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Diffstat (limited to 'kernel/Documentation/x86')
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diff --git a/kernel/Documentation/x86/00-INDEX b/kernel/Documentation/x86/00-INDEX new file mode 100644 index 000000000..692264456 --- /dev/null +++ b/kernel/Documentation/x86/00-INDEX @@ -0,0 +1,20 @@ +00-INDEX + - this file +boot.txt + - List of boot protocol versions +early-microcode.txt + - How to load microcode from an initrd-CPIO archive early to fix CPU issues. +earlyprintk.txt + - Using earlyprintk with a USB2 debug port key. +entry_64.txt + - Describe (some of the) kernel entry points for x86. +exception-tables.txt + - why and how Linux kernel uses exception tables on x86 +mtrr.txt + - how to use x86 Memory Type Range Registers to increase performance +pat.txt + - Page Attribute Table intro and API +usb-legacy-support.txt + - how to fix/avoid quirks when using emulated PS/2 mouse/keyboard. +zero-page.txt + - layout of the first page of memory. diff --git a/kernel/Documentation/x86/boot.txt b/kernel/Documentation/x86/boot.txt new file mode 100644 index 000000000..88b85899d --- /dev/null +++ b/kernel/Documentation/x86/boot.txt @@ -0,0 +1,1131 @@ + THE LINUX/x86 BOOT PROTOCOL + --------------------------- + +On the x86 platform, the Linux kernel uses a rather complicated boot +convention. This has evolved partially due to historical aspects, as +well as the desire in the early days to have the kernel itself be a +bootable image, the complicated PC memory model and due to changed +expectations in the PC industry caused by the effective demise of +real-mode DOS as a mainstream operating system. + +Currently, the following versions of the Linux/x86 boot protocol exist. + +Old kernels: zImage/Image support only. Some very early kernels + may not even support a command line. + +Protocol 2.00: (Kernel 1.3.73) Added bzImage and initrd support, as + well as a formalized way to communicate between the + boot loader and the kernel. setup.S made relocatable, + although the traditional setup area still assumed + writable. + +Protocol 2.01: (Kernel 1.3.76) Added a heap overrun warning. + +Protocol 2.02: (Kernel 2.4.0-test3-pre3) New command line protocol. + Lower the conventional memory ceiling. No overwrite + of the traditional setup area, thus making booting + safe for systems which use the EBDA from SMM or 32-bit + BIOS entry points. zImage deprecated but still + supported. + +Protocol 2.03: (Kernel 2.4.18-pre1) Explicitly makes the highest possible + initrd address available to the bootloader. + +Protocol 2.04: (Kernel 2.6.14) Extend the syssize field to four bytes. + +Protocol 2.05: (Kernel 2.6.20) Make protected mode kernel relocatable. + Introduce relocatable_kernel and kernel_alignment fields. + +Protocol 2.06: (Kernel 2.6.22) Added a field that contains the size of + the boot command line. + +Protocol 2.07: (Kernel 2.6.24) Added paravirtualised boot protocol. + Introduced hardware_subarch and hardware_subarch_data + and KEEP_SEGMENTS flag in load_flags. + +Protocol 2.08: (Kernel 2.6.26) Added crc32 checksum and ELF format + payload. Introduced payload_offset and payload_length + fields to aid in locating the payload. + +Protocol 2.09: (Kernel 2.6.26) Added a field of 64-bit physical + pointer to single linked list of struct setup_data. + +Protocol 2.10: (Kernel 2.6.31) Added a protocol for relaxed alignment + beyond the kernel_alignment added, new init_size and + pref_address fields. Added extended boot loader IDs. + +Protocol 2.11: (Kernel 3.6) Added a field for offset of EFI handover + protocol entry point. + +Protocol 2.12: (Kernel 3.8) Added the xloadflags field and extension fields + to struct boot_params for loading bzImage and ramdisk + above 4G in 64bit. + +**** MEMORY LAYOUT + +The traditional memory map for the kernel loader, used for Image or +zImage kernels, typically looks like: + + | | +0A0000 +------------------------+ + | Reserved for BIOS | Do not use. Reserved for BIOS EBDA. +09A000 +------------------------+ + | Command line | + | Stack/heap | For use by the kernel real-mode code. +098000 +------------------------+ + | Kernel setup | The kernel real-mode code. +090200 +------------------------+ + | Kernel boot sector | The kernel legacy boot sector. +090000 +------------------------+ + | Protected-mode kernel | The bulk of the kernel image. +010000 +------------------------+ + | Boot loader | <- Boot sector entry point 0000:7C00 +001000 +------------------------+ + | Reserved for MBR/BIOS | +000800 +------------------------+ + | Typically used by MBR | +000600 +------------------------+ + | BIOS use only | +000000 +------------------------+ + + +When using bzImage, the protected-mode kernel was relocated to +0x100000 ("high memory"), and the kernel real-mode block (boot sector, +setup, and stack/heap) was made relocatable to any address between +0x10000 and end of low memory. Unfortunately, in protocols 2.00 and +2.01 the 0x90000+ memory range is still used internally by the kernel; +the 2.02 protocol resolves that problem. + +It is desirable to keep the "memory ceiling" -- the highest point in +low memory touched by the boot loader -- as low as possible, since +some newer BIOSes have begun to allocate some rather large amounts of +memory, called the Extended BIOS Data Area, near the top of low +memory. The boot loader should use the "INT 12h" BIOS call to verify +how much low memory is available. + +Unfortunately, if INT 12h reports that the amount of memory is too +low, there is usually nothing the boot loader can do but to report an +error to the user. The boot loader should therefore be designed to +take up as little space in low memory as it reasonably can. For +zImage or old bzImage kernels, which need data written into the +0x90000 segment, the boot loader should make sure not to use memory +above the 0x9A000 point; too many BIOSes will break above that point. + +For a modern bzImage kernel with boot protocol version >= 2.02, a +memory layout like the following is suggested: + + ~ ~ + | Protected-mode kernel | +100000 +------------------------+ + | I/O memory hole | +0A0000 +------------------------+ + | Reserved for BIOS | Leave as much as possible unused + ~ ~ + | Command line | (Can also be below the X+10000 mark) +X+10000 +------------------------+ + | Stack/heap | For use by the kernel real-mode code. +X+08000 +------------------------+ + | Kernel setup | The kernel real-mode code. + | Kernel boot sector | The kernel legacy boot sector. +X +------------------------+ + | Boot loader | <- Boot sector entry point 0000:7C00 +001000 +------------------------+ + | Reserved