Linux yadrosi - Linux kernel

Linux yadrosi
Tux
Tux Linuxning maskoti bo'lgan pingvin[1]
Linux 3.0.0 boot.png
Linux yadrosi 3.0.0 yuklash
TuzuvchiLinus Torvalds va minglab hamkasblar
YozilganC (95,7%) va boshqa tillar, shu jumladan C ++ va yig'ilish[2]
OS oilasiUnixga o'xshash
Dastlabki chiqarilish0.02 (1991 yil 5 oktyabr); 29 yil oldin (1991-10-05))
Oxirgi nashr5.9.11[3] (2020 yil 24-noyabr); 2 kun oldin (2020-11-24)) [±]
Oxirgi oldindan ko'rish5.10-rc5[4] (2020 yil 22-noyabr); 4 kun oldin (2020-11-22)) [±]
Ombor
Buni Vikidatada tahrirlash
Mavjud:Ingliz tili
Kernel turiMonolitik
LitsenziyaGNU GPLv2 (faqat) mos keladigan GPL variantlari ostida yoki BSD, MIT kabi ruxsat beruvchi litsenziyalar ostida ba'zi kodlar bilan[5]
Rasmiy veb-saytwww.kernel.org

The Linux yadrosi a bepul va ochiq manbali,[6][7] monolitik, modulli,[8] ko'p vazifali, Unixga o'xshash operatsion tizim yadro.[9] U tomonidan 1991 yilda yaratilgan va yaratilgan Linus Torvalds[10] uning uchun i386 asoslangan kompyuter va tez orada u yadro sifatida qabul qilindi GNU operatsion tizimi,[11] sifatida yaratilgan ochiq manba va bepul dasturiy ta'minot va UNIX-ga asoslangan bo'lib, uning oqibati Unix urushlari.[12] O'shandan beri u ko'p narsalarni tug'dirdi operatsion tizimning tarqatilishi, odatda ham deyiladi Linux.

Linux turli xil hisoblash tizimlarida joylashtirilgan, masalan o'rnatilgan qurilmalar, mobil qurilmalar (jumladan, uni ishlatishda Android operatsion tizim), shaxsiy kompyuterlar, serverlar, meynframlar va superkompyuterlar.[13] Uni oddiy arxitekturalar va oddiy buyruqlar turkumidan foydalangan holda bir nechta foydalanish stsenariylari uchun moslashtirish mumkin (ya'ni kompilyatsiya qilinishidan oldin uning manba kodini qo'lda tahrirlash talab qilinmasdan);[14][15][16] imtiyozli foydalanuvchilar, shuningdek, ish vaqtida yadro parametrlarini aniq sozlashi mumkin.[17][18][19] Linux yadrosi kodining katta qismi GNU kengaytmalari GCC[20][21] standartga muvofiq C dasturlash tili va me'morchilikdan foydalangan holda maxsus ko'rsatmalar (ISA ). Bu juda optimallashtirilgan bajariladigan faylni ishlab chiqaradi (vmlinux ) xotira maydonidan foydalanish va vazifalarni bajarish vaqtiga nisbatan.[22]

Kundalik rivojlanish bo'yicha munozaralar Linux yadrosi pochta ro'yxati (LKML). O'zgarishlar versiyani boshqarish tizimi yordamida kuzatiladi git Torvalds tomonidan buyurtma qilingan almashtirish sifatida yaratilgan BitKeeper. Umuman olganda Linux ostida GNU umumiy jamoat litsenziyasi versiya 2 (GPLv2),[23] lekin u boshqa mos litsenziyalar ostida bir nechta fayllarni o'z ichiga oladi,[5] va foydalanuvchi maydoni API uchun vaqtinchalik ozod qilish sarlavha fayllari (UAPI).

Tarix

Shuningdek qarang: Linux tarixi va Linux yadrosi versiyasi tarixi
Linus Torvalds Dyusseldorfdagi LinuxCon Europe 2014 ko'rgazmasida mikrofon bilan

1991 yil aprelda, Linus Torvalds, o'sha paytda 21 yoshli yigit Kompyuter fanlari talaba Xelsinki universiteti, Finlyandiya, operatsion tizim uchun ba'zi oddiy g'oyalar ustida ishlashni boshladi. U a bilan boshladi vazifani o'zgartiruvchi yilda Intel 80386 yig'ilish tili va a terminal drayveri. 1991 yil 25 avgustda Torvalds quyidagilarni e'lon qildi comp.os.minix, a yangiliklar guruhi kuni Usenet:[24]

Men (bepul) operatsion tizimni (shunchaki xobbi, gnu kabi katta va professional bo'lmaydi) 386 (486) uchun qilyapman DA klonlar. Bu aprel oyidan beri tayyorlanib kelinmoqda. Minix-da odamlar yoqtiradigan / yoqtirmaydigan narsalar haqida men har qanday fikr bildirmoqchiman, chunki mening operatsion tizimim unga o'xshash (fayl tizimining bir xil jismoniy joylashuvi (amaliy sabablarga ko'ra) boshqa narsalar qatorida). bosh (1.08) va gcc (1.40), va narsalar ishlayotganga o'xshaydi. Bu shuni anglatadiki, men bir necha oy ichida biron bir amaliy narsaga ega bo'laman [...] Ha - bu har qanday minix kodidan ozod va unda ko'p yo'nalishli fs mavjud. Protable emas [sic ] (386 ta vazifani almashtirish va hokazolarni ishlatadi) va ehtimol u hech qachon AT-harddisklardan boshqasini qo'llab-quvvatlamaydi, chunki menda bor narsa :-(.

1991 yil 17 sentyabrda Torvalds Linuxning 0.01 versiyasini tayyorladi va Finlyandiya universiteti va tadqiqot tarmog'ining "ftp.funet.fi" - FTP serverini joylashtirdi (FUNET ). Hatto bajarib bo'lmaydigan edi, chunki uning kodi kompilyatsiya va ijro etish uchun hali ham Minixga muhtoj edi.[25]

1991 yil 5 oktyabrda Linus Linuxning 0.02 versiyasining birinchi "rasmiy" versiyasini e'lon qildi.[26] Shu nuqtada Linux Bash, GCC va boshqa ba'zi GNU yordam dasturlarini ishga tushira oldi:[26][25]

Bir oy oldin aytib o'tganimdek, men AT-386 kompyuterlari uchun Minix-lookalike-ning bepul versiyasi ustida ishlayapman. Nihoyat, u foydalanishga yaroqli darajaga yetdi (garchi siz xohlagan narsaga bog'liq bo'lmasa ham) va men kengroq tarqatish uchun manbalarni ochib berishga tayyorman. Bu faqat 0.02 versiyasidir ... lekin men uning ostida bash, gcc, gnu-make, gnu-sed, kompress va boshqalarni muvaffaqiyatli ishladim.

Shundan so'ng, ko'plab odamlar loyihaga kod qo'shdilar va ba'zi bir ishlab chiquvchilarni qo'shdilar MINIX jamiyat. O'sha paytda GNU loyihasi bepul operatsion tizim uchun zarur bo'lgan ko'plab tarkibiy qismlarni yaratgan edi, ammo o'z yadrosi, GNU Hurd, to'liq bo'lmagan va mavjud emas edi. The Berkli dasturiy ta'minotini tarqatish hali o'zini ozod qilmagan edi qonuniy og'irliklar. Dastlabki versiyalarning cheklangan ishlashiga qaramay, Linux tezda ishlab chiquvchilar va foydalanuvchilarga ega bo'ldi.

Torvalds yadroga 0 versiyasini tayinladi, bu uning asosan sinov uchun mo'ljallanganligini va unumli foydalanishga mo'ljallanmaganligini ko'rsatdi.[27] 1991 yil dekabrda chiqarilgan 0.11 versiyasi birinchisi edi o'z-o'zini tashkil qiladi Linux, chunki u bir xil yadro bilan ishlaydigan kompyuter tomonidan tuzilishi mumkin edi.

1992 yil fevral oyida Torvalds 0.12 versiyasini chiqarganda, u qabul qildi GNU umumiy jamoat litsenziyasi tijorat qayta taqsimlanishiga ruxsat bermagan oldingi o'z-o'zidan tuzilgan litsenziyasiga nisbatan 2-versiyasi (GPLv2).[28] Aksincha Unix, barchasi manba fayllari Linuxdan bepul foydalanish mumkin, shu jumladan qurilma drayverlari.[29] Linuxning dastlabki muvaffaqiyati butun dunyo bo'ylab dasturchilar va sinovchilar tomonidan boshqarildi. Ko'magida POSIX API-lar, agar kerak bo'lsa, yadro manzil maydoniga kirish nuqtasi vazifasini bajaradigan libC orqali Linux Unix uchun ishlab chiqilgan dasturiy ta'minot va dasturlarni ishga tushirishi mumkin.[30]

Linux yadrosi endi turli xil apparat arxitekturalarini qo'llab-quvvatlaydi, shu jumladan dasturiy ta'minot uchun umumiy platformani taqdim etadi mulkiy dasturiy ta'minot.

1992 yil 19-yanvarda yangi yangiliklar guruhiga birinchi xabar alt.os.linux taqdim etildi.[31] 1992 yil 31 martda yangiliklar guruhining nomi o'zgartirildi comp.os.linux.[32] Linux a monolit yadro a o'rniga mikrokernel o'rtasidagi bahs mavzusi bo'ldi Endryu S. Tanenbaum, MINIX va Torvalds yaratuvchisi.[33] The Tanenbaum - Torvalds bahslari 1992 yilda boshlangan Usenet guruh comp.os.minix yadro me'morchiligi haqida umumiy munozara sifatida.[34][35]

Linuxning 0.95 versiyasi birinchi bo'lib ishlashga qodir edi X oyna tizimi.[36] 1994 yil mart oyida Linux 1.0.0 176 250 satr kod bilan chiqarildi.[37] Bu foydalanish uchun mos bo'lgan birinchi versiya edi ishlab chiqarish muhiti.[27]

Uchinchi yoki to'rtta raqamlar bilan yadro uchun versiya tizimini ishga tushirdi katta ozod qilish, ikkinchisi kichik ozod qilish, uchinchisi esa qayta ko'rib chiqish.[38] O'sha paytda g'alati raqamlar voyaga etmagan relizlar ishlab chiqish va sinovlarga mo'ljallangan edi, shu bilan birga raqamlangan voyaga etmagan relizlar ishlab chiqarish uchun edi. Ixtiyoriy to'rtinchi raqam a ga tuzatishlar to'plamini ko'rsatdi qayta ko'rib chiqish.[27] Rivojlanish nashrlari ko'rsatildi -rc ("nomzodni ozod qilish") qo'shimchasi.

Amaldagi versiya raqamlashi yuqoridagilardan biroz farq qiladi. Toq va g'alati raqamlar tushirildi va aniq katta versiya endi bir butun sifatida olingan dastlabki ikkita raqam bilan ko'rsatiladi. Vaqt chegarasi keyingi rivojlanish uchun ochiq katta, -rcN qo'shimchasi n'ni aniqlash uchun ishlatiladi nomzodni ozod qilish keyingi versiyasi uchun.[39] Masalan, 4.16 versiyasining chiqarilishidan oldin yettita 4.16-rcN (-rc1 dan -rc7 gacha) bo'lgan. Barqaror chiqarilgandan so'ng, unga xizmat ko'rsatish "barqaror jamoaga" topshiriladi. Barqaror nashrlarning vaqti-vaqti bilan yangilanishi uchta raqamlash sxemasi bilan aniqlanadi (masalan, 4.13.1, 4.13.2, ..., 4.13.16). .[39]

1.2 versiyasi (1995 yil 7 martda chiqarilgan)[40] ga asoslangan protsessorlardan foydalangan holda kompyuter tizimlarini qo'llab-quvvatladi Alfa, SPARC va MIPS me'morchilik.[iqtibos kerak ]

Yadroning 1.3-versiyasidan so'ng Torvalds Linux yangisini ishlab chiqarishni ta'minlash uchun etarli darajada rivojlangan deb qaror qildi katta soni, shuning uchun u 1996 yil iyun oyida 2.0.0 versiyasini chiqardi.[41][42] Seriya 41 ta nashrni o'z ichiga olgan. 2.0 ning asosiy xususiyati qo'llab-quvvatlash edi nosimmetrik ko'p ishlov berish (SMP) va ko'proq turdagi protsessorlarni qo'llab-quvvatlash.

2.0 versiyasidan boshlab Linux aniq apparat maqsadlarini tanlash va arxitekturaga xos xususiyatlar va optimallashtirishni yoqish uchun sozlanishi mumkin.[30] The make * config buyruqlar oilasi qurish vaqtinchalik yadro dasturlarini yaratish uchun minglab variantlarni yoqish va sozlash uchun ishlatiladi (vmlinux ) va yuklanadigan modullar.[14][15]

2.2-versiya, 1999 yil 20-yanvarda chiqarilgan,[43] "Katta yadro qulfini" olib tashladi, bu global edi spinlock va takomillashtirilgan SMP-ni qo'llab-quvvatladi va qo'llab-quvvatladi m68k va PowerPC me'morchiligi va yangi qo'shildi fayl tizimlari (faqat o'qish uchun qo'llab-quvvatlashni o'z ichiga oladi Microsoft "s NTFS ).[44] 1999 yilda IBM o'zining qo'llab-quvvatlashi uchun Linux 2.2.13 kodiga o'z yamalarini nashr etdi S / 390 me'morchilik.[45]

2.4.0 versiyasi, 2001 yil 4-yanvarda chiqarilgan,[46] uchun yordam mavjud ISA Plug va Play, USB va Kompyuter kartalari.[47] Bu shuningdek, qo'llab-quvvatlashni o'z ichiga olgan PA-RISC protsessor Hewlett-Packard. 2.4 uchun ishlab chiqish.x Serial davomiyligi davomida ko'proq funktsiyalar, shu jumladan qo'llab-quvvatlashni o'z ichiga olganligi sababli biroz o'zgarib ketdi Bluetooth, Mantiqiy hajm menejeri (LVM) versiyasi 1, RAID qo'llab-quvvatlash, InterMezzo va ext3 fayl tizimlari.

