
| H A D | lsq.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | lsq_impl.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | lsq_unit.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | inst_queue_impl.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | iew_impl.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | lsq_unit_impl.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | cpu.hh | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
| H A D | cpu.cc | 13590:d7e018859709 Mon Feb 13 04:41:00 EST 2017 Rekai Gonzalez-Alberquilla <rekai.gonzalezalberquilla@arm.com> cpu-o3: O3 LSQ Generalisation This patch does a large modification of the LSQ in the O3 model. The main goal of the patch is to remove the 'an operation can be served with one or two memory requests' assumption that is present in the LSQ and the instruction with the req, reqLow, reqHigh triplet, and generalising it to operations that can be addressed with one request, and operations that require many requests, embodied in the SingleDataRequest and the SplitDataRequest. This modification has been done mimicking the minor model to an extent, shifting the responsibilities of dealing with VtoP translation and tracking the status and resources from the DynInst to the LSQ via the LSQRequest. The LSQRequest models the information concerning the operation, handles the creation of fragments for translation and request as well as assembling/splitting the data accordingly. With this modifications, the implementation of vector ISAs, particularly on the memory side, become more rich, as the new model permits a dissociation of the ISA characteristics as vector length, from the microarchitectural characteristics that govern how contiguous loads are executing, allowing exploration of different LSQ to DL1 bus widths to understand the tradeoffs in complexity and performance. Part of the complexities introduced stem from the fact that gem5 keeps a large amount of metadata regarding, in particular, memory operations, thus, when an instruction is squashed while some operation as TLB lookup or cache access is ongoing, when the relevant structure communicates to the LSQ that the operation is over, it tries to access some pieces of data that should have died when the instruction is squashed, leading to asserts, panics, or memory corruption. To ensure the correct behaviour, the LSQRequest rely on assesing who is their owner, and self-destroying if they detect their owner is done with the request, and there will be no subsequent action. For example, in the case of an instruction squashed whal the TLB is doing a walk to serve the translation, when the translation is served by the TLB, the LSQRequest detects that the instruction was squashed, and as the translation is done, no one else expect to access its information, and therefore, it self-destructs. Having destroyed the LSQRequest earlier, would lead to wrong behaviour as the TLB walk may access some fields of it. Additional authors: - Gabor Dozsa <gabor.dozsa@arm.com> Change-Id: I9578a1a3f6b899c390cdd886856a24db68ff7d0c Signed-off-by: Giacomo Gabrielli <giacomo.gabrielli@arm.com> Reviewed-on: https://gem5-review.googlesource.com/c/13516 Reviewed-by: Anthony Gutierrez <anthony.gutierrez@amd.com> Maintainer: Anthony Gutierrez <anthony.gutierrez@amd.com> |
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