for MBR/BIOS | +000800 +------------------------+ + | Typically used by MBR | +000600 +------------------------+ + | BIOS use only | +000000 +------------------------+ + +... where the address X is as low as the design of the boot loader +permits. + + +**** THE REAL-MODE KERNEL HEADER + +In the following text, and anywhere in the kernel boot sequence, "a +sector" refers to 512 bytes. It is independent of the actual sector +size of the underlying medium. + +The first step in loading a Linux kernel should be to load the +real-mode code (boot sector and setup code) and then examine the +following header at offset 0x01f1. The real-mode code can total up to +32K, although the boot loader may choose to load only the first two +sectors (1K) and then examine the bootup sector size. + +The header looks like: + +Offset Proto Name Meaning +/Size + +01F1/1 ALL(1 setup_sects The size of the setup in sectors +01F2/2 ALL root_flags If set, the root is mounted readonly +01F4/4 2.04+(2 syssize The size of the 32-bit code in 16-byte paras +01F8/2 ALL ram_size DO NOT USE - for bootsect.S use only +01FA/2 ALL vid_mode Video mode control +01FC/2 ALL root_dev Default root device number +01FE/2 ALL boot_flag 0xAA55 magic number +0200/2 2.00+ jump Jump instruction +0202/4 2.00+ header Magic signature "HdrS" +0206/2 2.00+ version Boot protocol version supported +0208/4 2.00+ realmode_swtch Boot loader hook (see below) +020C/2 2.00+ start_sys_seg The load-low segment (0x1000) (obsolete) +020E/2 2.00+ kernel_version Pointer to kernel version string +0210/1 2.00+ type_of_loader Boot loader identifier +0211/1 2.00+ loadflags Boot protocol option flags +0212/2 2.00+ setup_move_size Move to high memory size (used with hooks) +0214/4 2.00+ code32_start Boot loader hook (see below) +0218/4 2.00+ ramdisk_image initrd load address (set by boot loader) +021C/4 2.00+ ramdisk_size initrd size (set by boot loader) +0220/4 2.00+ bootsect_kludge DO NOT USE - for bootsect.S use only +0224/2 2.01+ heap_end_ptr Free memory after setup end +0226/1 2.02+(3 ext_loader_ver Extended boot loader version +0227/1 2.02+(3 ext_loader_type Extended boot loader ID +0228/4 2.02+ cmd_line_ptr 32-bit pointer to the kernel command line +022C/4 2.03+ initrd_addr_max Highest legal initrd address +0230/4 2.05+ kernel_alignment Physical addr alignment required for kernel +0234/1 2.05+ relocatable_kernel Whether kernel is relocatable or not +0235/1 2.10+ min_alignment Minimum alignment, as a power of two +0236/2 2.12+ xloadflags Boot protocol option flags +0238/4 2.06+ cmdline_size Maximum size of the kernel command line +023C/4 2.07+ hardware_subarch Hardware subarchitecture +0240/8 2.07+ hardware_subarch_data Subarchitecture-specific data +0248/4 2.08+ payload_offset Offset of kernel payload +024C/4 2.08+ payload_length Length of kernel payload +0250/8 2.09+ setup_data 64-bit physical pointer to linked list + of struct setup_data +0258/8 2.10+ pref_address Preferred loading address +0260/4 2.10+ init_size Linear memory required during initialization +0264/4 2.11+ handover_offset Offset of handover entry point + +(1) For backwards compatibility, if the setup_sects field contains 0, the + real value is 4. + +(2) For boot protocol prior to 2.04, the upper two bytes of the syssize + field are unusable, which means the size of a bzImage kernel + cannot be determined. + +(3) Ignored, but safe to set, for boot protocols 2.02-2.09. + +If the "HdrS" (0x53726448) magic number is not found at offset 0x202, +the boot protocol version is "old". Loading an old kernel, the +following parameters should be assumed: + + Image type = zImage + initrd not supported + Real-mode kernel must be located at 0x90000. + +Otherwise, the "version" field contains the protocol version, +e.g. protocol version 2.01 will contain 0x0201 in this field. When +setting fields in the header, you must make sure only to set fields +supported by the protocol version in use. + + +**** DETAILS OF HEADER FIELDS + +For each field, some are information from the kernel to the bootloader +("read"), some are expected to be filled out by the bootloader +("write"), and some are expected to be read and modified by the +bootloader ("modify"). + +All general purpose boot loaders should write the fields marked +(obligatory). Boot loaders who want to load the kernel at a +nonstandard address should fill in the fields marked (reloc); other +boot loaders can ignore those fields. + +The byte order of all fields is littleendian (this is x86, after all.) + +Field name: setup_sects +Type: read +Offset/size: 0x1f1/1 +Protocol: ALL + + The size of the setup code in 512-byte sectors. If this field is + 0, the real value is 4. The real-mode code consists of the boot + sector (always one 512-byte sector) plus the setup code. + +Field name: root_flags +Type: modify (optional) +Offset/size: 0x1f2/2 +Protocol: ALL + + If this field is nonzero, the root defaults to readonly. The use of + this field is deprecated; use the "ro" or "rw" options on the + command line instead. + +Field name: syssize +Type: read +Offset/size: 0x1f4/4 (protocol 2.04+) 0x1f4/2 (protocol ALL) +Protocol: 2.04+ + + The size of the protected-mode code in units of 16-byte paragraphs. + For protocol versions older than 2.04 this field is only two bytes + wide, and therefore cannot be trusted for the size of a kernel if + the LOAD_HIGH flag is set. + +Field name: ram_size +Type: kernel internal +Offset/size: 0x1f8/2 +Protocol: ALL + + This field is obsolete. + +Field name: vid_mode +Type: modify (obligatory) +Offset/size: 0x1fa/2 + + Please see the section on SPECIAL COMMAND LINE OPTIONS. + +Field name: root_dev +Type: modify (optional) +Offset/size: 0x1fc/2 +Protocol: ALL + + The default root device device number. The use of this field is + deprecated, use the "root=" option on the command line instead. + +Field name: boot_flag +Type: read +Offset/size: 0x1fe/2 +Protocol: ALL + + Contains 0xAA55. This is the closest thing old Linux kernels have + to a magic number. + +Field name: jump +Type: read +Offset/size: 0x200/2 +Protocol: 2.00+ + + Contains an x86 jump instruction, 0xEB followed by a signed offset + relative to byte 0x202. This can be used to determine the size of + the header. + +Field name: header +Type: read +Offset/size: 0x202/4 +Protocol: 2.00+ + + Contains the magic number "HdrS" (0x53726448). + +Field name: version +Type: read +Offset/size: 0x206/2 +Protocol: 2.00+ + + Contains the boot protocol version, in (major << 8)+minor format, + e.g. 0x0204 for version 2.04, and 0x0a11 for a hypothetical version + 10.17. + +Field name: realmode_swtch +Type: modify (optional) +Offset/size: 0x208/4 +Protocol: 2.00+ + + Boot loader hook (see ADVANCED BOOT LOADER HOOKS below.) + +Field name: start_sys_seg +Type: read +Offset/size: 0x20c/2 +Protocol: 2.00+ + + The load low segment (0x1000). Obsolete. + +Field name: kernel_version +Type: read +Offset/size: 0x20e/2 +Protocol: 2.00+ + + If set to a nonzero value, contains a pointer to a NUL-terminated + human-readable kernel version number string, less 0x200. This can + be used to display the kernel version to the user. This value + should be less than (0x200*setup_sects). + + For example, if this value is set to 0x1c00, the kernel version + number string can be found at offset 0x1e00 in the kernel file. + This is a valid value if and only if the "setup_sects" field + contains the value 15 or higher, as: + + 0x1c00 < 15*0x200 (= 0x1e00) but + 0x1c00 >= 14*0x200 (= 0x1c00) + + 0x1c00 >> 9 = 14, so the minimum value for setup_secs is 15. + +Field name: type_of_loader +Type: write (obligatory) +Offset/size: 0x210/1 +Protocol: 2.00+ + + If your boot loader has an assigned id (see table below), enter + 0xTV here, where T is an identifier for the boot loader and V is + a version number. Otherwise, enter 0xFF here. + + For boot loader IDs above T = 0xD, write T = 0xE to this field and + write the extended ID minus 0x10 to the ext_loader_type field. + Similarly, the ext_loader_ver field can be used to provide more than + four bits for the bootloader version. + + For example, for T = 0x15, V = 0x234, write: + + type_of_loader <- 0xE4 + ext_loader_type <- 0x05 + ext_loader_ver <- 0x23 + + Assigned boot loader ids (hexadecimal): + + 0 LILO (0x00 reserved for pre-2.00 bootloader) + 1 Loadlin + 2 bootsect-loader (0x20, all other values reserved) + 3 Syslinux + 4 Etherboot/gPXE/iPXE + 5 ELILO + 7 GRUB + 8 U-Boot + 9 Xen + A Gujin + B Qemu + C Arcturus Networks uCbootloader + D kexec-tools + E Extended (see ext_loader_type) + F Special (0xFF = undefined) + 10 Reserved + 11 Minimal Linux Bootloader <http://sebastian-plotz.blogspot.de> + 12 OVMF UEFI virtualization stack + + Please contact <hpa@zytor.com> if you need a bootloader ID + value assigned. + +Field name: loadflags +Type: modify (obligatory) +Offset/size: 0x211/1 +Protocol: 2.00+ + + This field is a bitmask. + + Bit 0 (read): LOADED_HIGH + - If 0, the protected-mode code is loaded at 0x10000. + - If 1, the protected-mode code is loaded at 0x100000. + + Bit 1 (kernel internal): ALSR_FLAG + - Used internally by the compressed kernel to communicate + KASLR status to kernel proper. + If 1, KASLR enabled. + If 0, KASLR disabled. + + Bit 5 (write): QUIET_FLAG + - If 0, print early messages. + - If 1, suppress early messages. + This requests to the kernel (decompressor and early + kernel) to not write early messages that require + accessing the display hardware directly. + + Bit 6 (write): KEEP_SEGMENTS + Protocol: 2.07+ + - If 0, reload the segment registers in the 32bit entry point. + - If 1, do not reload the segment registers in the 32bit entry point. + Assume that %cs %ds %ss %es are all set to flat segments with + a base of 0 (or the equivalent for their environment). + + Bit 7 (write): CAN_USE_HEAP + Set this bit to 1 to indicate that the value entered in the + heap_end_ptr is valid. If this field is clear, some setup code + functionality will be disabled. + +Field name: setup_move_size +Type: modify (obligatory) +Offset/size: 0x212/2 +Protocol: 2.00-2.01 + + When using protocol 2.00 or 2.01, if the real mode kernel is not + loaded at 0x90000, it gets moved there later in the loading + sequence. Fill in this field if you want additional data (such as + the kernel command line) moved in addition to the real-mode kernel + itself. + + The unit is bytes starting with the beginning of the boot sector. + + This field is can be ignored when the protocol is 2.02 or higher, or + if the real-mode code is loaded at 0x90000. + +Field name: code32_start +Type: modify (optional, reloc) +Offset/size: 0x214/4 +Protocol: 2.00+ + + The address to jump to in protected mode. This defaults to the load + address of the kernel, and can be used by the boot loader to + determine the proper load address. + + This field can be modified for two purposes: + + 1. as a boot loader hook (see ADVANCED BOOT LOADER HOOKS below.) + + 2. if a bootloader which does not install a hook loads a + relocatable kernel at a nonstandard address it will have to modify + this field to point to the load address. + +Field name: ramdisk_image +Type: write (obligatory) +Offset/size: 0x218/4 +Protocol: 2.00+ + + The 32-bit linear address of the initial ramdisk or ramfs. Leave at + zero if there is no initial ramdisk/ramfs. + +Field name: ramdisk_size +Type: write (obligatory) +Offset/size: 0x21c/4 +Protocol: 2.00+ + + Size of the initial ramdisk or ramfs. Leave at zero if there is no + initial ramdisk/ramfs. + +Field name: bootsect_kludge +Type: kernel internal +Offset/size: 0x220/4 +Protocol: 2.00+ + + This field is obsolete. + +Field name: heap_end_ptr +Type: write (obligatory) +Offset/size: 0x224/2 +Protocol: 2.01+ + + Set this field to the offset (from the beginning of the real-mode + code) of the end of the setup stack/heap, minus 0x0200. + +Field name: ext_loader_ver +Type: write (optional) +Offset/size: 0x226/1 +Protocol: 2.02+ + + This field is used as an extension of the version number in the + type_of_loader field. The total version number is considered to be + (type_of_loader & 0x0f) + (ext_loader_ver << 4). + + The use of this field is boot loader specific. If not written, it + is zero. + + Kernels prior to 2.6.31 did not recognize this field, but it is safe + to write for protocol version 2.02 or higher. + +Field name: ext_loader_type +Type: write (obligatory if (type_of_loader & 0xf0) == 0xe0) +Offset/size: 0x227/1 +Protocol: 2.02+ + + This field is used as an extension of the type number in + type_of_loader field. If the type in type_of_loader is 0xE, then + the actual type is (ext_loader_type + 0x10). + + This field is ignored if the type in type_of_loader is not 0xE. + + Kernels prior to 2.6.31 did not recognize this field, but it is safe + to write for protocol version 2.02 or higher. + +Field name: cmd_line_ptr +Type: write (obligatory) +Offset/size: 0x228/4 +Protocol: 2.02+ + + Set this field to the linear address of the kernel command line. + The kernel command line can be located anywhere between the end of + the setup heap and 0xA0000; it does not have to be located in the + same 64K segment as the real-mode code itself. + + Fill in this field even if your boot loader does not support a + command line, in which case you can point this to an empty string + (or better yet, to the string "auto".) If this field