2.6.0 versiyasi 2003 yil 17-dekabrda chiqarilgan.[48] 2.6 uchun rivojlanish.x ketma-ketligi davomida yangi xususiyatlarni o'z ichiga olgan holda yanada o'zgargan. 2.6 seriyadagi o'zgarishlar qatoriga quyidagilar kiradi: integratsiya linClinux asosiy yadro manbalariga, PAE qo'llab-quvvatlash, bir nechta yangi qatorlarni qo'llab-quvvatlash CPU, Advanced Linux Sound Architecture (ALSA) ning asosiy yadro manbalariga qo'shilishi, 2 tagacha qo'llab-quvvatlanishi32 foydalanuvchilar (2 tadan)16), 2 ga qadar qo'llab-quvvatlash29 jarayon identifikatorlari (faqat 64 bitli, 32 bitli kamarlar hali ham 2 bilan cheklangan15),[49] har bir turdagi qurilmalar va qurilmalar sonini sezilarli darajada oshirdi, yaxshilandi 64-bit qo'llab-quvvatlash, qo'llab-quvvatlash fayl tizimlari fayl o'lchamlarini 16 tagacha qo'llab-quvvatlaydi terabayt, yadro ichidagi imtiyoz, uchun qo'llab-quvvatlash Mahalliy POSIX mavzu kutubxonasi (NPTL), Linux-ning foydalanuvchi rejimi asosiy yadro manbalariga qo'shilish, SELinux asosiy yadro manbalariga qo'shilish, InfiniBand qo'llab-quvvatlash va yana ko'p narsalar.

Bundan tashqari, 2.6 dan boshlangan fayl tizimlarining keng tanlovi qo'shilgan.x relizlar: endi yadro Linux uchun mo'ljallangan ba'zi bir fayl tizimlarini qo'llab-quvvatlaydi ext3, ext4, FUSE, Btrfs,[50] va shunga o'xshash boshqa operatsion tizimlarning mahalliylari JFS, XFS, Minix, Kseniks, Irix, Solaris, Tizim V, Windows va MS-DOS.[51]

2005 yilda barqaror jamoa odamlar ishlashlari mumkin bo'lgan yadro daraxti yo'qligiga javoban shakllangan xatolarni tuzatish va u yangilanib turaveradi barqaror versiyalar.[52] 2008 yil fevral oyida Linux-keyingi daraxt keyingi rivojlanish tsikli davomida birlashtirilishi kerak bo'lgan yamaqlar yig'iladigan joy sifatida xizmat qilish uchun yaratilgan.[53][54] Bir nechta quyi tizimni qo'llab-quvvatlovchilar ham qo'shimchani qabul qildilar -Keyingisi kodni o'z ichiga olgan daraxtlar uchun, ular keyingi chiqarish tsikliga kiritish uchun taqdim etishni anglatadi. 2014 yil yanvar holatiga ko'ra, Linuxning rivojlanish versiyasi noma'lum filialda joylashgan Linux-keyingi.[55]

Ilgari Linux avtomatlashtirilgan yordamisiz saqlanib turardi manba kodini boshqarish tizim 2002 yilgacha rivojlanishga o'tdi BitKeeper. U Linux ishlab chiquvchilari uchun bemalol mavjud edi, ammo bunday emas edi bepul dasturiy ta'minot. 2005 yilda, sa'y-harakatlar tufayli teskari muhandis dasturiy ta'minotga ega bo'lgan kompaniya Linux hamjamiyatini qo'llab-quvvatlashni bekor qildi. Bunga javoban Torvalds va boshqalar yozgan Git. Yangi tizim bir necha hafta ichida yozildi va ikki oy ichida uni ishlatgan birinchi rasmiy yadro chiqarildi.[56]

2.6 yadro seriyasining tarixi haqida batafsil ma'lumotni 2.6 yadro seriyasining manba kodini chiqarish maydonidagi ChangeLog fayllarida topish mumkin. kernel.org.[57]

Torvalds tomonidan Linuxning 20 yilligi 2011 yil iyul oyida 3.0.0 yadrosi versiyasi chiqarilishi bilan nishonlandi.[41] 2.6 versiyasi 8 yildan beri versiya raqami bo'lib, yangi 26 3.x-ni 2.6.40 + x deb hisoblaydigan shaxsiyat yadroga qo'shilishi kerak edi, shunda eski dasturlar ishlaydi.[58]

3.0 versiyasi 2011 yil 22-iyulda chiqdi.[59] 2011 yil 30-mayda Torvalds katta o'zgarish "HECH NIMA. Mutlaqo hech narsa emas" deb e'lon qildi. va so'radi: "... kelgusi versiyani nafaqat yangi porloq raqamni, balki yaxshi yadroni ham yaratganimizga ishonch hosil qilaylik."[60] Rivojlanish jarayoni kutilgan 6-7 xaftadan so'ng, u Linuxning 20 yilligiga yaqin chiqarilishi kerak edi.

2012 yil 11 dekabrda Torvalds qo'llab-quvvatlashni olib tashlash orqali yadro murakkabligini kamaytirishga qaror qildi i386 3.7 yadro seriyasini so'nggi protsessorga aylantirib, asl protsessorni qo'llab-quvvatlaydi.[61][62] Xuddi shu ketma-ket birlashtirilgan qo'llab-quvvatlash ARM protsessor.[63]

3.11 versiyasi, 2013 yil 2 sentyabrda chiqarilgan,[64] kabi yangi xususiyatlarni qo'shadi O_TMPFILE uchun bayroq ochiq (2) vaqtinchalik fayl zaifliklarini kamaytirish, eksperimental AMD Radeon dinamik quvvatni boshqarish, kam kechiktirilgan tarmoq so'rovi va zswap (siqilgan almashtirish keshi).[65]

Raqamlarning o'zgarishi 2.6.39 dan 3.0 ga va 3.19 dan 4.0 gacha, hech qanday mazmunli texnik farqlanishni o'z ichiga olmaydi. Katta kichik raqamlardan qochish uchun asosiy versiya raqami oshirildi.[59][66] Barqaror 3.x.y yadrolari 2015 yil fevral oyida 3.19 ga qadar chiqarildi.

2015 yil aprel oyida Torvalds 4.0 yadrosi versiyasini chiqardi.[41] 2015 yil fevraliga qadar Linux 1200 dan ortiq kompaniyalarning, shu jumladan dunyodagi eng yirik dasturiy ta'minot va apparat sotuvchilarning 12000 ga yaqin dasturchilaridan hissa qabul qildi.[67] 2015 yil iyun oyida chiqarilgan Linuxning 4.1 versiyasida deyarli 14000 dasturchi tomonidan qo'shilgan 19,5 milliondan ortiq satr kod mavjud.[68]

Jami 1.991 ishlab chiquvchilar, ulardan 334 nafari birinchi hamkorlar bo'lib, 5.8 versiyasiga 553000 dan ortiq satr kod qo'shdilar va 4.9 versiyasida ilgari saqlanib qolgan rekordni yangiladilar.[69]

Asosiy maqola: Operatsion tizimlardan foydalanish ulushi

Stack Overflow-ning 2019 yilgi yillik tadqiqotchilarining so'roviga ko'ra, barcha respondentlarning 53% dan ortig'i dasturiy ta'minot ishlab chiqardi Linux operatsion tizimi va taxminan 27% Android,[70] faqat taxminan 25% Linux asosidagi operatsion tizimlar bilan rivojlanadi.[71]

Veb-sayt serverlarining aksariyati foydalanadi Linux operatsion tizimi[72][73] va barchasi dunyodagi eng kuchli 500 ta superkompyuter Linux asosidagi ba'zi bir OSlardan foydalaning.[74]

Linux tarqatish yadro bilan biriktiring tizim dasturlari (masalan., GNU C kutubxonasi, tizimd va boshqalar Unix kommunal xizmatlar va xizmatkorlar ) va keng tanlov dasturiy ta'minot, lekin ularning foydalanish ulushi boshqa operatsion tizimlarga nisbatan ish stoli past.

Aksariyat qismini hisoblaydigan Android OS o'rnatilgan taglik mobil qurilmalar uchun barcha operatsion tizimlarning,[75][76][77] Linux yadrosining ortib borishi uchun javobgardir,[30] bilan birgalikda keng ko'lamda keng foydalanish o'rnatilgan qurilmalar.

Arxitektura

Shuningdek qarang: vmlinux
Linux yadrosi xaritasi

Linux bu monolit yadro modulli dizayn bilan (masalan, uni qo'shib olib tashlashi mumkin yuklanadigan yadro modullari ko'p funktsiyalarni faqat bepul bo'lmagan operatsion tizimlarning yopiq manbali yadrolarida mavjud bo'lganda qo'llab-quvvatlaydi:

Qurilma drayverlari va yadro kengaytmalari ishlaydi yadro maydoni (qo'ng'iroq 0 ko'pchilikda Markaziy protsessor me'morchilik ), ba'zi bir istisnolar mavjud bo'lsa-da, qo'shimcha qurilmalarga to'liq kirish huquqi bilan foydalanuvchi maydoni masalan, asoslangan fayl tizimlari FUSE / CUSE va UIO qismlari.[95][96] The grafik tizim aksariyat odamlar Linux bilan ishlatish yadro ichida ishlamaydi. Standart monolitik yadrolardan farqli o'laroq, qurilma drayverlari osongina sozlangan modullar, va tizim ishlayotganda yuklangan yoki tushirilgan, shuningdek ishlov berish uchun ma'lum sharoitlarda oldindan bo'shatilishi mumkin apparat uzilishlari to'g'ri va yaxshiroq qo'llab-quvvatlash uchun nosimmetrik ko'p ishlov berish.[80] Tanlovga ko'ra, Linuxda barqaror qurilma drayveri yo'q dastur ikkilik interfeysi.[97]

Linux odatda foydalanadi xotirani himoya qilish va virtual xotira va shuningdek ishlov bera oladi bir xil bo'lmagan xotiraga kirish,[98] ammo loyiha o'zlashtirdi mClinux bu shuningdek Linuxni ishga tushirishga imkon beradi mikrokontrollerlar virtual xotirasiz.[99]

Uskuna fayllar ierarxiyasida namoyish etiladi. Foydalanuvchi dasturlari qurilmalar drayverlari bilan / dev yoki / sys kataloglar.[100] Axborotlarni qayta ishlash shuningdek fayl tizimiga / prok katalog.[100]

Linux ichidagi turli qatlamlar, shuningdek, ular orasidagi ajratishni ko'rsatmoqda foydalanuvchi maydoni va yadro maydoni
Foydalanuvchi rejimiFoydalanuvchi dasturlariMasalan, bosh, LibreOffice, GIMP, Blender, 0 milodiy, Mozilla Firefox, va boshqalar.
Past darajadagi tizim komponentlari:Tizim xizmatkorlar:
tizimd, runit, logind, networkd, PulseAudio, ...		Oyna tizimi:
X11, Wayland, SurfaceFlinger (Android)		Boshqa kutubxonalar:
GTK +, Qt, EFL, SDL, SFML, FLTK, GNUstep, va boshqalar.		Grafika:
Mesa, AMD katalizatori, ...
C standart kutubxonasiochiq(), exec (), sbrk (), rozetka (), fopen (), calloc (), ... (2000 yilgacha subroutines )
glibc tezkor bo'lishni maqsad qilgan, musulmon va uClibc maqsadli o'rnatilgan tizimlar, bionik uchun yozilgan Android va boshqalar POSIX /SUS - mos keladi.
Kernel rejimiLinux yadrosistat, qo'shimchalar, dup, o'qing, ochiq, ioctl, yozmoq, mmap, yaqin, Chiqishva boshqalar (taxminan 380 ta tizim qo'ng'iroqlari)
Linux yadrosi Tizim qo'ng'irog'i interfeysi (SCI, bo'lishni maqsad qiladi POSIX /SUS - mos)[iqtibos kerak ]
Jarayonlarni rejalashtirish
kichik tizim		IPC
kichik tizim		Xotirani boshqarish
kichik tizim		Virtual fayllar
kichik tizim		Tarmoq
kichik tizim
Boshqa komponentlar: ALSA, DRI, evdev, LVM, qurilma xaritasi, Linux tarmoq rejalashtiruvchisi, Netfilter
Linux xavfsizlik modullari: SELinux, TOMOYO, AppArmor, Smack
Uskuna (Markaziy protsessor, asosiy xotira, ma'lumotlarni saqlash qurilmalari, va boshqalar.)

Interfeyslar

Asosiy maqolalar: Linux yadrosi interfeyslari va Linux yadrosi interfeyslari (Turkum)
Shuningdek qarang: Tizim qo'ng'irog'i, POSIX va Yagona UNIX spetsifikatsiyasi
To'rt interfeys ajratilgan: ikkitasi yadro ichki, ikkitasi yadro va foydalanuvchilar maydoni o'rtasida.

Linux UNIX-ning klonidir va unga yo'naltirilgan POSIX va Yagona UNIX spetsifikatsiyasi muvofiqlik.[101] Yadro shuningdek tizimga qo'ng'iroqlarni va Linuxga xos bo'lgan boshqa interfeyslarni taqdim etadi. Rasmiy yadroga qo'shilish uchun kod litsenziyalash qoidalariga muvofiq bo'lishi kerak.[23][5]

Linux Ilova ikkilik interfeysi (ABI) yadro va foydalanuvchi maydoni o'rtasida to'rt daraja barqarorlik mavjud (barqaror, sinov, eskirgan, olib tashlangan);[102] ammo tizim qo'ng'iroqlari buzmaslik uchun hech qachon o'zgarmasligi kutilmoqda foydalanuvchilar maydoni ularga ishonadigan dasturlar.[103]

Yuklanadigan yadro modullari (LKM), dizayni bo'yicha, barqaror ABIga tayanolmaydi.[104] Shuning uchun ular tizimga yangi yadro dasturini o'rnatishda har doim kompilyatsiya qilinishi kerak, aks holda ular yuklanmaydi. Amalga oshiriladigan yadroning ajralmas qismi bo'lish uchun tuzilgan daraxt ichidagi drayverlar (vmlinux ) qurilish jarayoni bilan statik ravishda bog'langan.

