Changes between Version 51 and Version 52 of boot_procedure


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Timestamp:
Feb 28, 2019, 11:34:57 AM (6 years ago)
Author:
alain
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  • boot_procedure

    v51 v52  
    7979This assembly code makes the assuption that the CP0 register containing the core gid (global hardware identifier) has a fixed format:   '''gid''' == ('''cxy''' << 2) + '''lid'''
    8080
    81 Each core running this code makes the 3 following actions:                                                                          *
     81Each core running this code makes the 3 following actions:
    8282   * It initializes the core stack pointer depending on the '''lid''' value extracted from the '''gid''', using the BOOT_STACK_BASE and BOOT_STACK_SIZE parameters defined in the  ''boot_config.h'' file,                                                                    *
    8383   * It changes the value of the DATA address extension CP2 register, using the '''cxy''' value extracted from the '''gid'''                                                                           
     
    8686In this sequencial phase, the core[0][0]  executing this C function makes the following actions:
    8787   * The core[0][0] initializes 2 peripherals: The '''TTY''' terminal (channel 0)  to display log messages, and the '''IOC''' peripheral to access the disk.
    88    * The core[0][0] initializes the boot-loader private FAT32 structure, allowing the boot loader to access files stored in the FAT32 file system on disk.
    89     * The core[0][0] load in the KERNEL_ELF zone the ''kernel.elf'' file from the disk file system..
    90     * Then it copies in the KERNEL_CORE zone the ''kcode'' and ''data'' segments, using the addresses contained in the .elf file (identity mapping).
    91     * The core[0][0] load in the ARCH_INFO zone the ''arch_info.bin'' file from the disk file system.
    92     * Then it builds from this ''arch_info.t'' structure the specific ''boot_info_t'' structure for cluster 0, and stores it in the ''kdata'' segment.
    93     * The core[0][0] send IPIs to activate all cores [i][0] in all other clusters.
     88   * The core[0][0] initializes the boot-loader FAT32, allowing the boot loader to access files stored in the FAT32 file system on disk.
     89   * The core[0][0] load in the KERNEL_ELF zone the ''kernel.elf'' file from the disk file system..
     90   * Then it copies in the KERNEL_CORE zone the ''kcode'' and ''data'' segments, using the addresses contained in the .elf file (identity mapping).
     91   * The core[0][0] load in the ARCH_INFO zone the ''arch_info.bin'' file from the disk file system.
     92   * Then it builds from this ''arch_info.t'' structure the specific ''boot_info_t'' structure for cluster 0, and stores it in the ''kdata'' segment.
     93   * The core[0][0] send IPIs to activate all cores [i][0] in all other clusters.
    9494   
    9595This shows the memory content after this phase.
     
    196196Finally, each core enables its private timer IRQ to activate its private scheduler, and jump to the idle thread code.= Boot procedure =
    197197
    198 [[PageOutline]]
    199 
    200 == A) __General Principles__
    201 
    202 The ALMOS-MKH boot procedure can be decomposed in two phases:
    203  * The architecture dependent phase, implemented by an architecture specific '''boot_loader''' procedure.
    204  * The architecture independent phase, implemented by a generic (architecture independent) '''kernel-init''' procedure.
    205 
    206 As the generic (i.e. architecture independent) kernel initialization procedure is executed in parallel by all kernel instances in all clusters containing at least one core and one memory bank, the main task of the boot-loader is to load - in each cluster - a local copy of
    207 the ALMOS-MKH kernel code. This code includes a description of the hardware architecture, contained in the ''boot_info_t'' data-structure.
    208 
    209 This fixed size ''boot_info_t'' structure is build by the boot-loader, and stored at the beginning of the local copy of the kdata segment. As it contains both general and cluster specific information, the content depends on the cluster:
    210  * general hardware architecture features : number of clusters, topology, etc.
    211  * available external (shared) peripherals : types and features.
    212  * number of cores in cluster,
    213  * available internal (private) peripherals in cluster : types and features.
    214  * available physical memory in cluster.
    215 
    216 This boot_info_t structure is defined in the '''boot_info.h''' file.
    217 
    218 To build the various boot_info_t structures (one per cluster), the boot-loader uses the '''arch_info_t''' binary structure, that is described in
    219 section [wiki:arch_info Hardware Platform Definition]. This binary structure is contained in the '''arch_info.bin''' file, and must be stored
    220 in the file system root directory.
    221 
    222 This method allows  the boot_loader to check and reconfigure the hardware components, to guaranty that the generated boot_info_t structures contain only functionally tested hardware components.