is left at + zero, the kernel will assume that your boot loader does not support + the 2.02+ protocol. + +Field name: initrd_addr_max +Type: read +Offset/size: 0x22c/4 +Protocol: 2.03+ + + The maximum address that may be occupied by the initial + ramdisk/ramfs contents. For boot protocols 2.02 or earlier, this + field is not present, and the maximum address is 0x37FFFFFF. (This + address is defined as the address of the highest safe byte, so if + your ramdisk is exactly 131072 bytes long and this field is + 0x37FFFFFF, you can start your ramdisk at 0x37FE0000.) + +Field name: kernel_alignment +Type: read/modify (reloc) +Offset/size: 0x230/4 +Protocol: 2.05+ (read), 2.10+ (modify) + + Alignment unit required by the kernel (if relocatable_kernel is + true.) A relocatable kernel that is loaded at an alignment + incompatible with the value in this field will be realigned during + kernel initialization. + + Starting with protocol version 2.10, this reflects the kernel + alignment preferred for optimal performance; it is possible for the + loader to modify this field to permit a lesser alignment. See the + min_alignment and pref_address field below. + +Field name: relocatable_kernel +Type: read (reloc) +Offset/size: 0x234/1 +Protocol: 2.05+ + + If this field is nonzero, the protected-mode part of the kernel can + be loaded at any address that satisfies the kernel_alignment field. + After loading, the boot loader must set the code32_start field to + point to the loaded code, or to a boot loader hook. + +Field name: min_alignment +Type: read (reloc) +Offset/size: 0x235/1 +Protocol: 2.10+ + + This field, if nonzero, indicates as a power of two the minimum + alignment required, as opposed to preferred, by the kernel to boot. + If a boot loader makes use of this field, it should update the + kernel_alignment field with the alignment unit desired; typically: + + kernel_alignment = 1 << min_alignment + + There may be a considerable performance cost with an excessively + misaligned kernel. Therefore, a loader should typically try each + power-of-two alignment from kernel_alignment down to this alignment. + +Field name: xloadflags +Type: read +Offset/size: 0x236/2 +Protocol: 2.12+ + + This field is a bitmask. + + Bit 0 (read): XLF_KERNEL_64 + - If 1, this kernel has the legacy 64-bit entry point at 0x200. + + Bit 1 (read): XLF_CAN_BE_LOADED_ABOVE_4G + - If 1, kernel/boot_params/cmdline/ramdisk can be above 4G. + + Bit 2 (read): XLF_EFI_HANDOVER_32 + - If 1, the kernel supports the 32-bit EFI handoff entry point + given at handover_offset. + + Bit 3 (read): XLF_EFI_HANDOVER_64 + - If 1, the kernel supports the 64-bit EFI handoff entry point + given at handover_offset + 0x200. + + Bit 4 (read): XLF_EFI_KEXEC + - If 1, the kernel supports kexec EFI boot with EFI runtime support. + +Field name: cmdline_size +Type: read +Offset/size: 0x238/4 +Protocol: 2.06+ + + The maximum size of the command line without the terminating + zero. This means that the command line can contain at most + cmdline_size characters. With protocol version 2.05 and earlier, the + maximum size was 255. + +Field name: hardware_subarch +Type: write (optional, defaults to x86/PC) +Offset/size: 0x23c/4 +Protocol: 2.07+ + + In a paravirtualized environment the hardware low level architectural + pieces such as interrupt handling, page table handling, and + accessing process control registers needs to be done differently. + + This field allows the bootloader to inform the kernel we are in one + one of those environments. + + 0x00000000 The default x86/PC environment + 0x00000001 lguest + 0x00000002 Xen + 0x00000003 Moorestown MID + 0x00000004 CE4100 TV Platform + +Field name: hardware_subarch_data +Type: write (subarch-dependent) +Offset/size: 0x240/8 +Protocol: 2.07+ + + A pointer to data that is specific to hardware subarch + This field is currently unused for the default x86/PC environment, + do not modify. + +Field name: payload_offset +Type: read +Offset/size: 0x248/4 +Protocol: 2.08+ + + If non-zero then this field contains the offset from the beginning + of the protected-mode code to the payload. + + The payload may be compressed. The format of both the compressed and + uncompressed data should be determined using the standard magic + numbers. The currently supported compression formats are gzip + (magic numbers 1F 8B or 1F 9E), bzip2 (magic number 42 5A), LZMA + (magic number 5D 00), XZ (magic number FD 37), and LZ4 (magic number + 02 21). The uncompressed payload is currently always ELF (magic + number 7F 45 4C 46). + +Field name: payload_length +Type: read +Offset/size: 0x24c/4 +Protocol: 2.08+ + + The length of the payload. + +Field name: setup_data +Type: write (special) +Offset/size: 0x250/8 +Protocol: 2.09+ + + The 64-bit physical pointer to NULL terminated single linked list of + struct setup_data. This is used to define a more extensible boot + parameters passing mechanism. The definition of struct setup_data is + as follow: + + struct setup_data { + u64 next; + u32 type; + u32 len; + u8 data[0]; + }; + + Where, the next is a 64-bit physical pointer to the next node of + linked list, the next field of the last node is 0; the type is used + to identify the contents of data; the len is the length of data + field; the data holds the real payload. + + This list may be modified at a number of points during the bootup + process. Therefore, when modifying this list one should always make + sure to consider the case where the linked list already contains + entries. + +Field name: pref_address +Type: read (reloc) +Offset/size: 0x258/8 +Protocol: 2.10+ + + This field, if nonzero, represents a preferred load address for the + kernel. A relocating bootloader should attempt to load at this + address if possible. + + A non-relocatable kernel will unconditionally move itself and to run + at this address. + +Field name: init_size +Type: read +Offset/size: 0x260/4 + + This field indicates the amount of linear contiguous memory starting + at the kernel runtime start address that the kernel needs before it + is capable of examining its memory map. This is not the same thing + as the total amount of memory the kernel needs to boot, but it can + be used by a relocating boot loader to help select a safe load + address for the kernel. + + The kernel runtime start address is determined by the following algorithm: + + if (relocatable_kernel) + runtime_start = align_up(load_address, kernel_alignment) + else + runtime_start = pref_address + +Field name: handover_offset +Type: read +Offset/size: 0x264/4 + + This field is the offset from the beginning of the kernel image to + the EFI handover protocol entry point. Boot