Shuningdek, yadro ichidagi API manba darajasining barqarorligiga kafolat yo'q[97] va shu sababli, qurilma drayverlari kod, shuningdek boshqa yadro quyi tizimining kodi yadro evolyutsiyasi bilan yangilanishi kerak. API-ni o'zgartiradigan har qanday ishlab chiquvchi, ularning o'zgarishi natijasida buzilgan har qanday kodni tuzatishi kerak.[105]

Kernel-to-userpace API

To'plami Linux yadrosi API foydalanuvchi dasturlariga ta'sir qiladigan interfeyslarni hisobga olgan holda UNIX va Linuxga xos asosda tuzilgan tizim qo'ng'iroqlari.[106] Tizim qo'ng'irog'i - bu Linux yadrosiga kirish nuqtasi.[107] Masalan, Linuxga xos bo'lganlar orasida oilalar guruhi mavjud klon (2) tizim qo'ng'iroqlari.[108] Ko'pgina kengaytmalarni a-da _GNU_SOURCE so'lini belgilash orqali yoqish kerak sarlavha fayli yoki foydalanuvchi-yer kodi tuzilayotganda.[109]

Tizim qo'ng'iroqlarini faqat imtiyozsiz foydalanuvchi makonidan imtiyozli yadro maydoniga o'tishni ta'minlaydigan yig'ish ko'rsatmalari yordamida chaqirish mumkin. qo'ng'iroq 0. Shu sababli C standart kutubxonasi (libC) ko'pgina Linux tizim qo'ng'iroqlari uchun o'ralgan vazifasini bajaradi, faqatgina kerak bo'lganda C funktsiyalarini namoyish qiladi.[110] chaqiruv jarayoni nomidan bajariladigan yadroga shaffof ravishda kirishi mumkin.[106] LibC tomonidan ta'sirlanmagan tizim qo'ng'iroqlari uchun, masalan. The tez foydalanuvchilar maydoni mutex (futex ),[111] kutubxona deb nomlangan funktsiyani taqdim etadi syscall (2) ularni aniq chaqirish uchun ishlatilishi mumkin.[112]

Soxta fayl tizimlari (masalan, sysfs va procfs fayl tizimlari) va maxsus fayllar (masalan, / dev / random, / dev / sda, / dev / tty va boshqalar) qo'shimcha yoki mantiqiy (dasturiy ta'minot) qurilmalarni ifodalovchi yadro ma'lumotlar tuzilmalari interfeysining yana bir qatlamini tashkil qiladi.[113][114]

Yadrodan foydalanuvchilarga bo'shliq ABI

Asosiy maqola: Linux standart bazasi

Linux operatsion tizimining yuzlab turli xil dasturlari o'rtasida farqlar mavjud bo'lganligi sababli, bajariladigan ob'ektlar, garchi ular kompilyatsiya qilingan, yig'ilgan va ma'lum bir apparat arxitekturasida ishlash uchun bog'langan bo'lsa ham (ya'ni, ular ISA maqsadli qo'shimcha qurilmalardan), ko'pincha turli xil Linux tarqatmalarida ishlamaydi. Ushbu muammo asosan tarqatishga xos konfiguratsiyalar va Linux yadrosi kodiga qo'llaniladigan yamalar to'plami, tizim kutubxonalaridagi farqlar, xizmatlar (demonlar), fayl tizimlari ierarxiyalari va atrof-muhit o'zgaruvchilari bilan bog'liq.

Linux tarqatish dasturlari va ikkilik muvofiqligi bilan bog'liq asosiy standart bu Linux standart bazasi (LSB).[115][116] Shu bilan birga, LSB Linux yadrosi bilan bog'liq bo'lgan narsalardan tashqariga chiqadi, chunki u ish stoli xususiyatlarini, X kutubxonalari va u bilan unchalik bog'liq bo'lmagan Qt-ni aniqlaydi.[117] LSB 5-versiyasi bir nechta standartlar va loyihalar (POSIX, SUS, X / Open, Fayl tizimi iyerarxiyasi (FHS) va boshqalar).[118]

LSB ning yadroga taalluqli qismlari Umumiy ABI (gABI),[119] ayniqsa Tizim V ABI[120][121] va Bajariladigan va bog'lovchi format (ELF),[122][123] va Protsessorga xos ABI (psABI), masalan X86-64 uchun yadro spetsifikatsiyasi.[124][125]

X86_64 foydalanuvchi dasturlarining tizim qo'ng'iroqlarini qanday chaqirishi uchun standart ABI - syscall raqamini rax va boshqa parametrlarni ro'yxatdan o'tkazing rdi, rsi, RDX, r10, r8va r9va nihoyat syscall kodda yig'ish bo'yicha ko'rsatma.[126][127][128]

Yadro ichidagi API

XDC2014-da AMD-dan Aleks Deucher birlashtirilgan yadro rejimi drayverini e'lon qildi.[129] Xususiy Linux grafik drayveri, libGL-fglrx-glx, xuddi shunday bo'lishadi DRM bilan infratuzilma Mesa 3D. Yadro ichida barqaror bo'lmaganligi sababli ABI, AMD doimiy ravishda avvalgisini moslashtirishi kerak edi ikkilik blok Catalyst tomonidan ishlatiladi.

Turli quyi tizimlar o'rtasida bir nechta yadro ichki API mavjud. Ulardan ba'zilari faqat yadro quyi tizimlarida mavjud bo'lib, yadro ichidagi belgilarning bir muncha cheklangan to'plami (ya'ni o'zgaruvchilar, ma'lumotlar tuzilmalari va funktsiyalari) dinamik ravishda yuklanadigan modullarga ta'sir qiladi (masalan, talabga binoan yuklangan qurilma drayverlari), ular eksport qilinmoqda. bilan EXPORT_SYMBOL () va EXPORT_SYMBOL_GPL () makrolar[130][131] (ikkinchisi GPL-ga mos litsenziya asosida chiqarilgan modullarga tegishli).[132]

Linux ma'lumotlar tuzilmalarini boshqaradigan yadro ichidagi API-larni taqdim etadi (masalan, bog'langan ro'yxatlar, radix daraxtlari,[133] qizil-qora daraxtlar,[134] navbat ) yoki hech bo'lmaganda Linux versiyasi 2.6 dan beri barqaror bo'lib qolgan odatdagi ishlarni bajarish (masalan, foydalanuvchi maydonidan ma'lumotlarni ko'chirish, xotira ajratish, tizim jurnaliga bosma chiziqlar va boshqalar).[135][136][137]

Yadro ichidagi API-larga qurilma drayverlari tomonidan ishlatiladigan past darajadagi umumiy xizmatlarning kutubxonalari kiradi:

ABI yadrosi

Linux ishlab chiquvchilari yadro ichidagi ABI barqarorligini saqlamaslikni tanlaydilar.[146] Muayyan Linux uchun tuzilgan modullarni yadro ichidagi API manba darajasi bir xil bo'lib qoldi deb taxmin qilib, qayta kompilyatsiya qilinmasdan yadroning boshqa versiyasiga yuklash mumkin emas, aks holda modul kodi ham shunga mos ravishda o'zgartirilishi kerak.[97]

Texnik xususiyatlari

Jarayonlar va iplar

Shuningdek qarang: Jarayon (hisoblash), Mavzu (hisoblash) va Jarayonlarni boshqarish (hisoblash)

Linux klon (2) yoki yangi klon3 (2) yordamida jarayonlarni yaratadi[147] tizim qo'ng'iroqlari. Berilgan parametrlarga qarab, yangi tashkilot qo'ng'iroq qiluvchining resurslarini ko'pi bilan yoki umuman baham ko'rishi mumkin. Ushbu tizimlar yangi mustaqil jarayonlardan tortib yangi ob'ektlarni yaratishi mumkin (ularning har biri maxsus identifikatorga ega) TGID ichida task_struct yadro maydonidagi ma'lumotlar tuzilishi, garchi o'sha identifikator chaqirilsa PID foydalanuvchilar maydonida), qo'ng'iroq qilish jarayonida (CLONE_THREAD parametridan foydalangan holda) bajarilishning yangi yo'nalishlariga. Bunday holda, yangi tashkilot xuddi shunday narsaga egalik qiladi TGID qo'ng'iroq qilish jarayoni va natijada bir xil bo'ladi PID foydalanuvchilar maydonida.[148][149]

Agar bajariladigan dastur umumiy kutubxonalar bilan dinamik ravishda bog'langan bo'lsa, tarjimon (ELF ob'ektlari uchun bu odatda /lib/ld-linux.so.2) kerakli ob'ektlarni topish va yuklash, dasturni ishga tushirishga tayyorlash va undan keyin ishga tushirish uchun ishlatiladi.[150]

The Mahalliy POSIX mavzu kutubxonasi, shunchaki NPTL deb nomlanuvchi,[151] standart POSIX iplari interfeysini taqdim etadi (pthreads) foydalanuvchilar maydoniga[152] Pthread_create (3) POSIX interfeysi yordamida har qanday yangi mavzu yaratilganda,[153] tizim chaqiruvlarining klon (2) oilasiga, shuningdek, yangi ip o'tish kerak bo'lgan funktsiya manzili berilishi kerak. Linux yadrosi futex (7) ("Tez foydalanuvchi-bo'shliq mutekslari" qisqartmasi) foydalanuvchi makonini tez blokirovka qilish va sinxronizatsiya qilish mexanizmlarini taqdim etadi;[154] operatsiyalarning aksariyati foydalanuvchilar maydonida amalga oshiriladi, ammo futex (2) tizim qo'ng'irog'i yordamida yadro bilan aloqa qilish zarur bo'lishi mumkin.[111]

Iplarning juda alohida toifasi deyiladi yadro iplari. Ularni yuqorida aytib o'tilgan foydalanuvchi jarayonlarini bajarish yo'nalishlari bilan aralashtirib yubormaslik kerak. Yadro zarralari faqat yadro maydonida mavjud va ularning yagona maqsadi bir vaqtning o'zida yadro vazifalarini bajarishdir.[155]

Boshqacha qilib aytganda, har qanday mustaqil jarayon yaratilganda, syscalllar aynan o'sha dasturning keyingi ko'rsatmasiga qaytadi, bir vaqtning o'zida ota-ona jarayoni va bola bittasi (ya'ni bitta dastur, ikkita jarayon). Turli xil qaytish qiymatlari (har bir jarayon uchun bittasi) dasturga hozirda qaysi ikkita jarayonning qaysi birini bajarayotganini bilishga imkon beradi. Dasturlar bu ma'lumotga muhtoj, chunki bola jarayoni, jarayon takrorlanishidan bir necha qadam o'tgach, odatda execve (2) tizim chaqiruvini chaqiradi (ehtimol exec (3) grapC-dagi paket funktsiyalari oilasi orqali) va hozirda bajarilayotgan dasturni almashtiradi. yangi dastur bilan qo'ng'iroq qilish jarayoni, yangi boshlangan to'plam, yig'ma va (boshlang'ich va boshlanmagan) ma'lumotlar segmentlari bilan.[156] Tugallangach, natijada ikki xil dastur ishlaydigan ikkita jarayon bo'ladi.

Ga qarab samarali foydalanuvchi identifikatori (evd) va samarali guruh identifikatori (egid), foydalanuvchi nol imtiyozlari bilan ishlaydigan jarayon (ildiz, tizim ma'muri 0 identifikatoriga egalik qiladi) hamma narsani bajarishi mumkin (masalan, boshqa barcha jarayonlarni o'ldirish yoki butun fayl tizimlarini rekursiv ravishda yo'q qilish), buning o'rniga foydalanuvchi nolga teng bo'lmagan jarayonlarni amalga oshira olmaydi. Imkoniyatlar (7) superususer bilan an'anaviy ravishda bog'liq bo'lgan imtiyozlarni alohida birliklarga ajratadi, ularni ota-ona jarayoni mustaqil ravishda yoqishi va o'chirib qo'yishi yoki bolaning o'zi tashlab qo'yishi mumkin.[157]

Rejalashtirish va oldindan belgilash

Shuningdek qarang: To'liq adolatli rejalashtiruvchi, Preemption (hisoblash) va Kernel preemption

Linux har xil rejalashtirish darslari va qoidalarini yoqadi.[158] Odatiy bo'lib, yadro rejalashtiruvchi mexanizmidan foydalanadi To'liq adolatli rejalashtiruvchi yadroning 2.6.23 versiyasida kiritilgan.[81] Ichki sifatida ushbu standart rejalashtirish klassi sifatida ham tanilgan SCHED_OTHER, ammo yadroda ikkita POSIX-mos keluvchi element mavjud[159] nomlangan real vaqtda rejalashtirish darslari SCHED_FIFO (haqiqiy vaqt birinchi-birinchi-tashqarida ) va SCHED_RR (haqiqiy vaqt dumaloq robin ), ikkalasi ham standart sinfdan ustun turadi.[158] Qo'shimcha rejalashtirish siyosati sifatida tanilgan SCHED_DEADLINE, amalga oshirish dastlabki algoritm (EDF), 2014 yil 30 martda chiqarilgan 3.14 yadrosi versiyasiga qo'shilgan.[160][161] SCHED_DEADLINE boshqa barcha rejalashtirish sinflaridan ustun turadi.

Linux ikkalasini ham ta'minlaydi foydalanuvchi imtiyozi shuningdek to'liq yadroni oldindan ko'rish.[162] Preemption kamayadi kechikish, javobgarlikni oshiradi,[163] va Linuxni ish stoli va uchun yanada moslashtiradi haqiqiy vaqt ilovalar.

Foydalanuvchi oldindan o'ylashi bilan yadro rejalashtiruvchisi joriy jarayonni a bajarilishi bilan almashtirishi mumkin kontekstni almashtirish boshqasiga, shuning uchun ishlash uchun hisoblash resurslarini oladi (protsessor, xotira va boshqalar). Bu shunga muvofiq qiladi CFS algoritmi (xususan, u o'zgaruvchini ishlatadi vruntime jarayonlarni saralash uchun), faol rejalashtiruvchi siyosatiga va jarayonlarning nisbiy ustuvor yo'nalishlariga. Yadro oldindan ko'rib chiqilganda, yadro uzilishni boshqaruvchi qaytib kelganda, yadro vazifalari bloklanganda va kichik tizim sched () funktsiyasini aniq chaqirganda o'zini ustun qo'yishi mumkin.

