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UNIX Weapons School Weekplan: Difference between revisions
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==Week 1: C/C++ development in the x86 UNIX environment== | |||
==Week 1: C/C++ development in the x86 | |||
* SHELL LIFE aka Things I Hope You Already Know | * SHELL LIFE aka Things I Hope You Already Know | ||
Line 11: | Line 7: | ||
** effective use of interactive shells | ** effective use of interactive shells | ||
** shell scripting idioms. | ** shell scripting idioms. | ||
** rant: code is data and data is code so keep your home directory in source control | |||
* HOW COAL BECOMES CAT PICTURES aka Attack of the clone()s | * HOW COAL BECOMES CAT PICTURES aka Attack of the clone()s | ||
** UEFI. UNIX boot sequence. | ** UEFI. UNIX boot sequence. | ||
Line 17: | Line 14: | ||
** lsof, netstat, memstat, etc | ** lsof, netstat, memstat, etc | ||
* C/C++ UNIX DEVELOPMENT aka Onward Christian Soldiers | * C/C++ UNIX DEVELOPMENT aka Onward Christian Soldiers | ||
** Highlights of GCC, G++, LLVM, Clang, ICC, and NVCC. | ** Highlights of [[GCC]], G++, LLVM, Clang, ICC, and NVCC. | ||
** [[GNU Make]] | |||
** strace, ltrace, ptrace(). | ** strace, ltrace, ptrace(). | ||
** GDB tricks. | ** GDB tricks. | ||
Line 24: | Line 22: | ||
** Linker tricks both stupid and less stupid. | ** Linker tricks both stupid and less stupid. | ||
** The C and C++ machine models. | ** The C and C++ machine models. | ||
* THE WORLD FATHER aka UNIX | |||
** The Linux virtual memory implementation on x86 | |||
** The FreeBSD/Dragonfly virtual memory implementation | |||
** The Linux process schedulers | |||
** The Linux I/O schedulers | |||
* OUR EARTH MOTHERS aka C/C++ | * OUR EARTH MOTHERS aka C/C++ | ||
** The system call interface. | ** The system call interface. | ||
** Process-level memory management. | ** Process-level memory management. | ||
** The C standard library. | ** The C standard library. | ||
** The STL. | ** [[X Macros|Xmacros]] / The STL. | ||
** A glimpse of template metaprogramming | ** A glimpse of template metaprogramming | ||
Line 37: | Line 40: | ||
**The memory hierarchy. | **The memory hierarchy. | ||
** Branch prediction. | ** Branch prediction. | ||
** SIMD. | ** [[SIMD]]. | ||
** Memory fences. | ** Memory fences. | ||
** Transactional memory. | ** Transactional memory. | ||
Line 51: | Line 54: | ||
* ZERO-COPY I/O aka Now We're Getting Somewhere. | * ZERO-COPY I/O aka Now We're Getting Somewhere. | ||
** Mmap and shared memory. | ** Mmap and shared memory. | ||
** TLB invalidation and IPIs | |||
** CLONE_VM and a glimpse of threads. | ** CLONE_VM and a glimpse of threads. | ||
** RDMA. The PCIe bus. | ** RDMA. The PCIe bus. | ||
Line 67: | Line 71: | ||
* IN THE GRIM FUTURE OF WEEK 3 THERE ARE NO AKAs, ONLY ALGORITHMS | * IN THE GRIM FUTURE OF WEEK 3 THERE ARE NO AKAs, ONLY ALGORITHMS | ||
* Searching small spaces: Constant sorts. Dancing links. | * Searching small spaces: Constant sorts (sorting networks). Dancing links. Timer wheels. | ||
* Searching large spaces: Trees | * Searching large spaces: Trees. PATRICIA tries. Skip lists. Suffix trees. Automata search. Interval trees. | ||
* Searching by content: Hashes | * Searching by content: Hashes. Algorithmic complexity attacks. Universal hashes. Cuckoo hashing. Adaptive perfect hashes. | ||
* Searching huge spaces: | * Searching huge spaces: [[VLHU]]. Enumeration by method of linear congruence and other space-filling parlor tricks. | ||