loaders using the EFI + handover protocol to boot the kernel should jump to this offset. + + See EFI HANDOVER PROTOCOL below for more details. + + +**** THE IMAGE CHECKSUM + +From boot protocol version 2.08 onwards the CRC-32 is calculated over +the entire file using the characteristic polynomial 0x04C11DB7 and an +initial remainder of 0xffffffff. The checksum is appended to the +file; therefore the CRC of the file up to the limit specified in the +syssize field of the header is always 0. + + +**** THE KERNEL COMMAND LINE + +The kernel command line has become an important way for the boot +loader to communicate with the kernel. Some of its options are also +relevant to the boot loader itself, see "special command line options" +below. + +The kernel command line is a null-terminated string. The maximum +length can be retrieved from the field cmdline_size. Before protocol +version 2.06, the maximum was 255 characters. A string that is too +long will be automatically truncated by the kernel. + +If the boot protocol version is 2.02 or later, the address of the +kernel command line is given by the header field cmd_line_ptr (see +above.) This address can be anywhere between the end of the setup +heap and 0xA0000. + +If the protocol version is *not* 2.02 or higher, the kernel +command line is entered using the following protocol: + + At offset 0x0020 (word), "cmd_line_magic", enter the magic + number 0xA33F. + + At offset 0x0022 (word), "cmd_line_offset", enter the offset + of the kernel command line (relative to the start of the + real-mode kernel). + + The kernel command line *must* be within the memory region + covered by setup_move_size, so you may need to adjust this + field. + + +**** MEMORY LAYOUT OF THE REAL-MODE CODE + +The real-mode code requires a stack/heap to be set up, as well as +memory allocated for the kernel command line. This needs to be done +in the real-mode accessible memory in bottom megabyte. + +It should be noted that modern machines often have a sizable Extended +BIOS Data Area (EBDA). As a result, it is advisable to use as little +of the low megabyte as possible. + +Unfortunately, under the following circumstances the 0x90000 memory +segment has to be used: + + - When loading a zImage kernel ((loadflags & 0x01) == 0). + - When loading a 2.01 or earlier boot protocol kernel. + + -> For the 2.00 and 2.01 boot protocols, the real-mode code + can be loaded at another address, but it is internally + relocated to 0x90000. For the "old" protocol, the + real-mode code must be loaded at 0x90000. + +When loading at 0x90000, avoid using memory above 0x9a000. + +For boot protocol 2.02 or higher, the command line does not have to be +located in the same 64K segment as the real-mode setup code; it is +thus permitted to give the stack/heap the full 64K segment and locate +the command line above it. + +The kernel command line should not be located below the real-mode +code, nor should it be located in high memory. + + +**** SAMPLE BOOT CONFIGURATION + +As a sample configuration, assume the following layout of the real +mode segment: + + When loading below 0x90000, use the entire segment: + + 0x0000-0x7fff Real mode kernel + 0x8000-0xdfff Stack and heap + 0xe000-0xffff Kernel command line + + When loading at 0x90000 OR the protocol version is 2.01 or earlier: + + 0x0000-0x7fff Real mode kernel + 0x8000-0x97ff Stack and heap + 0x9800-0x9fff Kernel command line + +Such a boot loader should enter the following fields in the header: + + unsigned long base_ptr; /* base address for real-mode segment */ + + if ( setup_sects == 0 ) { + setup_sects = 4; + } + + if ( protocol >= 0x0200 ) { + type_of_loader = <type code>; + if ( loading_initrd ) { + ramdisk_image = <initrd_address>; + ramdisk_size = <initrd_size>; + } + + if ( protocol >= 0x0202 && loadflags & 0x01 ) + heap_end = 0xe000; + else + heap_end = 0x9800; + + if ( protocol >= 0x0201 ) { + heap_end_ptr = heap_end - 0x200; + loadflags |= 0x80; /* CAN_USE_HEAP */ + } + + if ( protocol >= 0x0202 ) { + cmd_line_ptr = base_ptr + heap_end; + strcpy(cmd_line_ptr, cmdline); + } else { + cmd_line_magic = 0xA33F; + cmd_line_offset = heap_end; + setup_move_size = heap_end + strlen(cmdline)+1; + strcpy(base_ptr+cmd_line_offset, cmdline); + } + } else { + /* Very old kernel */ + + heap_end = 0x9800; + + cmd_line_magic = 0xA33F; + cmd_line_offset = heap_end; + + /* A very old kernel MUST have its real-mode code + loaded at 0x90000 */ + + if ( base_ptr != 0x90000 ) { + /* Copy the real-mode kernel */ + memcpy(0x90000, base_ptr, (setup_sects+1)*512); + base_ptr = 0x90000; /* Relocated */ + } + + strcpy(0x90000+cmd_line_offset, cmdline); + + /* It is recommended to clear memory up to the 32K mark */ + memset(0x90000 + (setup_sects+1)*512, 0, + (64-(setup_sects+1))*512); + } + + +**** LOADING THE REST OF THE KERNEL + +The 32-bit (non-real-mode) kernel starts at offset (setup_sects+1)*512 +in the kernel file (again, if setup_sects == 0 the real value is 4.) +It should be loaded at address 0x10000 for Image/zImage kernels and +0x100000 for bzImage kernels. + +The kernel is a bzImage kernel if the protocol >= 2.00 and the 0x01 +bit (LOAD_HIGH) in the loadflags field is set: + + is_bzImage = (protocol >= 0x0200) && (loadflags & 0x01); + load_address = is_bzImage ? 0x100000 : 0x10000; + +Note that Image/zImage kernels can be up to 512K in size, and thus use +the entire 0x10000-0x90000 range of memory. This means it is pretty +much a requirement for these kernels to load the real-mode part at +0x90000. bzImage kernels allow much more flexibility. + + +**** SPECIAL COMMAND LINE OPTIONS + +If the command line provided by the boot loader is entered by the +user, the user may expect the following command line options to work. +They should normally not be deleted from the kernel command line even +though not all of them are actually meaningful to the kernel. Boot +loader authors who need additional command line options for the boot +loader itself should get them registered in +Documentation/kernel-parameters.txt to make sure they will not +conflict with actual kernel options now or in the future. + + vga=<mode> + <mode> here is either an integer (in C notation, either + decimal, octal, or hexadecimal) or one of the strings + "normal" (meaning 0xFFFF), "ext" (meaning 0xFFFE) or "ask" + (meaning 0xFFFD). This value should be entered into the + vid_mode field, as it is used by the kernel before the command + line is parsed. + + mem=<size> + <size> is an integer in C notation optionally followed by + (case insensitive) K, M, G, T, P or E (meaning << 10, << 20, + << 30, << 40, << 50 or << 60). This specifies the end of + memory to