Linux yadrosi patch PREEMPT_RT muhim bo'limlarni, interrupt ishlovchilarini va "interrupt disable" kodlar ketma-ketligini to'liq ko'rib chiqishga imkon beradi.[164] Haqiqiy vaqtdagi Linux yamoqlarining qisman integratsiyasi yadro magistraliga yuqoridagi funktsiyalarni keltirdi.[165]

Xotirani boshqarish

Shuningdek qarang: Xotirani boshqarish

Linuxda xotirani boshqarish murakkab mavzu. Avvalo, yadro sahifaga joylashtirilmaydi (ya'ni, u doimo jismoniy xotirada doimiy bo'ladi va uni diskka almashtirish mumkin emas). Yadroda xotirani himoya qilish yo'q (yo'q SIGSEGV signallari, foydalanuvchilar maydonidan farqli o'laroq), shuning uchun xotirani buzish beqarorlik va tizimning ishdan chiqishiga olib keladi.[166]

Linux saqlash to'plami diagrammasi[167]

Qo'llab-quvvatlanadigan arxitektura

Shuningdek qarang: Linux tomonidan qo'llab-quvvatlanadigan kompyuter arxitekturalari ro'yxati va Linuxda ishlaydigan qurilma
TiVo DVR, Linux bilan ishlaydigan iste'molchi qurilmasi

Dastlabki tarzda ishlab chiqilmagan bo'lsa-da ko'chma,[24][168] Linux hozirda eng keng ko'chiriladigan operatsion tizim yadrolaridan biri bo'lib, u turli xil tizimlarda ishlaydi ARM arxitekturasi IBM-ga z / Arxitektura asosiy kompyuterlar. Birinchi port amalga oshirildi Motorola 68000 platforma. Yadroga kiritilgan o'zgartirishlar shunchalik muhim ediki, Torvalds Motorola versiyasini a vilka va "Linuxga o'xshash operatsion tizim".[168] Biroq, bu Torvaldsni ko'proq hisoblash me'morchiligiga ko'chirishni osonlashtirish uchun kodning katta qayta tuzilishiga olib keldi. Bitta manba daraxtida faqatgina i386 dan ortiq kodga ega bo'lgan birinchi Linux-ni qo'llab-quvvatladi DEK Alpha AXP 64-bitli platforma.[169][170][168]

Linux asosiy operatsion tizim sifatida ishlaydi IBM "s Sammit; 2019 yil oktyabr oyidan boshlab, butun dunyo 500 ta eng tezkor superkompyuterlar Linux yadrosi asosida operatsion tizimni ishga tushirish,[13] ro'yxatga birinchi Linux superkompyuteri qo'shilgan 1998 yildan buyon katta o'zgarish.[171]

Linux shuningdek, turli xil qo'l qurilmalariga ko'chirilgan Olmalar iPhone 3G va iPod.[172]

Jonli yamoq

Qayta boshlashsiz yangilanishlar yordamida hatto yadroga ham qo'llanilishi mumkin jonli yamoq kabi texnologiyalar Ksplice, kpatch va kGraft. Jonli yadrolarni yamoqlashning minimalistik asoslari Linux yadrosi magistral liniyasiga 2015 yil 12 aprelda chiqarilgan 4.0 yadrosi versiyasida birlashtirildi. Ushbu asoslar livepatch va birinchi navbatda yadroga asoslangan ftrace funktsiyasi, ikkala kGraft va kpatch tomonidan issiq yamoqlarni qo'llab-quvvatlashga qodir bo'lgan umumiy yadroni hosil qiladi dastur dasturlash interfeysi (API) yadro modullari uchun, issiq yamalar va dastur ikkilik interfeysi (ABI) foydalanuvchilar maydonini boshqarish yordam dasturlari uchun. Biroq, Linux yadrosi 4.0 ga kiritilgan umumiy yadro faqat x86 me'morchiligi va ta'minlash uchun hech qanday mexanizmlarni ta'minlamaydi funktsiya - issiq yamalar qo'llanilganda darajadagi mustahkamlik. 2015 yil aprel oyidan boshlab, kpatch va kGraft-ni Linux yadrosi magistrali tomonidan taqdim etilgan umumiy jonli patching yadrosiga ko'chirish bo'yicha ishlar olib borilmoqda.[173][174][175]

Xavfsizlik

Kernel xatolari potentsial xavfsizlik muammolarini keltirib chiqaradi. Masalan, ular ruxsat berishlari mumkin imtiyozlarning kuchayishi yoki yaratish xizmatni rad etish hujumi vektorlar. Bir necha yillar davomida tizim xavfsizligiga ta'sir qiluvchi ko'plab xatolar topildi va ularni bartaraf etishdi.[176] Yadro xavfsizligini yaxshilash uchun tez-tez yangi funktsiyalar qo'llaniladi.[177][178]

Imkoniyatlar (7) jarayonlar va mavzular haqidagi bo'limda allaqachon kiritilgan. Android ulardan foydalanadi va Systemd jarayonlar imkoniyatlari ustidan ma'murlarga batafsil nazorat qilish imkonini beradi.[179]

Linux yadro hujumi sirtini kamaytirish va xavfsizlikni yaxshilash uchun juda ko'p mexanizmlarni taklif etadi, ular birgalikda tanilgan Linux xavfsizlik modullari (LSM).[180] Ular tarkibiga quyidagilar kiradi Xavfsizligi yaxshilangan Linux (SELinux) moduli, uning kodi dastlab ishlab chiqilgan va keyin NSA,[181] va AppArmor[94] Boshqalar orasida. SELinux hozirda faol ishlab chiqilgan va saqlanib qolgan GitHub.[93] SELinux va AppArmor kirish xavfsizligini ta'minlash siyosatini qo'llab-quvvatlaydi, shu jumladan majburiy kirishni boshqarish (MAC), ammo ular murakkabligi va ko'lami jihatidan bir-biridan tubdan farq qiladi.

Xavfsizlikning yana bir xususiyati Seccomp BPF (SECure COMPuting with Berkeley Packet Filters) bo'lib, u parametrlarni filtrlash va foydalanuvchi-er dasturlari uchun mavjud bo'lgan qo'ng'iroqlar to'plamini kamaytirish orqali ishlaydi.[182]

Tanqidchilar yadro ishlab chiqaruvchilarni xavfsizlik nuqsonlarini yashirishda yoki hech bo'lmaganda ularni e'lon qilmaslikda ayblashadi; 2008 yilda Linus Torvalds bunga quyidagilar bilan javob berdi:[183][184]

Men shaxsan xavfsizlik xatolarini shunchaki "oddiy xatolar" deb bilaman. Men ularni yashirmayman, lekin menda ularni kuzatib, ularni alohida narsa deb e'lon qilish yaxshi fikr deb o'ylash uchun hech qanday sabab yo'q ... bu bitta sabab, men butun xavfsizlik bilan bezovtalanishni rad qilaman sirk - bu noto'g'ri xatti-harakatni ulug'laydi va shu bilan rag'batlantiradi deb o'ylayman. Xavfsizlik xodimlaridan "qahramonlar" chiqadi, go'yo oddiy xatolarni tuzatmaydigan odamlar unchalik muhim emas. Aslida, barcha zerikarli oddiy xatolar yo'l bundan ham muhimi, ularning ko'plari borligi sababli. Menimcha, ba'zi bir xavfsizlik teshiklari yomon qulflanganligi sababli tasodifiy ajoyib qulashdan ko'ra ko'proq "maxsus" deb maqtanishi yoki g'amxo'rlik qilishi kerak emas.

Linux tarqatish odatda Linux yadrosidagi zaifliklarni tuzatish uchun xavfsizlik yangilanishlarini chiqaradi. Ko'pchilik taklif qiladi uzoq muddatli qo'llab-quvvatlash uzoq vaqt davomida ma'lum bir Linux yadrosi versiyasi uchun xavfsizlik yangilanishlarini oladigan nashrlar.

Rivojlanish

Dasturchilar jamoasi

Linux yadrosi ishlab chiqaruvchilarining hamjamiyati taxminan 5000-6000 a'zodan iborat. "Linux yadrosi rivojlanishining 2017 yilgi holati" ga ko'ra, Linux jamg'armasi tomonidan 4.8 dan 4.13 gacha nashrlarning majburiyatlarini o'z ichiga olgan bir tadqiqotda 1500 ga yaqin ishlab chiquvchilar o'rtacha 200-250 ta kompaniyadan o'z hissalarini qo'shishdi. Eng yaxshi 30 ta ishlab chiquvchi kodning 16% dan bir oz ko'proq hissasini qo'shdi. Kompaniyalar bo'yicha eng yaxshi hissadorlar Intel (13,1%) va Red Hat (7,2%), Linaro (5,6%), IBM (4,1%), ikkinchi va beshinchi o'rinlarni "yo'q" (8,2%) va "noma'lum" (4,1%) toifalari.[185]

Yo'l xaritasi o'rniga texnik ko'rsatmalar mavjud. Resurslarni markaziy ravishda taqsimlash o'rniga, Linux yadrosini yanada rivojlantirishda bir-biridan mustaqil ravishda o'z ulushiga ega bo'lgan shaxslar va kompaniyalar mavjud: Linus Torvalds kabi odamlar va men yadro evolyutsiyasini rejalashtirmaymiz. Biz u erda o'tirmaymiz va kelgusi ikki yil uchun yo'l xaritasini o'ylaymiz, so'ngra turli xil yangi xususiyatlarga resurslarni tayinlaymiz. Buning sababi, bizda hech qanday resurs yo'q. The resources are all owned by the various corporations who use and contribute to Linux, as well as by the various independent contributors out there. It's those people who own the resources who decide...

— Endryu Morton, 2005

Source code management

The Linux development community uses Git boshqarish manba kodi. Git users clone the latest version of Torvalds' tree with git-clone(1)[186] and keep it up to date using git-pull(1).[187][188] Contributions are submitted as patches, in the form of text messages on the LKML (and often also on other mailing lists dedicated to particular subsystems). The patches must conform to a set of rules and to a formal language that, among other things, describes which lines of code are to be deleted and what others are to be added to the specified files. These patches can be automatically processed so that system administrators can apply them in order to make just some changes to the code or to incrementally upgrade to the next version.[189] Linux is distributed also in GNU zip (gzip) and bzip2 formatlari.

Submitting code to the kernel

A developer who wants to change the Linux kernel starts with developing and testing that change. Depending on how significant the change is and how many subsystems it modifies, the change will either be submitted as a single patch or in multiple patches of manba kodi. In case of a single subsystem that is maintained by a single maintainer, these patches are sent as e-mails to the maintainer of the subsystem with the appropriate mailing list in Cc. The maintainer and the readers of the mailing list will review the patches and provide feedback. Once the review process has finished the subsystem maintainer accepts the patches in the relevant Git kernel tree. If the changes to the Linux kernel are bug fixes that are considered important enough, a pull request for the patches will be sent to Torvalds within a few days. Otherwise, a pull request will be sent to Torvalds during the next merge window. The merge window usually lasts two weeks and starts immediately after the release of the previous kernel version.[190] The Git kernel source tree names all developers who have contributed to the Linux kernel in the Kreditlar directory and all subsystem maintainers are listed in Ta'minchilar.[191]

Programming language and coding style

Linux is written in a special C dasturlash tili tomonidan qo'llab-quvvatlanadi GCC, a compiler that extends in many ways the C standard, for example using inline sections of code da yozilgan assambleya tili (in GCC's "AT&T-style" syntax) of the target architecture. Since 2002 all the code must adhere to the 21 rules comprising the Linux Kernel Coding Style.[192][193]

GNU asboblar zanjiri

The GNU kompilyatori to'plami (GCC or GNU cc) is the default kompilyator for the mainline Linux sources and it is invoked by a utility called qilish. Keyin GNU Assembler (more often called GAS or GNU as) outputs the ob'ekt fayllari from the GCC generated yig'ilish kod. Va nihoyat GNU bog'lovchi (GNU ld) is used to produce a statically linked executable kernel file called vmlinux. as and ld are part of a package called GNU binutillari. The above-mentioned tools are collectively known as the GNU asboblar zanjiri.

Compiler compatibility

GCC was for a long time the only compiler capable of correctly building Linux. 2004 yilda, Intel claimed to have modified the kernel so that its C compiler was also capable of compiling it.[194] There was another such reported success in 2009, with a modified 2.6.22 version.[195][196]

Since 2010, effort has been underway to build Linux with Jiringlash, an alternative compiler for the C language;[197] as of 12 April 2014, the official kernel could almost be compiled by Clang.[198][199] The project dedicated to this effort is named LLVMLinux keyin LLVM compiler infrastructure upon which Clang is built.[200] LLVMLinux does not aim to fork either Linux or the LLVM, therefore it is a meta-project composed of patches that are eventually submitted to the upstream projects. By enabling Linux to be compiled by Clang, developers may benefit from shorter compilation times.[201]

Kernel debugging

An example of Linux kernel panic
Asosiy maqolalar: KGDB, Kernel vahima va Linux yadrosi xafa

Linux bugs can be very hard to find out and fix, firstly because of kernel interaction with userspace and hardware and secondly because they might be caused from a wider number of reasons than those which can affect user programs. A few examples of the underlying causes are semantic errors in code, misuse of synchronization primitives, and an incorrect hardware management.[202]

A report of a non-fatal bug in the kernel is called an "xafa "; such deviations from correct behavior of the Linux kernel may allow continued operation with compromised reliability.[203]

A critical and fatal error is reported via the "panic() " function. It prints a message and then halts the kernel.[204]

One of the most common techniques used to find out bugs in code is debugging by printing. For this purpose Linux provides an in-kernel API called printk () which stores messages in a circular buffer. The syslog(2) system call is used for reading and/or clearing the kernel message ring buffer and for setting the maximum log level of the messages to be sent to the console (i.e., one of the eight KERN_* parameters of printk(), which tell the severity of the condition reported); usually it is invoked via the glibC wrapper klogctl(3).[205] Kernel messages are also exported to userland through the /dev/kmsg interfeys[206] (masalan, systemd-journald[207][208] reads that interface and by default append the messages to /var/log/journal).