    223 
    224 We describe below the boot_loader for the TSAR architecture, the boot_loader for the I86 architecture, and the generic kernel initialization procedure.
    225 
    226 == B) __Boot-loader for the TSAR architecture__ ==
    227 
    228 The TSAR boot-loader uses an OS-independent '''pre-loader''', stored in an external ROM, that load the TSAR
    229 '''boot-loader''' code from an external block-device to the memory. This preloader is specific for the TSAR architecture, but independent on the Operating System. It is used by ALMOS-MKH, but also by LINUX, NetBSD, ALMOS_MKH, or the GIET-VM. 
    230 
    231 The TSAR boot_loader allocates - in each cluster containing a physical memory bank - five fixed size memory zones, to store various
    232 binary files or data structures :
    233  ||                                                     ||  size                                              ||  local physical address     ||
    234  || préloader code itself                    ||  PRELOADER_MAX_SIZE (16 Kb)  ||  PRELOADER_BASE(0x0)    ||
    235  || boot-loader code local copy        ||  BOOT_MAX_SIZE (1 Mb)              ||  BOOT_BASE (0x100000)  ||
    236  || arch_info.bin file local copy         ||  ARCHINFO_MAX_SIZE (2 Mb)       ||  ARCHINFO_BASE (0x200000)  ||
    237  || kernel.elf binary file                     ||  KERN_MAX_SIZE (1 Mb)               ||  KERN_BASE (0x400000)  ||
    238  || execution stacks (one per core)   ||  BOOT_STACK_SIZE (1 Mb)           ||  BOOT_STACK_BASE (0x500000)  ||
    239 
    240 The values given in this array are indicative. The actual values are defined by configuration parameters in the '''boot_config.h''' file.
    241 These memory zones are only used for temporary storage : when the TSAR boot_loader completes, and transfer control to the kernel_init procedure,
    242 the kernel code (i.e. the code and data segments) has been copied - in each cluster - in the lowest part of the cluster physical memory.
    243 The four pages (16 Kbytes) reserved for the prelloader are only used in cluster 0.
    244 
    245 A core is identified by  two indexes[cxy][lid] : ''cxy'' is the cluster identifier, an ''lid'' is the core local index in cluster cxy.
    246  
    247 
    248 We describe below the four phases for the TSAR boot-loader:
    249 
    250 === B1. Preloader phase ===
    251 
    252 At reset, the MMU is de-activated, and the extension address registers (for both data and instructions) in all cores[cxy][lid] contain the 0 value.
    253 Therefore, all cores can only access the physical address space of cluster 0.
    254  * In the TSAR_LETI architecture, the preloader is loaded in the first 16 kbytes of the RAM located in cluster 0.
    255  * In the TSAR_IOB architecture, the preloader is stored in an external ROM, that is accessed throug the IO_bridge located in cluster 0.
    256 
    257 All cores execute the same preloader code, but the work done depends on the core identifier. The core[0][0] (i.e. Core0 in cluster 0) load
    258 in local memory of cluster 0, the boot-loader code. All other cores do only one task before going to sleep (low-power) state:
    259 each core activates its private WTI channel in the local ICU (Interrupt Controller Unit) to be wake-up by core [0][0], using an
    260 IPI (Inter Processor Interrupt). 
    261 
    262 This shows the memory content after this first phase.
    263    [[Image(Phys_Mem1.svg)]]
    264 
    265 === B2. Sequencial phase ===
    266 
    267 In this second phase the work is entirely done by core[0][0].
    268 
    269     * The core[0][0] initializes the stack pointer. The boot stack size is a configuration parameter.
    270     * The core[0][0] initializes 2 peripherals: The '''TTY''' terminal (channel 0)  to display log info, and the '''IOC''' to access the disk.
    271     * The core[0][0] loads in cluster 0 the '''arch_info.bin''' file and the  '''kernel.elf''' file at addresses ARCHINFO_BASE and KERN_BASE respectively.
    272     * The core[0][0] uses the '''arch_info.bin'''structure to initialize  the local '''boot_info_t''' structure in cluster 0.
    273     * The core[0][0] send IPIs to activate all cores [i][0] in all other clusters.
    274    
    275 All Core0 in all clusters synchronize through a synchronisation barrier before entering the next phase.
    276 This shows the memory content after this phase.
    277    [[Image(Phys_Mem2.svg)]]
    278 
    279 === B3. partially parallel phase ===
    280 
    281 In each cluster(i), the core[I][0] exécutes the boot-loader code (stored in physical memory of cluster 0), to do he following tasks:
    282     * each core[i][0] analyses the '''arch_info.bin''' structure (stored in physical memory of cluster 0), to search his own cluster identifier '''cxy'''. This is done in parallel by all cores[i][0], and can create contention.