the kernel. This affects the possible placement of + an initrd, since an initrd should be placed near end of + memory. Note that this is an option to *both* the kernel and + the bootloader! + + initrd=<file> + An initrd should be loaded. The meaning of <file> is + obviously bootloader-dependent, and some boot loaders + (e.g. LILO) do not have such a command. + +In addition, some boot loaders add the following options to the +user-specified command line: + + BOOT_IMAGE=<file> + The boot image which was loaded. Again, the meaning of <file> + is obviously bootloader-dependent. + + auto + The kernel was booted without explicit user intervention. + +If these options are added by the boot loader, it is highly +recommended that they are located *first*, before the user-specified +or configuration-specified command line. Otherwise, "init=/bin/sh" +gets confused by the "auto" option. + + +**** RUNNING THE KERNEL + +The kernel is started by jumping to the kernel entry point, which is +located at *segment* offset 0x20 from the start of the real mode +kernel. This means that if you loaded your real-mode kernel code at +0x90000, the kernel entry point is 9020:0000. + +At entry, ds = es = ss should point to the start of the real-mode +kernel code (0x9000 if the code is loaded at 0x90000), sp should be +set up properly, normally pointing to the top of the heap, and +interrupts should be disabled. Furthermore, to guard against bugs in +the kernel, it is recommended that the boot loader sets fs = gs = ds = +es = ss. + +In our example from above, we would do: + + /* Note: in the case of the "old" kernel protocol, base_ptr must + be == 0x90000 at this point; see the previous sample code */ + + seg = base_ptr >> 4; + + cli(); /* Enter with interrupts disabled! */ + + /* Set up the real-mode kernel stack */ + _SS = seg; + _SP = heap_end; + + _DS = _ES = _FS = _GS = seg; + jmp_far(seg+0x20, 0); /* Run the kernel */ + +If your boot sector accesses a floppy drive, it is recommended to +switch off the floppy motor before running the kernel, since the +kernel boot leaves interrupts off and thus the motor will not be +switched off, especially if the loaded kernel has the floppy driver as +a demand-loaded module! + + +**** ADVANCED BOOT LOADER HOOKS + +If the boot loader runs in a particularly hostile environment (such as +LOADLIN, which runs under DOS) it may be impossible to follow the +standard memory location requirements. Such a boot loader may use the +following hooks that, if set, are invoked by the kernel at the +appropriate time. The use of these hooks should probably be +considered an absolutely last resort! + +IMPORTANT: All the hooks are required to preserve %esp, %ebp, %esi and +%edi across invocation. + + realmode_swtch: + A 16-bit real mode far subroutine invoked immediately before + entering protected mode. The default routine disables NMI, so + your routine should probably do so, too. + + code32_start: + A 32-bit flat-mode routine *jumped* to immediately after the + transition to protected mode, but before the kernel is + uncompressed. No segments, except CS, are guaranteed to be + set up (current kernels do, but older ones do not); you should + set them up to BOOT_DS (0x18) yourself. + + After completing your hook, you should jump to the address + that was in this field before your boot loader overwrote it + (relocated, if appropriate.) + + +**** 32-bit BOOT PROTOCOL + +For machine with some new BIOS other than legacy BIOS, such as EFI, +LinuxBIOS, etc, and kexec, the 16-bit real mode setup code in kernel +based on legacy BIOS can not be used, so a 32-bit boot protocol needs +to be defined. + +In 32-bit boot protocol, the first step in loading a Linux kernel +should be to setup the boot parameters (struct boot_params, +traditionally known as "zero page"). The memory for struct boot_params +should be allocated and initialized to all zero. Then the setup header +from offset 0x01f1 of kernel image on should be loaded into struct +boot_params and examined. The end of setup header can be calculated as +follow: + + 0x0202 + byte value at offset 0x0201 + +In addition to read/modify/write the setup header of the struct +boot_params as that of 16-bit boot protocol, the boot loader should +also fill the additional fields of the struct boot_params as that +described in zero-page.txt. + +After setting up the struct boot_params, the boot loader can load the +32/64-bit kernel in the same way as that of 16-bit boot protocol. + +In 32-bit boot protocol, the kernel is started by jumping to the +32-bit kernel entry point, which is the start address of loaded +32/64-bit kernel. + +At entry, the CPU must be in 32-bit protected mode with paging +disabled; a GDT must be loaded with the descriptors for selectors +__BOOT_CS(0x10) and __BOOT_DS(0x18); both descriptors must be 4G flat +segment; __BOOT_CS must have execute/read permission, and __BOOT_DS +must have read/write permission; CS must be __BOOT_CS and DS, ES, SS +must be __BOOT_DS; interrupt must be disabled; %esi must hold the base +address of the struct boot_params; %ebp, %edi and %ebx must be zero. + +**** 64-bit BOOT PROTOCOL + +For machine with 64bit cpus and 64bit kernel, we could use 64bit bootloader +and we need a 64-bit boot protocol. + +In 64-bit boot protocol, the first step in loading a Linux kernel +should be to setup the boot parameters (struct boot_params, +traditionally known as "zero page"). The memory for struct boot_params +could be allocated anywhere (even above 4G) and initialized to all zero. +Then, the setup header at offset 0x01f1 of kernel image on should be +loaded into struct boot_params and examined. The end of setup header +can be calculated as follows: + + 0x0202 + byte value at offset 0x0201 + +In addition to read/modify/write the setup header of the struct +boot_params as that of 16-bit boot protocol, the boot loader should +also fill the additional fields of the struct boot_params as described +in zero-page.txt. + +After setting up the struct boot_params, the boot loader can load +64-bit kernel in the same way as that of 16-bit boot protocol, but +kernel could be loaded above 4G. + +In 64-bit boot protocol, the kernel is started by jumping to the +64-bit kernel entry point, which is the start address of loaded +64-bit kernel plus 0x200. + +At entry, the CPU must be in 64-bit mode with paging enabled. +The range with setup_header.init_size from start address of loaded +kernel and zero page and command line buffer get ident mapping; +a GDT must be loaded with the descriptors for selectors +__BOOT_CS(0x10) and __BOOT_DS(0x18); both descriptors must be 4G flat +segment; __BOOT_CS must have execute/read permission, and __BOOT_DS +must have read/write permission; CS must be __BOOT_CS and DS, ES, SS +must be __BOOT_DS; interrupt must be disabled; %rsi must hold the base +address of the struct boot_params. + +**** EFI HANDOVER PROTOCOL + +This protocol allows boot loaders to defer initialisation to the EFI +boot stub. The boot loader is required to load the kernel/initrd(s) +from the boot media and jump to the EFI handover protocol entry point +which is hdr->handover_offset bytes from the beginning of +startup_{32,64}. + +The function prototype for the handover entry point looks like this, + + efi_main(void *handle, efi_system_table_t *table, struct boot_params *bp) + +'handle' is the EFI image handle passed to the boot loader by the EFI +firmware, 'table' is the EFI system table - these are the first two +arguments of the "handoff state" as described in section 2.3 of the +UEFI specification. 