Another fundamental technique for debugging a running kernel is tracing. The ftrace mechanism is a Linux internal tracer; it is used for monitoring and debugging Linux at runtime and it can also analyze user space latencies due to kernel misbehavior.[209][210][211] Bundan tashqari, ftrace allows users to trace Linux at boot-time.[212]

kprobes va kretprobes can break (like debuggers in userspace) into Linux and non-disruptively collect information.[213] kprobes can be inserted into code at (almost) any address, while kretprobes work at function return. uprobes have similar purposes but they also have some differences in usage and implementation.[214]

Bilan KGDB Linux can be debugged in much the same way as userspace programs. KGDB requires an additional machine that runs GDB and that is connected to the target to be debugged using a ketma-ket simi yoki Ethernet.[215]

Rivojlanish modeli

The Linux kernel project integrates new code on a rolling basis. Software checked into the project must work and kompilyatsiya qilish xatosiz. For each kernel subsystem there is a maintainer who is responsible for reviewing patches against the kernel code standards and keeps a queue of patches that can be submitted to Linus Torvalds within a merge window of several weeks. Patches are merged by Torvalds into the source code of the prior stable Linux kernel release, creating the -rc release candidate for the next stable kernel. Once the merge window is closed only fixes to the new code in the development release are accepted. The -rc development release of the kernel goes through regressiya sinovlari and once it is judged to be stable by Torvalds and the kernel subsystem maintainers a new Linux kernel is released and the development process starts all over again.[216]

Developers who feel treated unfairly can report this to the Linux fondi 's Technical Advisory Board.[217] In July 2013 the maintainer of the USB 3.0 driver Sara Sharp asked Torvalds to address the abusive commentary in the kernel development community. In 2014, Sharp backed out of Linux kernel development, saying that "The focus on technical excellence, in combination with overloaded maintainers, and people with different cultural and social norms, means that Linux kernel maintainers are often blunt, rude, or brutal to get their job done".[218] At the linux.conf.au (LCA) conference in 2018, developers expressed the view that the culture of the community has gotten much better in the past few years. Daniel Vetter, the maintainer of the Intel drm/i915 graphics kernel driver, commented that the "rather violent language and discussion" in the kernel community has decreased or disappeared.[219]

Laurent Pinchart asked developers for feedback on their experience with the kernel community at the 2017 Embedded Linux Conference Europe. The issues brought up were a few days later discussed at the Maintainers Summit. Concerns over the lack of consistency in how maintainers responded to patches submitted by developers were echoed by Shuah Khan, the maintainer of the kernel self-test framework. Torvalds contended that there would never be consistency in the handling of patches because different kernel subsystems have over time adopted different development processes. Therefore, it was agreed upon that each kernel subsystem maintainer would document the rules for patch acceptance.[220]

Linux forks

An iPod yuklash iPodLinux

There are certain communities that develop kernels based on the official Linux. Some interesting bits of code from these vilkalar (i.e., a slang term meaning "derived projects") that include Linux-libre, Linux tugunini hisoblash, Siyoh, L4Linux, RTLinux va Foydalanuvchi rejimi Linux (UML) have been merged into the mainline.[221] Some operating systems developed for mobile phones initially used heavily modified versions of Linux, including Google Android, Firefox OS, HP webOS, Nokia Maemo and Jolla Sailfish OS. In 2010, the Linux community criticised Google for effectively starting its own kernel tree:[222][223]

This means that any drivers written for Android hardware platforms, can not get merged into the main kernel tree because they have dependencies on code that only lives in Google's kernel tree, causing it to fail to build in the kernel.org tree. Because of this, Google has now prevented a large chunk of hardware drivers and platform code from ever getting merged into the main kernel tree. Effectively creating a kernel branch that a number of different vendors are now relying on.[224]

— Greg Kroah-Xartman, 2010

Today Android uses a slightly customized Linux[225] where changes are implemented in device drivers so that little or no change to the core kernel code is required. Android developers also submit patches to the official Linux that finally can boot the Android operating system. Masalan, a Nexus 7 can boot and run the mainline Linux.[225]

Development community conflicts

There have been several notable conflicts among Linux kernel developers. Examples of such conflicts are:

  • 2007 yil iyul oyida, Kon Kolivas announced that he would cease developing for the Linux kernel.[226][227]
  • 2009 yil iyul oyida, Alan Koks quit his role as the TTY layer maintainer after disagreement with Linus Torvalds.[228]
  • In December 2010, there was a discussion between Linux SCSI maintainer James Bottomley and SCST maintainer Vladislav Bolkhovitin about which SCSI target stack should be included in the Linux kernel.[229] This made some Linux users upset.[230]
  • In June 2012, Torvalds made it very clear that he did not agree with NVIDIA releasing its drivers as closed.[231]
  • In April 2014, Torvalds banned Kay Sievers from submitting patches to the Linux kernel for failing to deal with xatolar sabab bo'ldi tizimd to negatively interact with the kernel.[232]
  • 2014 yil oktyabr oyida, Lennart Poettering accused Torvalds of tolerating the rough discussion style on Linux kernel related mailing lists and of being a bad role model.[233]
  • In March 2015, Christoph Hellwig filed a lawsuit against VMware for infringement of the copyright on the Linux kernel.[234] Linus Torvalds made it clear that he did not agree with this and similar initiatives by calling lawyers a festering disease.[235]

Prominent Linux kernel developers have been aware of the importance of avoiding conflicts between developers.[236] For a long time there was no code of conduct for kernel developers due to opposition by Linus Torvalds.[237] However, a Linux Kernel Konflikt kodeksi was introduced on 8 March 2015.[238] It was replaced on 16 September 2018 by a new Odob-axloq qoidalari asosida Hissadorlar to'g'risidagi ahd. This coincided with a public apology by Linus and a brief break from kernel development.[239][240] On 30 November 2018, complying with the Odob-axloq qoidalari, Jarkko Sakkinen of Intel sent out patches replacing instances of "fuck" appearing in source code comments with suitable versions focused on the word 'hug'.[241]

Kod bazasi

2020 yildan boshlab, the 5.9 release of the Linux kernel had around 27.8 million lines of code, roughly 14% of the code is part of the "core" (arch, kernel and mm directories) while 60% is drivers.

Linux is evolution, not intelligent design!

— Linus Torvalds, 2005[242][243][244]

Estimated cost to redevelop

Redevelopment costs of Linux kernel

The cost to redevelop the Linux kernel version 2.6.0 in a traditional proprietary development setting has been estimated to be US$612 million (€467M, £394M) in 2004 prices using the KOKOMO man-month estimation model.[245] In 2006, a study funded by the European Union put the redevelopment cost of kernel version 2.6.8 higher, at €882M ($1.14bn, £744M).[246]

This topic was revisited in October 2008 by Amanda McPherson, Brian Proffitt, and Ron Hale-Evans. Using David A. Wheeler's methodology, they estimated redevelopment of the 2.6.25 kernel now costs $1.3bn (part of a total $10.8bn to redevelop Fedora 9).[247] Again, Garcia-Garcia and Alonso de Magdaleno from University of Oviedo (Spain) estimate that the value annually added to kernel was about €100M between 2005 and 2007 and €225M in 2008, it would cost also more than €1bn (about $1.4bn as of February 2010) to develop in the European Union.[248]

As of 7 March 2011, using then-current LOC (lines of code) of a 2.6.x Linux kernel and wage numbers with David A. Wheeler's calculations it would cost approximately $3bn (about €2.2bn) to redevelop the Linux kernel as it keeps getting bigger. An updated calculation as of 26 September 2018, using then-current 20,088,609 LOC (lines of code) for the 4.14.14 Linux kernel and the current US National average programmer salary of $75,506 show it would cost approximately $14,725,449,000 dollars (£11,191,341,000) to rewrite the existing code.[249]

Maintenance and long-term support

Boot messages of a Linux kernel 2.6.25.17

The latest kernel version and older kernel versions are maintained separately. Most latest kernel releases were supervised by Linus Torvalds.[250] Current versions are released by Greg Kroah-Xartman.[251]

The Linux kernel developer community maintains a stable kernel by applying fixes for dasturiy ta'minotdagi xatolar that have been discovered during the development of the subsequent stable kernel. Therefore, www.kernel.org will always list two stable kernels. The next stable Linux kernel is now released only 8 to 12 weeks later. Therefore, the Linux kernel maintainers have designated some stable kernel releases as longterm, bular uzoq muddatli qo'llab-quvvatlash Linux kernels are updated with bug fixes for two or more years.[252] In November 2019 there were five longterm Linux kernels: 4.19.84, 4.14.154, 4.9.201, 4.4.201 and 3.16.76.[253] The full list of releases is at Linux yadrosi versiyasi tarixi.

Relation with Linux distributions

Most Linux users run a kernel supplied by their Linux tarqatish. Some distributions ship the "vanilla" or "stable" kernels. However, several Linux distribution vendors (such as Qizil shapka va Debian ) maintain another set of Linux kernel branches which are integrated into their products. These are usually updated at a slower pace compared to the "vanilla" branch, and they usually include all fixes from the relevant "stable" branch, but at the same time they can also add support for drivers or features which had not been released in the "vanilla" version the distribution vendor started basing their branch from.

Huquqiy jihatlar

GPLv2 licensing terms

Initially, Torvalds released Linux under a license which forbade any commercial use.[254] This was changed in version 0.12 by a switch to the GNU umumiy jamoat litsenziyasi version 2 (GPLv2).[28] This license allows distribution and sale of possibly modified and unmodified versions of Linux but requires that all those copies be released under the same license and be accompanied by the complete corresponding source code.[255] Torvalds has described licensing Linux under the GPLv2 as the "best thing I ever did".[254]

The Linux kernel is licensed explicitly only under version 2 of the GPL,[23] without offering the licensee the option to choose "any later version", which is a common GPL extension. The official git branch of Torvalds contains documentation that explains the kernel development process to people who want to work with the community and contribute code; it clearly states that "[Any] contributions which are not covered by a [GPLv2] compatible license will not be accepted into the kernel.".[105]

There was considerable debate about how easily the license could be changed to use later GPL versions (including version 3), and whether this change is even desirable.[256] Torvalds himself specifically indicated upon the release of version 2.4.0 that his own code is released only under version 2.[257] However, the terms of the GPL state that if no version is specified, then any version may be used,[258] va Alan Koks pointed out that very few other Linux contributors had specified a particular version of the GPL.[259]

In September 2006, a survey of 29 key kernel programmers indicated that 28 preferred GPLv2 to the then-current GPLv3 draft. Torvalds commented, "I think a number of outsiders... believed that I personally was just the odd man out because I've been so publicly not a huge fan of the GPLv3."[260] This group of high-profile kernel developers, including Torvalds, Greg Kroah-Xartman va Endryu Morton, commented on mass media about their objections to the GPLv3.[261] They referred to clauses regarding DRM /tivoizatsiya, patents, "additional restrictions" and warned a Bolqonlashtirish of the "Open Source Universe" by the GPLv3.[261][262] Linus Torvalds, who decided not to adopt the GPLv3 for the Linux kernel, reiterated his criticism even years later.[263]

Loadable kernel modules

It is debated whether some yuklanadigan yadro modullari (LKMs) are to be considered lotin ishlari under copyright law, and thereby whether or not they fall under the terms of the GPL.

In accordance with the license rules, LKMs using only a public subset of the kernel interfaces[130][131] are non-derived works, thus Linux gives system administrators the mechanisms to load out-of-tree binary objects into the kernel address space.[5]

There are some out-of-tree loadable modules that make legitimate use of the dma_buf kernel feature.[264] GPL compliant code can certainly use it. However, a different possible use case would be Nvidia Optimus that pairs a fast GPU with an Intel integrated GPU, where the Nvidia GPU writes into the Intel framebuffer when it is active. But, Nvidia cannot use this infrastructure because it necessitates bypassing a rule that can only be used by LKMs that are also GPL.[132] Alan Koks replied on LKML, rejecting a request from one of their engineers to remove this technical enforcement from the API.[265] Torvalds clearly stated on the LKML that "[I] claim that binary-only kernel modules ARE derivative "by default"'".[266]

On the other hand, Torvalds has also said that "[one] gray area in particular is something like a driver that was originally written for another operating system (i.e. clearly not a derived work of Linux in origin). THAT is a gray area, and _that_ is the area where I personally believe that some modules may be considered to not be derived works simply because they weren't designed for Linux and don't depend on any special Linux behaviour".[267] Mulkiy graphics drivers, in particular, are heavily discussed.

Firmware binary blobs

The official kernel, that is the Linus git branch at the kernel.org repository, does not contain any kind of proprietary code;[23][5] however Linux can search the filesystems to locate proprietary firmware, drivers, and other executable modules (collectively known as "ikkilik bloklar "), then it can load and link them into the kernel space.[268] Whenever proprietary modules are loaded into Linux, the kernel marks itself as being "tainted"[269] and therefore bug reports from tainted kernels will often be ignored by developers.

When it is needed (e.g., for accessing boot devices or for speed) firmware can be built-in to the kernel, this means building the firmware into vmlinux; however this is not always a viable option for technical or legal issues (e.g., it is not permitted to firmware that is non-GPL compatible).[270]

Savdo belgisi

Shuningdek qarang: Linux: Copyright, trademark, and naming

Linux is a registered savdo belgisi ning Linus Torvalds in the United States, the European Union, and some other countries.[271][272] A legal battle over the trademark began in 1996, when William Della Croce, a lawyer who was never involved in the development of Linux, started requesting licensing fees for the use of the word Linux. After it was proven that the word was in common use long before Della Croce's claimed first use, the trademark was awarded to Torvalds.[273][274][275]