* Real-time machine learning: Support vector machines. Non-negative matrix factorization. Hierarchal hashing. Hidden Markov models. | * Real-time machine learning: Support vector machines. Non-negative matrix factorization. Hierarchal hashing. Hidden Markov models. | ||
* Three impossible things before breakfast: Detecting an infinite loop, transforming an infinite list, and computing without executing. | * Three impossible things before breakfast: Detecting an infinite loop, transforming an infinite list, and computing without executing. | ||
Line 77: | Line 81: | ||
* select(), poll(), interaction with signals | * select(), poll(), interaction with signals | ||
* Linux's epoll, FreeBSD's kqueue. Level- vs edge-triggered events. | * Linux's epoll, FreeBSD's kqueue. Level- vs edge-triggered events. | ||
** Algorithms for oneshot edge-triggered interfaces. Asynchronous I/O on POSIX systems. | |||
* Everything as events: timerfd, signalfd, V_NODE | * Everything as events: timerfd, signalfd, V_NODE | ||
* Wrapping pthread events | * Wrapping pthread events. Multithreaded event engines. Work queues, work stealing, tasklets. | ||
** Digression: Kernel threads and interrupt handlers | |||
* Robust systems and judicious fork()ing | * Robust systems and judicious fork()ing | ||
* libev, libevent, libtorque | * libev, libevent, libtorque | ||
==Week 4: Compilers and their limitations | ==Week 4: [[Compiler Design|Compilers]] and their limitations== | ||
* SSA, aka Planet of the Compilers | * SSA and Basic Blocks, aka Planet of the Compilers | ||
* The Banerjee Test and the Polyhedral Model, aka Beneath the Planet of the Compilers | * The Banerjee Test and the Polyhedral Model, aka Beneath the Planet of the Compilers | ||
* The limits of compiler-based optimization, aka Escape from the Planet of the Compilers | * The limits of compiler-based optimization, aka Escape from the Planet of the Compilers | ||
* Inline assembly, aka Conquest of the Planet of the Compilers | * Inline assembly, aka Conquest of the Planet of the Compilers | ||
* PGO and Genetic-O aka Battle for the Planet of the Compilers | * PGO and Genetic-O aka Battle for the Planet of the Compilers | ||
==Week 5== | ==Week 5== | ||
=== | ===Allotrios=== | ||
* Windows aka Unfathomably Wretched Function Naming: I/O Completion Ports. With Fibers come Heaps. | * Windows aka Unfathomably Wretched Function Naming: I/O Completion Ports. With Fibers come Heaps. | ||
* Libraries: objdump, nm, and how to design a shared library. | * Libraries: objdump, nm, and how to design a shared library. | ||
* Internationalization. UTF8 | |||
* Unpleasant Details of the UNIX Environment aka What Stevens Forgot to Tell You. | * Unpleasant Details of the UNIX Environment aka What Stevens Forgot to Tell You. | ||
** The OOM killer. | ** The OOM killer. | ||
Line 113: | Line 120: | ||
* Parallelism among tasks | * Parallelism among tasks | ||
* Algorithms simulating parallelism and nondeterminism. | * Algorithms simulating parallelism and nondeterminism. | ||
* POSIX threads. Userspace threading. Coroutines. | * [[Pthreads|POSIX threads]]. Userspace threading. Coroutines. | ||
* Parallel languages and libraries. IPP and TBB. | * Parallel languages and libraries. IPP and TBB. | ||
==Week 7: Effective use of intranets and the Internet== | ==Week 7: Effective use of intranets and the Internet== | ||
* Sampling theory of Nyquist | |||
* | * Queueing theory of Kleinrock. The Linux packet queue disciplines. | ||
* Queueing theory of Kleinrock. The Linux packet queue disciplines | |||
* The Internet backbone. Preserving service via anycast networking. Threats to the Internet. PMTUD / MSS black holes. | * The Internet backbone. Preserving service via anycast networking. Threats to the Internet. PMTUD / MSS black holes. | ||