'bp' is the boot loader-allocated boot params. + +The boot loader *must* fill out the following fields in bp, + + o hdr.code32_start + o hdr.cmd_line_ptr + o hdr.cmdline_size + o hdr.ramdisk_image (if applicable) + o hdr.ramdisk_size (if applicable) + +All other fields should be zero. diff --git a/kernel/Documentation/x86/early-microcode.txt b/kernel/Documentation/x86/early-microcode.txt new file mode 100644 index 000000000..d62bea679 --- /dev/null +++ b/kernel/Documentation/x86/early-microcode.txt @@ -0,0 +1,42 @@ +Early load microcode +==================== +By Fenghua Yu <fenghua.yu@intel.com> + +Kernel can update microcode in early phase of boot time. Loading microcode early +can fix CPU issues before they are observed during kernel boot time. + +Microcode is stored in an initrd file. The microcode is read from the initrd +file and loaded to CPUs during boot time. + +The format of the combined initrd image is microcode in cpio format followed by +the initrd image (maybe compressed). Kernel parses the combined initrd image +during boot time. The microcode file in cpio name space is: +on Intel: kernel/x86/microcode/GenuineIntel.bin +on AMD : kernel/x86/microcode/AuthenticAMD.bin + +During BSP boot (before SMP starts), if the kernel finds the microcode file in +the initrd file, it parses the microcode and saves matching microcode in memory. +If matching microcode is found, it will be uploaded in BSP and later on in all +APs. + +The cached microcode patch is applied when CPUs resume from a sleep state. + +There are two legacy user space interfaces to load microcode, either through +/dev/cpu/microcode or through /sys/devices/system/cpu/microcode/reload file +in sysfs. + +In addition to these two legacy methods, the early loading method described +here is the third method with which microcode can be uploaded to a system's +CPUs. + +The following example script shows how to generate a new combined initrd file in +/boot/initrd-3.5.0.ucode.img with original microcode microcode.bin and +original initrd image /boot/initrd-3.5.0.img. + +mkdir initrd +cd initrd +mkdir -p kernel/x86/microcode +cp ../microcode.bin kernel/x86/microcode/GenuineIntel.bin (or AuthenticAMD.bin) +find . | cpio -o -H newc >../ucode.cpio +cd .. +cat ucode.cpio /boot/initrd-3.5.0.img >/boot/initrd-3.5.0.ucode.img diff --git a/kernel/Documentation/x86/earlyprintk.txt b/kernel/Documentation/x86/earlyprintk.txt new file mode 100644 index 000000000..688e3eeed --- /dev/null +++ b/kernel/Documentation/x86/earlyprintk.txt @@ -0,0 +1,136 @@ + +Mini-HOWTO for using the earlyprintk=dbgp boot option with a +USB2 Debug port key and a debug cable, on x86 systems. + +You need two computers, the 'USB debug key' special gadget and +and two USB cables, connected like this: + + [host/target] <-------> [USB debug key] <-------> [client/console] + +1. There are a number of specific hardware requirements: + + a.) Host/target system needs to have USB debug port capability. + + You can check this capability by looking at a 'Debug port' bit in + the lspci -vvv output: + + # lspci -vvv + ... + 00:1d.7 USB Controller: Intel Corporation 82801H (ICH8 Family) USB2 EHCI Controller #1 (rev 03) (prog-if 20 [EHCI]) + Subsystem: Lenovo ThinkPad T61 + Control: I/O- Mem+ BusMaster+ SpecCycle- MemWINV- VGASnoop- ParErr- Stepping- SERR+ FastB2B- DisINTx- + Status: Cap+ 66MHz- UDF- FastB2B+ ParErr- DEVSEL=medium >TAbort- <TAbort- <MAbort- >SERR- <PERR- INTx- + Latency: 0 + Interrupt: pin D routed to IRQ 19 + Region 0: Memory at fe227000 (32-bit, non-prefetchable) [size=1K] + Capabilities: [50] Power Management version 2 + Flags: PMEClk- DSI- D1- D2- AuxCurrent=375mA PME(D0+,D1-,D2-,D3hot+,D3cold+) + Status: D0 PME-Enable- DSel=0 DScale=0 PME+ + Capabilities: [58] Debug port: BAR=1 offset=00a0 + ^^^^^^^^^^^ <==================== [ HERE ] + Kernel driver in use: ehci_hcd + Kernel modules: ehci-hcd + ... + +( If your system does not list a debug port capability then you probably + won't be able to use the USB debug key. ) + + b.) You also need a Netchip USB debug cable/key: + + http://www.plxtech.com/products/NET2000/NET20DC/default.asp + + This is a small blue plastic connector with two USB connections, + it draws power from its USB connections. + + c.) You need a second client/console system with a high speed USB 2.0 + port. + + d.) The Netchip device must be plugged directly into the physical + debug port on the "host/target" system. You cannot use a USB hub in + between the physical debug port and the "host/target" system. + + The EHCI debug controller is bound to a specific physical USB + port and the Netchip device will only work as an early printk + device in this port. The EHCI host controllers are electrically + wired such that the EHCI debug controller is hooked up to the + first physical and there is no way to change this via software. + You can find the physical port through experimentation by trying + each physical port on the system and rebooting. Or you can try + and use lsusb or look at the kernel info messages emitted by the + usb stack when you plug a usb device into various ports on the + "host/target" system. + + Some hardware vendors do not expose the usb debug port with a + physical connector and if you find such a device send a complaint + to the hardware vendor, because there is no reason not to wire + this port into one of the physically accessible ports. + + e.) It is also important to note, that many versions of the Netchip + device require the "client/console" system to be plugged into the + right and side of the device (with the product logo facing up and + readable left to right). The reason being is that the 5 volt + power supply is taken from only one side of the device and it + must be the side that does not