Shuningdek qarang

Adabiyotlar

  1. ^ "Linux Logos and Mascots". Linux Online. 2008. Arxivlangan asl nusxasi 2010 yil 15 avgustda. Olingan 11 avgust 2009.
  2. ^ The Linux Kernel Open Source Project on Open Hub: Languages Page
  3. ^ Kroax-Xartman, Greg (2020 yil 24-noyabr). "Linux 5.9.11". LKML (Pochta ro'yxati). Olingan 24-noyabr 2020.
  4. ^ Torvalds, Linus (2020 yil 23-noyabr). "Linux 5.10-rc5". LKML (Pochta ro'yxati). Olingan 23 noyabr 2020.
  5. ^ a b v d e "Linux kernel licensing rules — The Linux Kernel documentation". www.kernel.org. Olingan 6 yanvar 2020.
  6. ^ Tanenbaum, Andrew; Bos, Herbert (2015). Zamonaviy operatsion tizimlar. Amerika Qo'shma Shtatlari: Pearson. p. 722. ISBN  9781292061429. OCLC  892574803.
  7. ^ Sevgi, Robert (2010). Linux kernel development. Addison-Uesli. p. 4. ISBN  978-0-672-32946-3. OCLC  268788260.
  8. ^ Sevgi, Robert (2010). Linux kernel development. Addison-Uesli. p. 338. ISBN  978-0-672-32946-3. OCLC  268788260.
  9. ^ "README". git.kernel.org.
  10. ^ Richardson, Marjorie (1 November 1999). "Interview: Linus Torvalds". Linux jurnali. Olingan 20 avgust 2009.
  11. ^ Uilyams, Sem (2002 yil mart). "Chapter 9: The GNU General Public License". Ozodlikdagi kabi bepul: Richard Stallmanning bepul dasturiy ta'minot uchun salib yurishi. O'Rayli. ISBN  0-596-00287-4. Olingan 12 noyabr 2010.
  12. ^ Unix System Laboratories v. Berkeley Software, 832 F. Supp. 790 (D.N.J. 1993).
  13. ^ a b "TOP500 Supercomputer Sites: Operating system Family / Linux". Top500.org. Olingan 5 oktyabr 2019.
  14. ^ a b v "Kernel Build System — The Linux Kernel documentation". www.kernel.org. Olingan 17 iyul 2020.
  15. ^ a b v "Kconfig make config — The Linux Kernel documentation". www.kernel.org. Olingan 13 sentyabr 2020.
  16. ^ a b "KernelBuild - Linux Kernel Newbies". kernelnewbies.org. Olingan 13 sentyabr 2020.
  17. ^ a b "The Sysctl Interface". www.linux.it. Olingan 13 sentyabr 2020.
  18. ^ a b "sysctl(8) - Linux manual page". man7.org. Olingan 13 sentyabr 2020.
  19. ^ a b "procfs(5) - Linux manual page". man7.org. Olingan 13 sentyabr 2020.
  20. ^ Sevgi, Robert (2010). Linux Kernel Development. Addison Uesli. p. 18. ISBN  978-0-672-32946-3. OCLC  268788260.
  21. ^ "C Extensions (Using the GNU Compiler Collection (GCC))". gcc.gnu.org. Olingan 13 noyabr 2020.
  22. ^ Sevgi, Robert (2010). Linux Kernel Development. USA: Addison Wesley. 379-380 betlar. ISBN  9780672329463.
  23. ^ a b v d "Linux source code: COPYING (v5.4.8) - Bootlin". elixir.bootlin.com. Olingan 6 yanvar 2020.
  24. ^ a b Torvalds, Linus Benedict (26 August 1991). "What would you like to see most in minix?". Yangiliklar guruhicomp.os.minix. Usenet:  [email protected].
  25. ^ a b Welsh, Matt; Dalheimer, Matthias Kalle; Kaufman, Lar (1999). "1". Linuxni ishga tushirish (3-nashr). Sebastopol, Kaliforniya: O'Reilly Media, Inc. ISBN  1-56592-976-4. OCLC  50638246.
  26. ^ a b "Free minix-like kernel sources for 386-AT - Google Groups". groups.google.com. 1991 yil 5 oktyabr. Olingan 19 mart 2020.
  27. ^ a b v Christine Bresnahan & Richard Blum (2016). LPIC-2: Linux Professional Institute Certification Study Guide: Exam 201 and Exam 202. John Wiley & Sons. p. 107. ISBN  9781119150794.
  28. ^ a b Torvalds, Linus. "Release Notes for Linux v0.12". The Linux Kernel Archives. Olingan 21 fevral 2007.
  29. ^ Fred Hantelmann (2016). LINUX Start-up Guide: A self-contained introduction. Springer Science & Business Media. p. 1. ISBN  9783642607493.
  30. ^ a b v Fred Hantelmann (2016). LINUX Start-up Guide: A self-contained introduction. Springer Science & Business Media. p. 16. ISBN  9783642607493.
  31. ^ Summers, David W. (19 January 1992). "Troubles with Partitions". Yangiliklar guruhialt.os.linux. Usenet:  [email protected]. Olingan 7 yanvar 2007.
  32. ^ Clegg, Alan B. (31 March 1992). "It's here!". Yangiliklar guruhicomp.os.linux. Usenet:  [email protected]. Olingan 7 yanvar 2007.
  33. ^ "Appendix A: The Tanenbaum-Torvalds Debate". Ochiq manbalar: Ochiq manbalar inqilobidan ovozlar. O'Rayli. 1999. ISBN  1-56592-582-3. Olingan 22 noyabr 2006.
  34. ^ Tanenbaum, Andy (29 January 1992). "LINUX is obsolete". Yangiliklar guruhicomp.os.minix. Usenet:  [email protected]. Olingan 10 may 2006.
  35. ^ Tanenbaum, Andy (12 May 2006). "Tanenbaum-Torvalds Debate: Part II". Amsterdam VU universiteti. Olingan 6 yanvar 2007.
  36. ^ November 2012, David Hayward22. "The history of Linux: how time has shaped the penguin". TechRadar. Olingan 19 mart 2020.
  37. ^ November 2012, David Hayward22. "The history of Linux: how time has shaped the penguin". TechRadar. Olingan 26 mart 2020.
  38. ^ Love, Robert (Robert M.) (2010). Linux kernel development (3-nashr). Upper Saddle River, NJ: Addison-Wesley. p. 9. ISBN  978-0-672-32946-3. OCLC  268788260.
  39. ^ a b "How the development process works — The Linux Kernel documentation". www.kernel.org. Olingan 26 mart 2020.
  40. ^ "Kernel 1.2 Source Code Release". Olingan 27 oktyabr 2008.
  41. ^ a b v Christine Bresnahan & Richard Blum (2016). LPIC-2: Linux Professional Institute Certification Study Guide: Exam 201 and Exam 202. John Wiley & Sons. p. 108. ISBN  9781119150794.
  42. ^ Torvalds, Linus (9 June 1996). "Linux 2.0 really _is_ released." LKML (Pochta ro'yxati). Olingan 8 mart 2015.
  43. ^ Torvalds, Linus (1999 yil 20-yanvar). "2.2.0-final". LKML (Pochta ro'yxati). Olingan 8 mart 2015.
  44. ^ "The Wonderful World of Linux 2.2". 1999 yil 26-yanvar. Olingan 27 oktyabr 2008.
  45. ^ "Linux/390 Observations and Notes". linuxvm.org. Olingan 29 mart 2020.
  46. ^ Torvalds, Linus (4 January 2001). "And oh, btw." LKML (Pochta ro'yxati). Olingan 8 mart 2015.
  47. ^ "The Wonderful World of Linux 2.4". Arxivlandi asl nusxasi 2005 yil 17 martda. Olingan 27 oktyabr 2008.
  48. ^ Torvalds, Linus (17 December 2003). "Linux 2.6.0". LKML (Pochta ro'yxati). Olingan 28 fevral 2015.
  49. ^ "proc(5) - Linux manual page" (see /proc/sys/kernel/pid_max).
  50. ^ "btrfs Wiki". btrfs.wiki.kernel.org. Olingan 17 iyul 2020.
  51. ^ Fred Hantelmann (2016). LINUX Start-up Guide: A self-contained introduction. Springer Science & Business Media. 1-2 bet. ISBN  9783642607493.
  52. ^ Kroax-Xartman, Greg (3 August 2006). "Adrian Bunk is now taking over the 2.6.16-stable branch". LKML (Pochta ro'yxati). Olingan 21 fevral 2015.
  53. ^ Rothwell, Stephen (12 February 2008). "Announce: Linux-next (Or Andrew's dream :-))". LKML (Pochta ro'yxati). Olingan 30 oktyabr 2010.
  54. ^ Corbet, Jonathan (21 October 2010). "linux-next and patch management process". LWN.net. Eklektix, Inc. Olingan 30 oktyabr 2010.
  55. ^ "The Linux Kernel Archives". Kernel.org. Olingan 22 yanvar 2014.
  56. ^ Linux Kernel Mailing List (17 June 2005). "Linux 2.6.12". git-commits-head (Pochta ro'yxati).
  57. ^ "Index of /pub/linux/kernel/v2.6". Kernel.org. Olingan 2 mart 2014.
  58. ^ "Add a personality to report 2.6.x version numbers [LWN.net]". lwn.net.
  59. ^ a b Torvalds, Linus (2011 yil 21-iyul). "Linux 3.0 release". Linux yadrosi pochta ro'yxati. Olingan 16 may 2013.
  60. ^ Torvalds, Linus (2011 yil 30-may). "Linux 3.0-rc1". LKML (Pochta ro'yxati). Arxivlandi asl nusxasi 2011 yil 31 mayda. Olingan 1 iyul 2013.
  61. ^ Vaughan-Nichols, Steven J. (13 December 2012). "Good-Bye 386: Linux to drop support for i386 chips with next major release". ZDNet. CBS Interactive. Olingan 6 fevral 2013.
  62. ^ Fingas, Jon (15 December 2012). "Linux to drop i386 support in the 3.8 kernel, make us upgrade our Doom rig". Engadget. AOL. Olingan 22 mart 2015.
  63. ^ Vaughan-Nichols, Steven J. (11 December 2012). "Linux 3.7 arrives, ARM developers rejoice". ZDNet. CBS Interactive. Olingan 6 fevral 2013.
  64. ^ Torvalds, Linus (2013 yil 2 sentyabr). "Linux 3.11". LKML (Pochta ro'yxati). Olingan 3 sentyabr 2013.
  65. ^ "Linux 3.11". kernelnewbies.org. 2013 yil 2 sentyabr. Olingan 21 yanvar 2014.
  66. ^ Torvalds, Linus (2015 yil 12-aprel). "Linux 4.0 released". LKML (Pochta ro'yxati). Olingan 12 aprel 2015.
  67. ^ "The Linux Foundation Releases Linux Development Report". Linux fondi. 18 Fevral 2015. Arxivlangan asl nusxasi 2016 yil 19-iyulda. Olingan 20 fevral 2015.
  68. ^ Michael Larabel (23 June 2014). "Linux Kernel At 19.5 Million Lines Of Code, Continues Rising". Froniks. Olingan 23 iyun 2015.
  69. ^ Corbet, Jonathan (3 August 2020). "Some statistics from the 5.8 kernel cycle". LWN - Linux Weekly News. Olingan 11 avgust 2020.
  70. ^ "Stack Overflow Developer Survey 2019 - most popular technologies". Stack overflow. Olingan 17 mart 2020.
  71. ^ "Stack Overflow Developer Survey 2019 - development environments and tools". Stack overflow. Olingan 17 mart 2020.
  72. ^ "Usage Statistics and Market Share of Operating Systems for Websites, March 2020". w3techs.com. Olingan 17 mart 2020.
  73. ^ "Usage Statistics and Market Share of Unix for Websites, March 2020". w3techs.com. Olingan 17 mart 2020.
  74. ^ "TOP500 Supercomputer Sites: Operating system Family / Linux". Top500.org. Olingan 5 oktyabr 2019.
  75. ^ "Gartner Says Sales of Tablets Will Represent Less Than 10 Percent of All Devices in 2014" (Matbuot xabari). Egham, UK: Gartner. 15 oktyabr 2014 yil. Olingan 19 oktyabr 2014.
  76. ^ Lunden, Ingrid (15 October 2014). "Tablet Sales Growth Plummets In 2014 As Android Smartphones Continue To Soar: Gartner". TechCrunch. AOL. Olingan 23 oktyabr 2014.
  77. ^ "Global PC Shipments Exceed Forecast with Mild Improvement in Consumer Demand, While Apple Moves to #5 Spot, According to IDC" (Matbuot xabari). Framingham, MA: IDC. 8 oktyabr 2014. Arxivlangan asl nusxasi 2014 yil 11 oktyabrda. Olingan 19 oktyabr 2014.
  78. ^ "sched(7) - Linux manual page". man7.org. Olingan 27 iyul 2020.
  79. ^ "FAQ: Preemption". kernelnewbies.org. 2009 yil 22-avgust. Olingan 7 may 2015.
  80. ^ a b Jonathan Corbet (24 February 2003). "Driver porting: the preemptible kernel". LWN.net. Olingan 7 may 2015.
  81. ^ a b Molnár, Ingo (13 April 2007). "[patch] Modular Scheduler Core and Completely Fair Scheduler [CFS]". LKML (Pochta ro'yxati). Olingan 30 mart 2020.
  82. ^ "Completely Fair Scheduler | Linux Journal". www.linuxjournal.com. Olingan 30 mart 2020.
  83. ^ "ioctl(2) - Linux manual page". man7.org. Olingan 11 avgust 2020.
  84. ^ "aio(7) - Linux manual page". man7.org. Olingan 11 avgust 2020.
  85. ^ "io_setup(2) - Linux manual page". man7.org. Olingan 11 avgust 2020.
  86. ^ "KVM". www.linux-kvm.org. Olingan 29 mart 2020.
  87. ^ "TechComparison - Linux Virtualization Wiki". virt.kernelnewbies.org. Olingan 29 mart 2020.
  88. ^ "Virtualization_support_through_KVM in Linux_2_6_20 - Linux Kernel Newbies". kernelnewbies.org. Olingan 29 mart 2020.
  89. ^ Coekaerts, Wim. "Linux mainline contains all the Xen code bits for Dom0 and DomU support". bloglar.oracle.com. Olingan 29 mart 2020.
  90. ^ "Xen celebrates full Dom0 and DomU support in Linux 3.0 – blog.xen.org". 7 Iyun 2011. Arxivlangan asl nusxasi 2011 yil 7 iyunda. Olingan 29 mart 2020.
  91. ^ Wilk, Konrad Rzeszutek (31 January 2014). "Linux 3.14 and PVH". Xen loyihasi. Olingan 29 mart 2020.