* Bufferbloat. Perils of the end-user network. Hardware design of fast networking devices. The CODEL queue | * Bufferbloat. Perils of the end-user network. Hardware design of fast networking devices. The CODEL and CAKE queue disciplines. | ||
* IPv6. Algorithms for IPv6. Zeroconf. PXE. Ad-hoc and mesh networking. Algorithms for fragmentation and sequencing. Intranet threats. | * IPv6. Algorithms for IPv6. Zeroconf. PXE. Ad-hoc and mesh networking. Algorithms for fragmentation and sequencing. Intranet threats. | ||
* Packet sockets. Linux's netlink(7). | * [[Packet sockets]]. Linux's netlink(7). | ||
* Local topology discovery | |||
==Week 8: Heterogeneity== | |||
===Hardware=== | |||
* TCP offload engines | |||
* SolarFlare's OpenPacket | |||
* Microsoft AMP | |||
* NVIDIA's [[CUDA]] | |||
* OpenCL | |||
===Software=== | |||
* System / guest emulation | |||
* Transmeta CMS (Code Morphing Software) | |||
* Popek and Goldberg virtualization requirements / KVM / Xen | |||
==Week | ==Week 9: The future of systems programming== | ||
* C++11 | |||
* Amorphous computing | |||
* RAIN/RAIM, EMC-aware programming | |||
* COMA, ccNUMA, directories, SCI, SCA | |||
* Computational memory | |||
* Software-defined networking | |||
* MRAM / FeRam / PRAM / SONOS |
Latest revision as of 22:26, 5 April 2023
Week 1: C/C++ development in the x86 UNIX environment
- SHELL LIFE aka Things I Hope You Already Know
- Job control
- GNU readline
- SSH tricks
- effective use of interactive shells
- shell scripting idioms.
- rant: code is data and data is code so keep your home directory in source control
- HOW COAL BECOMES CAT PICTURES aka Attack of the clone()s
- UEFI. UNIX boot sequence.
- Everything you wanted to know about /dev and /sys and /proc but never found out.
- Where a process comes from, what composes it while alive, and where it goes when it dies.
- lsof, netstat, memstat, etc
- C/C++ UNIX DEVELOPMENT aka Onward Christian Soldiers
- THE WORLD FATHER aka UNIX
- The Linux virtual memory implementation on x86
- The FreeBSD/Dragonfly virtual memory implementation
- The Linux process schedulers
- The Linux I/O schedulers
- OUR EARTH MOTHERS aka C/C++
- The system call interface.
- Process-level memory management.
- The C standard library.
- Xmacros / The STL.
- A glimpse of template metaprogramming
Week 2: Systems methods for efficient use of memory and buses
- YOUR FRIEND THE COMPUTER aka Computer Architecture in Thirty Minutes.
- Intel Core processors.
- The memory hierarchy.
- Branch prediction.
- SIMD.
- Memory fences.
- Transactional memory.
- Predication.
- DOUBLE-COPIED I/O aka Definitely More Copying Than Required.
- C/C++ I/O using stdio.h and streams. Interactions of standard library buffering and I/O.
- Semantics and side-effects of the I/O model.
- popen() and the seven thousand ways it can be incorrectly used.
- SINGLE-COPIED I/O aka Not Good Enough, Try Again.
- UNIX I/O using bytestreams, datagrams, and sequenced packets.
- The AF_UNIX namespace.
- That mysterious EAGAIN.
- ZERO-COPY I/O aka Now We're Getting Somewhere.
- Mmap and shared memory.
- TLB invalidation and IPIs
- CLONE_VM and a glimpse of threads.
- RDMA. The PCIe bus.
- NEGATIVE-COPY I/O aka Oh Shit! There Go My Pages!
- COW games.
- sendfile() and TCP.
- splice() your way to success.
- MORE MEMORY aka When in Doubt, Blame Memory.
- Interactions of disk, disk paging, memory paging, caching, registers, and multiprocessing.
- Memory characteristics of long-lived programs.
- Life in a post-paged world.