    283     * each core[i][0] updates its own extended address register to access the data stored in its local physical memory. Nevertheless, it still access to the boot code stored in cluster(0), as long as the code has not been copied in local cluster.
    284     * each core[i][0] allocates a private stack at address BOOT_STACK_BASE in its local memory.
    285     * each core[i][0] copy l'image du boot-loader et le fichier '''arch_info.bin''' aux mêmes adresses, respectivement '''0x100000''' et '''0x200000''', dans la mémoire physique locale. À partir d'ici, chaque '''CP0''' peut exécuter le code du boot-loader en local.
    286     * Il copie ensuite l'image du noyau à l'adresse '''0x4000''' de la mémoire physique locale de son cluster (c'est à dire, juste après les quatre pages réservées au prélasser).
    287     * Il utilise la structure '''arch_info.bin''' locale pour initialiser les différents champs de la structure '''boot_info_t''' de son cluster. Cette tâche n'utilise que des accès mémoire locaux puisque toutes les informations nécessaires sont disponibles localement.
    288     * Il arrive à la barrière de synchronisation, et le dernier '''CP0''' débloque tous les '''CP0''' (y compris '''bscpu'''),
    289     *  Chaque CP0 envoie des IPIs pour réveiller les autres cores dans son cluster local.
    290     * Les '''CP0''' se mettent en attente jusqu'à ce que tous les autres cores arrivent à ce point de rendez-vous en utilisant le mécanisme de barrière de synchronisation.
    291 
    292 This shows the memory content after this phase. 
    293    [[Image(Phys_Mem3.svg)]]
    294 
    295 === B4. Fully parallel phase ===
    296 
    297 Chaque core CPi ('''lid''' non nul), réveillé par le CP0 local de son cluster, sort du code du preloader et exécute le boot-loader dans le cluster de boot puisque ses registres d'extension d'adresse ne sont pas encore mis à jour. Une fois sortis du preloader, ces cores décrémentent le compteur de la barrière de synchronisation et débloquent les '''CP0'''. Tous ces '''CP0''' sauf un, se mettent tout de suite en attente jusqu'à ce que les '''CPi''' finissent leur exécution du boot-loader. Le seul '''CP0''' qui n'arrive pas encore à cette barrière de synchronisation, celui du cluster(0,0), peut maintenant écraser le code du preloader en déplaçant l'image du noyau à l'adresse '''0x0''' de l'espace adressable physique du cluster(0,0), puisque tous les cores sont déjà sortis du preloader. Il rejoint ensuite les autres '''CP0''' au dernier point de rendez-vous dans le boot-loader. Les '''CPi''', quant à eux, exécutent, pour le moment, le code du boot-loader se trouvant dans le cluster de boot car leurs registres d'extension d'adresse ont toujours la valeur 0 par défaut. Chacun de ces '''CPi''' effectue les étapes suivantes:
    298     * Il analyse le contenu de '''arch_info.bin''' (dans l'espace adressable physique du cluster de boot) en parcourant le tableau de descripteurs de core pour retrouver son identificateur de cluster '''cxy''' ainsi que son identificateur de core local dans son cluster '''lid'''. Notons que cette étape est exécutée parallèlement par tous les '''CPi''', ce qui entraine une contention, encore plus forte que celle créée par les accès parallèles des '''CP0''', au banc mémoire contenant ce tableau de descripteurs de core .
    299     * Il peut maintenant, à partir de son '''cxy''', mettre à jour les valeurs dans ses registres d'extension d'adresse de code et de données. Comme le '''CP0''' du même cluster a déjà copié les informations nécessaires dans le banc mémoire local aux mêmes adresses que du cluster de boot, il peut toujours exécuter le code du boot-loader en local.
    300     * Il alloue sa pile de boot en initialisant son pointeur de pile à l'adresse '''0x600000 - 4K*lid''' dans l'espace adressable physique locale de son cluster (grâce à la nouvelle valeur dans le registre d'extension d'adresse de code).
    301     * La structure '''boot_info_t''' du cluster étant déjà initialisée, chacun des '''CPi''' ne fait que vérifier les informations qui le concernent.
    302     * Il arrive finalement au point de rendez-vous avec tous les '''CP0''', décrémente le compteur de la barrière de synchronisation et se met en attente.