  92. ^ "Introduction to Xen Virtualization | Virtualization Guide | openSUSE Leap 15.2". doc.opensuse.org. Olingan 29 sentyabr 2020.
  93. ^ a b "SELinux Project". GitHub. Olingan 10 yanvar 2020.
  94. ^ a b "AppArmor — The Linux Kernel documentation". www.kernel.org. Olingan 10 yanvar 2020.
  95. ^ Jake Edge (25 November 2008). "Character devices in user space". LWN.net. Olingan 7 may 2015.
  96. ^ Jonathan Corbet (2 May 2007). "UIO: user-space drivers". LWN.net. Olingan 7 may 2015.
  97. ^ a b v "barqaror-api-bema'nilik - Linux yadrosi manba daraxti". git.kernel.org. Olingan 18 aprel 2020.
  98. ^ Gorman, Mel (2004 yil 15 fevral). Linux virtual xotira menejerini tushunish (PDF). Prentice Hall. p. 26. ISBN  0-13-145348-3.
  99. ^ Greg Ungerer. "uClinux asosiy liniyasi to'g'risida e'lon". Arxivlandi asl nusxasi 2007 yil 31 oktyabrda. Olingan 15 yanvar 2008.
  100. ^ a b Nguyen, Binx (2004 yil 30-iyul). "Linux fayl tizimining iyerarxiyasi: 1-bob. Linux fayl tizimining iyerarxiyasi". Linux hujjatlari loyihasi. Olingan 28 noyabr 2012.
  101. ^ "Linux yadrosi versiyasi 5.x - Linux yadrosi hujjatlari". www.kernel.org. Olingan 4 yanvar 2020.
  102. ^ "READMEABIDocumentation - kernel / git / torvalds / linux.git - Linux yadrosi manba daraxti". git.kernel.org. Olingan 18 aprel 2020.
  103. ^ "syscallsstableABIDocumentation - kernel / git / torvalds / linux.git - Linux yadrosi manba daraxti". git.kernel.org. Olingan 18 aprel 2020.
  104. ^ "barqaror-api-bema'nilik - Linux yadrosi manba daraxti". git.kernel.org. Olingan 18 aprel 2020.
  105. ^ a b "1.Intro.rst - Hujjatlar / jarayon / 1.Intro.rst - Linux manba kodi (v5.8) - Bootlin". elixir.bootlin.com. Olingan 8 avgust 2020.
  106. ^ a b "to'siqlar". man7.
  107. ^ "intro (2) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 16 iyul 2020.
  108. ^ "klon". man7.org. Olingan 28 yanvar 2020.
  109. ^ "xususiyati_test_macros". man7.org. Olingan 28 yanvar 2020.
  110. ^ "vdso (7) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 2 fevral 2020.
  111. ^ a b "futex (2) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 2 fevral 2020.
  112. ^ "syscall (2) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 2 fevral 2020.
  113. ^ "sysfs (5) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 6 yanvar 2020.
  114. ^ "Sysfs-da ma'lumotlarga qanday kirish qoidalari - Linux yadrosi hujjatlari". www.kernel.org. Olingan 6 yanvar 2020.
  115. ^ "Linux Foundation-ga havola qilingan texnik xususiyatlar". refspecs.linuxbase.org. Olingan 3 fevral 2020.
  116. ^ "LSB texnik xususiyatlari". refspecs.linuxbase.org. Olingan 3 fevral 2020.
  117. ^ "Linux uchun standart ish stoli spetsifikatsiyasi, umumiy qism". refspecs.linuxbase.org. Olingan 3 fevral 2020.
  118. ^ "Normativ qo'llanmalar". refspecs.linuxfoundation.org. Olingan 3 fevral 2020.
  119. ^ "Linux standart bazasi yadrosi spetsifikatsiyasi, umumiy qism". refspecs.linuxfoundation.org. Olingan 3 fevral 2020.
  120. ^ "System V Application Binary Interface - Edition 4.1" (PDF). www.sco.com.
  121. ^ "Xinuos Inc. | Ishlab chiquvchilar | Gabi | 2003-12-17 | System V Application Binary Interface - DRAFT". www.sco.com. Olingan 3 fevral 2020.
  122. ^ "Bajariladigan va bog'laydigan format (ELF)". refspecs.linuxbase.org. Olingan 3 fevral 2020.
  123. ^ "elf (5) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 18 noyabr 2020.
  124. ^ "X86-64 uchun Linux standart bazaviy yadrosi". refspecs.linuxbase.org. Olingan 3 fevral 2020.
  125. ^ "System V Application Binary Interface - DRAFT". refspecs.linuxbase.org. Olingan 3 fevral 2020.
  126. ^ Seyfart, Rey (2012). Linux uchun 64 bitli Intel Assambleyasi Til dasturlash bilan tanishish. p. 170. ISBN  9781478119203.
  127. ^ "Tizim chaqiruvi anatomiyasi, 1-qism [LWN.net]". lwn.net. Olingan 16 iyul 2020.
  128. ^ "Tizim chaqiruvi anatomiyasi, 2-qism [LWN.net]". lwn.net. Olingan 16 iyul 2020.
  129. ^ Deucher, Aleks (2014 yil 7 oktyabr). "AMD-ning yangi birlashtirilgan ochiq manbali drayveri". X.Org jamg'armasi. Olingan 21 yanvar 2015.
  130. ^ a b "Belgilar - Linux yadrosini buzish bo'yicha ishonchli qo'llanma - Linux yadrosi hujjatlari". www.kernel.org. Olingan 8 fevral 2020.
  131. ^ a b "Eksport qilingan belgilar va ichki API [LWN.net]". lwn.net. Olingan 15 mart 2020.
  132. ^ a b "Eksport qilinmaydigan kallsyms_lookup_name () [LWN.net]". lwn.net. Olingan 15 mart 2020.
  133. ^ "Daraxtlar I: Radiks daraxtlari [LWN.net]". lwn.net. Olingan 13 noyabr 2020.
  134. ^ "Daraxtlar II: qizil-qora daraxtlar [LWN.net]". lwn.net. Olingan 13 noyabr 2020.
  135. ^ "Linux yadrosini buzish bo'yicha ishonchli qo'llanma". www.kernel.org (1-nashr). 2005 yil. Olingan 15 mart 2020.
  136. ^ "Linux yadrosini buzish bo'yicha ishonchli qo'llanma - Linux yadrosi hujjatlari". www.kernel.org. Olingan 15 mart 2020.
  137. ^ "Qulflash bo'yicha ishonchli qo'llanma - Linux yadrosi hujjatlari". www.kernel.org. Olingan 15 mart 2020.
  138. ^ "SCSI interfeyslari bo'yicha qo'llanma - Linux yadrosi hujjatlari". www.kernel.org. Olingan 11 iyun 2020.
  139. ^ "libATA ishlab chiquvchilari uchun qo'llanma - Linux yadrosi hujjatlari". www.kernel.org. Olingan 11 iyun 2020.
  140. ^ "DRM Internals - Linux yadrosi hujjatlari". www.kernel.org. Olingan 11 iyun 2020.
  141. ^ "Kernel Mode Setting (KMS) - Linux Kernel hujjatlari". www.kernel.org. Olingan 11 iyun 2020.
  142. ^ "DMA bufer almashish mexanizmini joriy eting [LWN.net]". lwn.net. Olingan 11 iyun 2020.
  143. ^ "Linuxda CPU va GPU buferlarini almashish *". 01.org. 2016 yil 12-may. Olingan 11 iyun 2020.
  144. ^ "Buferlarni almashish va sinxronizatsiya - Linux yadrosi hujjatlari". www.kernel.org. Olingan 11 iyun 2020.
  145. ^ "Mac80211 haqida". Linux yadrosi tashkiloti, Inc. Olingan 8 iyun 2014.
  146. ^ "Linux yadrosidagi ABI o'zgarishlar to'g'risida hisobot". Andrey Ponomarenkoning ABI laboratoriyasi. 2016 yil 17 mart.
  147. ^ "[PATCH v3 1/2] vilkalar: klon3 qo'shing [LWN.net]". lwn.net. Olingan 16 iyul 2020.
  148. ^ "clone (2) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 15 iyul 2020.
  149. ^ "clone3 (), fchmodat4 () va fsinfo () [LWN.net]". lwn.net. Olingan 15 iyul 2020.
  150. ^ "ld-linux.so (8) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 18 noyabr 2020.
  151. ^ "nptl (7) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 25 iyul 2020.
  152. ^ "pthreads (7) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 25 iyul 2020.
  153. ^ "pthread_create (3) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 25 iyul 2020.
  154. ^ "futex (7) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 25 iyul 2020.
  155. ^ "Yadro iplari osonlashdi [LWN.net]". lwn.net. Olingan 15 avgust 2020.
  156. ^ "execve (2) - Linux uchun qo'llanma sahifasi". www.man7.org. Olingan 17 iyul 2020.
  157. ^ "qobiliyatlar (7) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 2 avgust 2020.
  158. ^ a b Bar, Moshe (2000 yil 1 aprel). "Linux rejalashtiruvchisi". Linux jurnali. Belltown Media, Inc. Olingan 14 aprel 2012.
  159. ^ "Axborot texnologiyalari uchun IEEE standarti - Portativ operatsion tizim interfeysi, POSIX.1b, real vaqt kengaytmalari (IEEE Std 1003.1b-1993)".
  160. ^ Larabel, Maykl (2014 yil 24-yanvar). "Linux 3.14 yadrosi allaqachon ko'plab qiziqarli xususiyatlarga ega". Froniks. Olingan 3 fevral 2014.
  161. ^ "Linux yadrosi 3.14, 1.1-bo'lim. Haqiqiy vaqtni yaxshiroq rejalashtirish uchun muddatni rejalashtirish klassi". kernelnewbies.org. 30 mart 2014 yil. Olingan 2 aprel 2014.
  162. ^ Sevgi, Robert (2010). "4". Linux Kernel Development (3-nashr). Addison Uesli. 62-63 betlar. ISBN  9780672329463.
  163. ^ "Linuxda kechikishni pasaytirish: imtiyozli yadro bilan tanishtirish | Linux jurnali". www.linuxjournal.com. Olingan 17 avgust 2020.
  164. ^ MakKenni, Pol (2005 yil 10-avgust). "Haqiqiy vaqt oralig'ida tanlovga umumiy nuqtai". LWN.net. Olingan 5 fevral 2012.
  165. ^ "OSADL loyihasi: real vaqtda Linux". OSADL. Olingan 5 fevral 2012.
  166. ^ Sevgi, Robert (2010). Linux Kernel Development. Addison Uesli. p. 20. ISBN  9780672329463.
  167. ^ "Linux saqlash to'plami diagrammasi". www.thomas-krenn.com. Olingan 19 mart 2020.
  168. ^ a b v Torvalds, Linus (1999 yil yanvar). "Linux qirrasi". Ochiq manbalar: Ochiq manbalar inqilobidan ovozlar. O'Rayli. ISBN  1-56592-582-3. Olingan 13 oktyabr 2013.
  169. ^ "Linuxni DEC Alpha-ga ko'chirish: yadro va qobiq".
  170. ^ "Linuxda Alpha: strategik tanlov".
  171. ^ "Avalon klasteri | TOP500 superkompyuter saytlari". www.top500.org. Olingan 5 oktyabr 2019.
  172. ^ Vang, Devid (2010 yil 6-may). "Android endi iPhone 3G da ishlaydi". TechHive. IDG. Olingan 11 iyul 2010.
  173. ^ "Linux kernel 4.0, 1.2-bo'lim. Jonli patching". kernelnewbies.org. 2015 yil 26 aprel. Olingan 27 aprel 2015.
  174. ^ Jonathan Corbet (2015 yil 25-fevral). "Jonli yamoq uchun qo'pol yamoq". LWN.net. Olingan 27 aprel 2015.
  175. ^ "kernel / git / torvalds / linux.git: Jiri Kosinadan jonli patching infratuzilmasini torting (Linux yadrosi manbasi daraxti)". kernel.org. 2015 yil 11-fevral. Olingan 27 aprel 2015.
  176. ^ Mookhey, K. K .; Burghate, Nilesh (2005 yil 1-iyul). Linux: xavfsizlik, audit va boshqarish xususiyatlari. AQSH: ISACA. p. 14. ISBN  1-893209-78-4. Olingan 31 dekabr 2010.
  177. ^ Xetch, Brayan (2008 yil 15-iyul). Ochiq Linuxni buzish: Linux xavfsizligi sirlari va echimlari. McGraw-Hill Osborne Media. p. 524. ISBN  978-0-07-226257-5. Olingan 31 dekabr 2010.
  178. ^ Jaeger, Trent (2008 yil 7 oktyabr). Operatsion tizim xavfsizligi. Morgan va Claypool Publishers. p. 122. ISBN  978-1-59829-212-1. Olingan 31 dekabr 2010.
  179. ^ "CAP_PERFMON - va umuman yangi imkoniyatlar [LWN.net]". lwn.net. Olingan 2 avgust 2020.
  180. ^ "Linux xavfsizlik modulidan foydalanish - Linux yadrosi hujjatlari". www.kernel.org. Olingan 10 yanvar 2020.
  181. ^ "Milliy xavfsizlik agentligi | Markaziy xavfsizlik xizmati> Biz nima qilamiz> Tadqiqotlar> SE Linux> SE Linux bilan bog'liq savollar". www.nsa.gov. Olingan 10 yanvar 2020.
  182. ^ "Seccomp BPF (filtrlar bilan xavfsiz hisoblash) - Linux yadrosi hujjatlari". www.kernel.org. Olingan 10 yanvar 2020.
  183. ^ Andrews, Jeremy (2008 yil 16-iyul). "Xavfsizlik xatosi va to'liq oshkor qilish". KernelTrap. Arxivlandi asl nusxasi 2008 yil 19-iyulda. Olingan 31 dekabr 2010.
  184. ^ Spengler, Bred (2008 yil 16-iyul). "Linuxning yashirin ravishda yashiringan norasmiy siyosati". To'liq ma'lumot (Pochta ro'yxati). Olingan 31 dekabr 2010.
  185. ^ Foundation, Linux (25 oktyabr 2017). "2017 yilgi Linux yadrosi rivojlanishining holati". Linux fondi. Olingan 27 may 2020.
  186. ^ "git-clone (1) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 16 avgust 2020.
  187. ^ "git-pull (1) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 16 avgust 2020.
  188. ^ Robert Love (2010). Linux yadrosi rivojlanishi: Linux yadrosi rivojlanishi. Pearson ta'limi. p. 11. ISBN  9780768696790.
  189. ^ Robert Love (2010). Linux yadrosi rivojlanishi: Linux yadrosi rivojlanishi. Pearson ta'limi. p. 12. ISBN  9780768696790.