- Computational memory.
- NUMA and you.
Week 3: Algorithmic methods for efficient use of CPU and memory
- IN THE GRIM FUTURE OF WEEK 3 THERE ARE NO AKAs, ONLY ALGORITHMS
- Searching small spaces: Constant sorts (sorting networks). Dancing links. Timer wheels.
- Searching large spaces: Trees. PATRICIA tries. Skip lists. Suffix trees. Automata search. Interval trees.
- Searching by content: Hashes. Algorithmic complexity attacks. Universal hashes. Cuckoo hashing. Adaptive perfect hashes.
- Searching huge spaces: VLHU. Enumeration by method of linear congruence and other space-filling parlor tricks.
- Real-time machine learning: Support vector machines. Non-negative matrix factorization. Hierarchal hashing. Hidden Markov models.
- Three impossible things before breakfast: Detecting an infinite loop, transforming an infinite list, and computing without executing.
- Yes, You Really Have to Learn Fourier Transforms.
Algorithms for event systems
- select(), poll(), interaction with signals
- Linux's epoll, FreeBSD's kqueue. Level- vs edge-triggered events.
- Algorithms for oneshot edge-triggered interfaces. Asynchronous I/O on POSIX systems.
- Everything as events: timerfd, signalfd, V_NODE
- Wrapping pthread events. Multithreaded event engines. Work queues, work stealing, tasklets.
- Digression: Kernel threads and interrupt handlers
- Robust systems and judicious fork()ing
- libev, libevent, libtorque
Week 4: Compilers and their limitations
- SSA and Basic Blocks, aka Planet of the Compilers
- The Banerjee Test and the Polyhedral Model, aka Beneath the Planet of the Compilers
- The limits of compiler-based optimization, aka Escape from the Planet of the Compilers
- Inline assembly, aka Conquest of the Planet of the Compilers
- PGO and Genetic-O aka Battle for the Planet of the Compilers
Week 5
Allotrios
- Windows aka Unfathomably Wretched Function Naming: I/O Completion Ports. With Fibers come Heaps.
- Libraries: objdump, nm, and how to design a shared library.
- Internationalization. UTF8
- Unpleasant Details of the UNIX Environment aka What Stevens Forgot to Tell You.
- The OOM killer.
- Atime.
- Fragmentation, a spectre haunting your userspace.
- Hardware failures.
- Build systems aka They're All Shite
Parallelism I: Hardware Parallelism
- Models of parallelism aka They're All Shite
- Bit-level parallelism
- Parallelism within a register
- Parallelism among instructions
- Parallelism among memory accesses
Week 6: Parallelism II: Software Parallelism
- Parallelism among tasks
- Algorithms simulating parallelism and nondeterminism.
- POSIX threads. Userspace threading. Coroutines.
- Parallel languages and libraries. IPP and TBB.
Week 7: Effective use of intranets and the Internet
- Sampling theory of Nyquist
- Queueing theory of Kleinrock. The Linux packet queue disciplines.
- The Internet backbone. Preserving service via anycast networking. Threats to the Internet. PMTUD / MSS black holes.
- Bufferbloat. Perils of the end-user network. Hardware design of fast networking devices. The CODEL and CAKE queue disciplines.
- IPv6. Algorithms for IPv6. Zeroconf. PXE. Ad-hoc and mesh networking. Algorithms for fragmentation and sequencing. Intranet threats.
- Packet sockets. Linux's netlink(7).
- Local topology discovery
Week 8: Heterogeneity
Hardware
- TCP offload engines
- SolarFlare's OpenPacket
- Microsoft AMP
- NVIDIA's CUDA
- OpenCL
Software
- System / guest emulation
- Transmeta CMS (Code Morphing Software)
- Popek and Goldberg virtualization requirements / KVM / Xen
Week 9: The future of systems programming
- C++11
- Amorphous computing
- RAIN/RAIM, EMC-aware programming
- COMA, ccNUMA, directories, SCI, SCA
- Computational memory
- Software-defined networking
- MRAM / FeRam / PRAM / SONOS