    303     * Dès que le dernier core arrive à ce point et débloque les autres, tous les cores se branchent à la fonction '''kern_init()'''.
    304 
    305 There is the physical memory content at boot completion.
    306 
    307    [[Image(Phys_Mem4.svg)]]
    308 
    309 At this point, the boot-loader completed its job:
    310  * The kernel code ''kcode'' and ''kdata'' segments are loaded - in all clusters - in the first ''offset'' physical pages.
    311  * The hardware architecture described by the '''arch_info.bin'''file has been analyzed, and copied - in each cluster - in the '''boot_info_t''' structure, stored in the kdata segment.
    312  * Each  local kernel instance can use all the physical memory that is not used to store the kernel ''kcode'' and ''kdata'' segments themselves.
    313 
    314 == C) __Boot-loader for the I86 architecture__ ==
    315 
    316 TODO
    317 
    318 == D) __Generic kernel initialization procedure__ ==
    319 
    320 The kernel_init( boot_info_t * info ) function is the kernel entry point when the boot_loader transfer control to the kernel.
    321 The ''info'' argument is a pointer on the fixed size boot_info_t structure, that is stored in the data kernel segment.
    322 
    323 All cores execute this procedure in parallel, but some tasks are only executed by the CP0 core.
    324 This procedure uses two synchronisation barriers, defined as global variables in the data segment:
    325  * the global_barrier variable is used to synchronize all CP0 cores in all clusters containing a kernel instance.
    326  * the local_barrier variable is used to synchronize all cores in a given cluster.
    327 
    328 The kernel initialization procedure execute sequentially the following steps:
    329 
    330 === D1) Core and cluster identification ===
    331 
    332 Each core has an unique hardware identifier, called '''gid''', that is hard-wired in a read-only register.
    333 From the kernel point of view a core is identified by a composite index (cxy,lid), where '''cxy''' is the cluster identifier, and ''lid'' is a local (continuous) index in the cluster. The association between the gid hardware index and the (cxy,lid) composite index is defined in the boot_info_t structure.
    334 In this first step, each core makes an associative search in the boot_info_t structure to obtain the ('''cxy,lid''') indexes from the '''gid''' index.
    335 Then the CP0 initialize the global variable '''local_cxy''' defining the local cluster identifier.
    336 
    337 === D2) TXT0 device initialization ===
    338 
    339 The core[io_cxy][0] (i.e. CP0 in I/O cluster) initializes the chdev descriptor associated to the kernel text terminal TXT0. This terminal is used by any kernel instance running on any core to display log or debug messages.  This terminal is configured in ''non-descheduling'' mode :
    340 the calling thread call directly the relevant TXT driver, without using a server thread.
    341 
    342 A first synchonization barrier is used to avoid other cores to use the TXT0 terminal before initialization completion.
    343 
    344 === D3) Cluster manager initialization ===
    345 
    346 In each cluster, the CP0 makes the cluster manager initialization, namely the cores descriptors array, and the physical memory allocators.
    347 Then it initializes the local process_zero, containing al kernel threads in a given cluster.
    348 
    349 A second synchonization barrier is used to avoid other cores to access cluster manager before initialization completion.
    350 
    351 === D4) Internal & external devices initialization ===
    352 
    353 In each cluster, the CP0 makes the devices initialization. For multi-channels devices, there is one channel device (called chdev_t) per channel.
    354 For internal (replicated) devices, the khedive descriptors are allocated in the local cluster. For external (shared) devices, the chdev descriptors are regularly distributed on all clusters. These external chdev are indexed by a global index, and the host cluster is computed from this
    355 index by a modulo.
    356 
    357 The internal devices descriptors are created first( ICU, then MMC, then DMA ), because the ICU device is used by all other devices.
    358 Then the WTI mailboxes used for IPIs (Inter Processor Interrupt) are allocated in local ICU : one WTI mailbox per core.
    359 Then each external chdev descriptor is created by the CP0 in the cluster where it must be created.
    360 
    361 A third synchonization barrier is used to avoid other cores to access devices before initialization completion. 
    362 
    363 === D5) Idle thread initialization ===
    364 
    365 In this step, each core creates and initializes its private idle thread descriptor.
    366 
    367 === D6) File system initialization ===
    368 
    369 The CP0 in I/O cluster) initializes the file system.
    370 
    371 A fourth synchonization barrier is used to avoid other cores to access file system before initialization completion. 
    372 
    373 === D7) Scheduler activation ===
    374 
    375 Finally, each core enables its private timer IRQ to activate its private scheduler, and jump to the idle thread code.