  190. ^ "Rivojlanish jarayoni qanday ishlaydi". Olingan 4 fevral 2018.
  191. ^ Robert Love (2010). Linux yadrosi rivojlanishi: Linux yadrosi rivojlanishi. Pearson ta'limi. p. 13. ISBN  9780768696790.
  192. ^ "Linux yadrosi qanday ishlab chiqilmoqda - Linux yadrosi hujjatlari". www.kernel.org. Olingan 4 yanvar 2020.
  193. ^ "Linux yadrosini kodlash uslubi - Linux yadrosi hujjatlari". www.kernel.org. Olingan 4 yanvar 2020.
  194. ^ Kubbilun, Ingo A. (2004 yil 2-iyun). "Intel Compiler uchun Linux yadrosi patch" (nemis tilida). Pyrillion.org. Arxivlandi asl nusxasi 2011 yil 22-iyulda. Olingan 12 noyabr 2010.
  195. ^ timoti (2009 yil 26-fevral). "Yuqori samarali Linux yadrosi loyihasi - LinuxDNA". Slashdot Linux. Dice Holdings. Olingan 30 oktyabr 2010.
  196. ^ Rayan, Jastin (2009 yil 25-fevral). "LinuxDNA Linuxni Intel C / C ++ kompilyatori bilan to'ldiradi". Linux jurnali. Belltown Media, Inc. Olingan 30 oktyabr 2010.
  197. ^ Lelbax, Brys (2010 yil 25 oktyabr). "Clang ishlaydigan Linux yadrosini yaratadi (SMP, tarmoq va X, o'zini o'zi boshqarish tizimlari bilan RL5-ga yuklash)". cfe-dev (Pochta ro'yxati). Arxivlandi asl nusxasi 2015 yil 7 sentyabrda.
  198. ^ Larabel, Maykl (2014 yil 12 aprel). "Linux 3.15-ni deyarli LLVM-ning jiringlashi ostida kompilyatsiya qilish mumkin". Froniks. Olingan 10 iyun 2014.
  199. ^ Larabel, Maykl. "Patch By Patch, LLVM Clang Linux yadrosini yaratishda yaxshilanadi". Froniks. Olingan 20 noyabr 2014.
  200. ^ Edge, Jeyk (2013 yil 7-may). "LFCS: LLVMLinux loyihasi". LWN.net. Olingan 3 mart 2015.
  201. ^ Myuller, Jan-Simon (2014 yil 2-fevral). "LLVMLinux: Linux yadrosi va ajdar qanotlari" (PDF). LLVM loyihasi. Olingan 3 mart 2015.
  202. ^ Sevgi, Robert (2010). Linux yadrosi rivojlanishi (3-nashr). Addison-Uesli. p. 364. ISBN  978-0-672-32946-3. OCLC  268788260.
  203. ^ Bredford, Jon (2003 yil 8 mart). "Re: OOPS nima". LKML (Pochta ro'yxati). Olingan 30 oktyabr 2010.
  204. ^ Sevgi, Robert (2010). Linux yadrosi rivojlanishi. Addison Uesli. p. 371. ISBN  9780672329463. OCLC  268788260.
  205. ^ "syslog (2) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 15 avgust 2020.
  206. ^ "kmsg: printk yozuvlarini / dev / kmsg interfeysiga eksport qilish [LWN.net]". lwn.net. Olingan 16 avgust 2020.
  207. ^ "systemd". www.freedesktop.org. Olingan 16 avgust 2020.
  208. ^ "systemd-journald (8) - Linux uchun qo'llanma sahifasi". man7.org. Olingan 15 avgust 2020.
  209. ^ "Ftrace yordamida yadroni disk raskadrovka - qism 1 [LWN.net]". lwn.net. Olingan 15 sentyabr 2020.
  210. ^ "Ftrace yordamida yadroni disk raskadrovka - qism 2 [LWN.net]". lwn.net. Olingan 15 sentyabr 2020.
  211. ^ "ftrace - Function Tracer - Linux yadrosi hujjatlari". www.kernel.org. Olingan 15 sentyabr 2020.
  212. ^ "Ish vaqtini kuzatish - Linux yadrosi hujjatlari". www.kernel.org. Olingan 19 sentyabr 2020.
  213. ^ "Kernel probes (Kprobes) - Linux yadrosi hujjatlari". www.kernel.org. Olingan 6 oktyabr 2020.
  214. ^ "Uprobe-tracer: Uprobe-based Event Tracing - Linux yadrosi hujjatlari". www.kernel.org. Olingan 6 oktyabr 2020.
  215. ^ "Kgdb, kdb va yadro tuzatuvchi ichki qismlardan foydalanish". mirrors.edge.kernel.org. Olingan 3 noyabr 2020.
  216. ^ Gen Salli (2010). Pro Linux ko'milgan tizimlari. Apress. p. 252. ISBN  9781430272267.
  217. ^ "Ixtilof kodeksi". Olingan 4 fevral 2018.[doimiy o'lik havola ]
  218. ^ Sharwood, Simon (2015 yil 6-oktabr). "Linus Torvaldsdan og'zaki haqoratni to'xtatishni so'ragan Linux kernel dev, og'zaki suiiste'mollikni to'xtatadi". Ro'yxatdan o'tish.
  219. ^ Edge, Jeyk (31 yanvar 2018). "Juda ko'p lordlar, boshqaruvchilar etarli emas". LWN.net. Olingan 4 fevral 2018.
  220. ^ Corbet, Jonathan (6 noyabr 2017). "Yadro texnikasini boshqaring". LWN.net. Olingan 4 fevral 2018.
  221. ^ "Pre-pre-state" holati. linuxplumbersconf.org. Arxivlandi asl nusxasi 2016 yil 15 oktyabrda. Olingan 14 iyun 2016.
  222. ^ Meyer, Devid (3 Fevral 2010). "Linux ishlab chiqaruvchisi Android yadrosi kodini olib tashlashni tushuntirdi". ZDNet. CBS Interactive. Olingan 3 fevral 2010.
  223. ^ "03-bob: maemo platformasi haqida umumiy ma'lumot". maemo texnologiyasiga umumiy nuqtai. Nokia. 2008. Arxivlangan asl nusxasi 2008 yil 16-iyunda. Olingan 9 aprel 2010.
  224. ^ Kroah-Xartman, Greg (2010 yil 2-fevral). "Android va Linux yadrosi hamjamiyati". Olingan 3 fevral 2010.
  225. ^ a b Rojer Ye (2017). Android tizim dasturlash. Packt Publishing. p. 14. ISBN  9781787120389.
  226. ^ "Men nega ishdan chiqdim: yadro ishlab chiqaruvchi Con Kolivas". APC jurnali. ACP jurnallari. 24 Iyul 2007. Arxivlangan asl nusxasi 2011 yil 7-iyulda. Olingan 15 avgust 2011.
  227. ^ Corbet, Jonathan (25 iyul 2007). "Re: -mm birlashtirish rejalari 2.6.23". LWN.net. Olingan 10 fevral 2018.
  228. ^ Koks, Alan (2009 yil 28-iyul). "Re: [PATCH] kdesu buzilgan". Olingan 10 fevral 2018.
  229. ^ Rodriges, Goldvin (2011 yil 22-yanvar). "Ikki SCSI maqsadlari haqida ertak". Olingan 14 fevral 2018.
  230. ^ Shtaynets, Andreas (2013 yil 17-yanvar). "LIO - buzilgan iSCSI maqsadini amalga oshirish". Olingan 14 fevral 2018.
  231. ^ Pol, Rayan (2012 yil 19-iyun). "Linus Torvalds NVIDIA-ga" f-k sen "demoqda". Olingan 14 fevral 2018.
  232. ^ Jon Gold (2014 yil 3-aprel). "Linus Torvalds Linuxning asosiy ishlab chiquvchisini to'xtatib qo'ydi: Systemd dev ayiqni urayotgani sababli yadro vahimasi". Olingan 24 mart 2019.
  233. ^ Poettering, Lennart (6 oktyabr 2014). "Linux yadrosi hamjamiyati kasalligi to'g'risida". Google+. Olingan 10 fevral 2018.
  234. ^ Brodkin, Jon (2015 yil 6 mart). "VMware Linux-ning ochiq manbali litsenziyasini yillar davomida buzganlikda gumon qilingan". Ars Technica. Olingan 14 fevral 2018.
  235. ^ Makkarti, Kiren (2016 yil 26-avgust). "Dunyoda hamma boshqalarni xafa qilgan Linus Torvalds o'z huquqshunoslarini yomon kasallik deb ataydi'". Ro'yxatdan o'tish. Olingan 14 fevral 2018.
  236. ^ Corbet, Jonathan (10 sentyabr 2007). "KS2007: Dasturchilar bilan aloqalar va rivojlanish jarayoni". LWN.net. Olingan 11 fevral 2018.
  237. ^ Brodkin, Jon (2013 yil 16-iyul). "Linus Torvalds Linux yadrosi ishlab chiqaruvchilarini sharmanda qilish huquqini himoya qiladi". ARS Technica. Olingan 11 fevral 2018.
  238. ^ Corbet, Jonathan (9 mart 2015). "Yadroning ziddiyat kodi". LWN.net. Olingan 11 fevral 2018.
  239. ^ Corbet, Jonathan (18 sentyabr 2018). "Kodeks, nizo va xulq-atvor". LWN.net.
  240. ^ Koen, Noam (2018 yil 19-sentabr). "Bir necha yillik haqoratli elektron pochta xabarlaridan so'ng, Linux qadamlarini yaratuvchisi bir chetda". Nyu-Yorker.
  241. ^ Larabel, Maykl. "Kernel kodidagi shafqatsizlikni qoldirish Izohlar: Linux oladi" quchoqlaydi"". Froniks. Olingan 15 iyun 2019.
  242. ^ "Linux evolyutsiyasi" (PDF). 26 mart 2008 yil.
  243. ^ "Doimiy rivojlanish: Linux yadrosi hayot tsiklining modeli" (PDF). 2011 yil 25 oktyabr.
  244. ^ Kroah-Xartman, Greg (2008 yil 12-fevral). "Re: E'lon qiling: Linux-next (Yoki Endryuning orzusi :-))". Linux yadrosi pochta ro'yxati (Pochta ro'yxati). Olingan 30 yanvar 2017.
  245. ^ Uiler, Devid A. "Linux Kernel 2.6: Bu ko'proq arziydi!".
  246. ^ "FLOSS ning Evropa Ittifoqining AKT sohasining innovatsiyalarga va raqobatbardoshlikka iqtisodiy ta'siri" (PDF) (50-betdagi 3-jadval).
  247. ^ "Linux tarqatish uchun umumiy ishlab chiqarish xarajatlarini baholash" (PDF) (6-betdagi jadval). Arxivlandi asl nusxasi (PDF) 2010 yil 11 iyulda.
  248. ^ "Milliard dollarlik yadro". Linux.slashdot.org. 24 fevral 2010 yil. Olingan 12 noyabr 2010.
  249. ^ Uiler, Devid. "Linux yadrosi: bunga arziydi!". Olingan 17 sentyabr 2012.
  250. ^ "Linux MAINTAINERS fayli". Arxivlandi asl nusxasi 2013 yil 12-yanvarda.
  251. ^ Torvalds, Linus (16 sentyabr 2018). "Linux 4.19-rc4 chiqarildi, kechirim so'radi va xizmat ko'rsatishga oid eslatma". LKML. Olingan 23 sentyabr 2018.
  252. ^ Aleksandru Vaduva, Aleks Gonsales va Kris Simmonds (2016). Linux: O'rnatilgan rivojlanish. Packt Publishing. p. 663. ISBN  9781787124455.
  253. ^ "Linux yadrosi arxivi". Olingan 13 noyabr 2019.
  254. ^ a b Yamagata, Xiroo (1997 yil 3-avgust). "Bepul dasturiy ta'minotning pragmatisti". HotWired. Arxivlandi asl nusxasi 2007 yil 10 fevralda. Olingan 21 fevral 2007.
  255. ^ "GPL-v2". gnu.org.
  256. ^ Corbet, Jonathan (2006 yil 31-yanvar). "GPLv3 va yadro". LWN.net. Olingan 21 fevral 2007.
  257. ^ Torvalds, Linus (8 sentyabr 2000). "Linux-2.4.0-test8". LKML (Pochta ro'yxati). Olingan 21 fevral 2007.
  258. ^ "gnu.org". www.gnu.org. Olingan 18 oktyabr 2017.
  259. ^ Koks, Alan (2006 yil 20-yanvar). "Re: GPL V3 va Linux". LKML (Pochta ro'yxati). Olingan 21 fevral 2007.
  260. ^ Shankland, Stiven (2006 yil 25 sentyabr). "GPL 3-ni eng yaxshi Linux dasturchilari". News.com. CNET. Olingan 21 fevral 2007.
  261. ^ a b Jeyms E.J. Bottomli, Mauro Karvalyu Chexab, Tomas Gliksner, Kristof Xellvig, Deyv Jons, Greg Kroax-Xartman, Toni Lak, Endryu Morton, Trond Myklebust, Devid Vudxaus (2006 yil 15 sentyabr). "GPLv3 bo'yicha yadro ishlab chiquvchilarining pozitsiyasi: GPLv3 bilan bog'liq xavf va muammolar". LWN.net. Olingan 11 mart 2015.CS1 maint: mualliflar parametridan foydalanadi (havola)
  262. ^ Petreley, Nikolay (2006 yil 27 sentyabr). "Yomonlikka qarshi kurashmi yoki e'tibor uchun kurashmi?". linuxjournal.com. Olingan 11 mart 2015.
  263. ^ "Linus Torvalds, GPL v3, GPLv2-ning barcha qoidalarini buzishini aytmoqda". Debconf 2014. 2014. Olingan 21 mart 2018.
  264. ^ Klark, Rob; Semval, Sumit (2012 yil 1-noyabr). "DMA buferini almashish doirasi: kirish" (PDF). O'rnatilgan Linux konferentsiyasi. Olingan 2 avgust 2014.
  265. ^ Koks, Alan (2012 yil 10 oktyabr). "[PATCH] dma-buf: EXPORT_SYMBOL dan foydalaning". To'g'ridan-to'g'ri ko'rsatish infratuzilmasi (Pochta ro'yxati). Olingan 3 sentyabr 2013.
  266. ^ Torvalds, Linus (2003 yil 10-dekabr). "RE: Linux GPL va ikkilik modulni istisno qilish qoidasi?". LKML (Pochta ro'yxati). Olingan 31 dekabr 2010.
  267. ^ Torvalds, Linus (2003 yil 3-dekabr). "Re: Linux GPL va ikkilik modul istisno bandi?". LKML (Pochta ro'yxati). Olingan 12 noyabr 2010.
  268. ^ "Linux Firmware API - Linux yadrosi hujjatlari". www.kernel.org. Olingan 13 yanvar 2020.
  269. ^ "Buzilgan yadrolar - Linux yadrosi hujjatlari". www.kernel.org. Olingan 13 yanvar 2020.
  270. ^ "Ichki dasturiy ta'minot - Linux yadrosi hujjatlari". www.kernel.org. Olingan 10 iyun 2020.
  271. ^ "AQShda Linux TM ro'yxatdan o'tishi". uspto.gov.
  272. ^ "Evropa Ittifoqida Linux TM ro'yxatdan o'tishi". euipo.europa.eu. Arxivlandi asl nusxasi 2016 yil 9-iyun kuni.
  273. ^ Xyuz, Fil (1997 yil 1-avgust). "Linux savdo markasi bo'yicha nizo". Linux jurnali. Belltown Media, Inc. Olingan 8 dekabr 2010.
  274. ^ Xyuz, Fil (1997 yil 1 mart). "Linux savdo belgisida harakat". Linux jurnali. Belltown Media, Inc. Olingan 8 dekabr 2010.
  275. ^ Gisselberg, Tonya (2010). "Linuxning savdo markasi tarixi, operatsion tizim" (PDF). Gisselberg yuridik firmasi, Inc Arxivlangan asl nusxasi (PDF) 2011 yil 11-iyulda. Olingan 8 dekabr 2010.

Qo'shimcha o'qish

Tashqi havolalar