get rebooted. + +2. Software requirements: + + a.) On the host/target system: + + You need to enable the following kernel config option: + + CONFIG_EARLY_PRINTK_DBGP=y + + And you need to add the boot command line: "earlyprintk=dbgp". + (If you are using Grub, append it to the 'kernel' line in + /etc/grub.conf) + + On systems with more than one EHCI debug controller you must + specify the correct EHCI debug controller number. The ordering + comes from the PCI bus enumeration of the EHCI controllers. The + default with no number argument is "0" the first EHCI debug + controller. To use the second EHCI debug controller, you would + use the command line: "earlyprintk=dbgp1" + + NOTE: normally earlyprintk console gets turned off once the + regular console is alive - use "earlyprintk=dbgp,keep" to keep + this channel open beyond early bootup. This can be useful for + debugging crashes under Xorg, etc. + + b.) On the client/console system: + + You should enable the following kernel config option: + + CONFIG_USB_SERIAL_DEBUG=y + + On the next bootup with the modified kernel you should + get a /dev/ttyUSBx device(s). + + Now this channel of kernel messages is ready to be used: start + your favorite terminal emulator (minicom, etc.) and set + it up to use /dev/ttyUSB0 - or use a raw 'cat /dev/ttyUSBx' to + see the raw output. + + c.) On Nvidia Southbridge based systems: the kernel will try to probe + and find out which port has debug device connected. + +3. Testing that it works fine: + + You can test the output by using earlyprintk=dbgp,keep and provoking + kernel messages on the host/target system. You can provoke a harmless + kernel message by for example doing: + + echo h > /proc/sysrq-trigger + + On the host/target system you should see this help line in "dmesg" output: + + SysRq : HELP : loglevel(0-9) reBoot Crashdump terminate-all-tasks(E) memory-full-oom-kill(F) kill-all-tasks(I) saK show-backtrace-all-active-cpus(L) show-memory-usage(M) nice-all-RT-tasks(N) powerOff show-registers(P) show-all-timers(Q) unRaw Sync show-task-states(T) Unmount show-blocked-tasks(W) dump-ftrace-buffer(Z) + + On the client/console system do: + + cat /dev/ttyUSB0 + + And you should see the help line above displayed shortly after you've + provoked it on the host system. + +If it does not work then please ask about it on the linux-kernel@vger.kernel.org +mailing list or contact the x86 maintainers. diff --git a/kernel/Documentation/x86/entry_64.txt b/kernel/Documentation/x86/entry_64.txt new file mode 100644 index 000000000..9132b8617 --- /dev/null +++ b/kernel/Documentation/x86/entry_64.txt @@ -0,0 +1,104 @@ +This file documents some of the kernel entries in +arch/x86/kernel/entry_64.S. A lot of this explanation is adapted from +an email from Ingo Molnar: + +http://lkml.kernel.org/r/<20110529191055.GC9835%40elte.hu> + +The x86 architecture has quite a few different ways to jump into +kernel code. Most of these entry points are registered in +arch/x86/kernel/traps.c and implemented in arch/x86/kernel/entry_64.S +for 64-bit, arch/x86/kernel/entry_32.S for 32-bit and finally +arch/x86/ia32/ia32entry.S which implements the 32-bit compatibility +syscall entry points and thus provides for 32-bit processes the +ability to execute syscalls when running on 64-bit kernels. + +The IDT vector assignments are listed in arch/x86/include/asm/irq_vectors.h. + +Some of these entries are: + + - system_call: syscall instruction from 64-bit code. + + - ia32_syscall: int 0x80 from 32-bit or 64-bit code; compat syscall + either way. + + - ia32_syscall, ia32_sysenter: syscall and sysenter from 32-bit + code + + - interrupt: An array of entries. Every IDT vector that doesn't + explicitly point somewhere else gets set to the corresponding + value in interrupts. These point to a whole array of + magically-generated functions that make their way to do_IRQ with + the interrupt number as a parameter. + + - APIC interrupts: Various special-purpose interrupts for things + like TLB shootdown. + + - Architecturally-defined exceptions like divide_error. + +There are a few complexities here. The different x86-64 entries +have different calling conventions. The syscall and sysenter +instructions have their own peculiar calling conventions. Some of +the IDT entries push an error code onto the stack; others don't. +IDT entries using the IST alternative stack mechanism need their own +magic to get the stack frames right. (You can find some +documentation in the AMD APM, Volume 2, Chapter 8 and the Intel SDM, +Volume 3, Chapter 6.) + +Dealing with the swapgs instruction is especially tricky. Swapgs +toggles whether gs is the kernel gs or the user gs. The swapgs +instruction is rather fragile: it must nest perfectly and only in +single depth, it should only be used if entering from user mode to +kernel mode and then when returning to user-space, and precisely +so. If we mess that up even slightly, we crash. + +So when we have a secondary entry, already in kernel mode, we *must +not* use SWAPGS blindly - nor must we forget doing a SWAPGS when it's +not switched/swapped yet. + +Now, there's a secondary complication: there's a cheap way to test +which mode the CPU is in and an expensive way. + +The cheap way is to pick this info off the entry frame on the kernel +stack, from the CS of the ptregs area of the kernel stack: + + xorl %ebx,%ebx + testl $3,CS+8(%rsp) + je error_kernelspace + SWAPGS + +The expensive (paranoid) way is to read back the MSR_GS_BASE value +(which is what SWAPGS modifies): + + movl $1,%ebx + movl $MSR_GS_BASE,%ecx + rdmsr + testl %edx,%edx + js 1f /* negative -> in kernel */ + SWAPGS + xorl %ebx,%ebx +1: ret + +If we are at an interrupt or user-trap/gate-alike boundary then we can +use the faster check: the stack will be a reliable indicator of +whether SWAPGS was already done: if we see that we are a secondary +entry interrupting kernel mode execution, then we know that the GS +base has already been switched. If it says that we interrupted +user-space execution then we must do the SWAPGS. + +But if we are in an NMI/MCE/DEBUG/whatever super-atomic entry context, +which might have triggered right after a normal entry wrote CS to the +stack but before we executed SWAPGS, then the only safe way to check +for GS is the slower method: the RDMSR. + +Therefore, super-atomic entries (except NMI, which is handled separately) +must use idtentry with paranoid=1 to handle gsbase correctly. This +triggers three main behavior changes: + + - Interrupt entry will use the slower gsbase check. + - Interrupt entry from user mode will switch off the IST stack. + - Interrupt exit to kernel mode will not attempt to reschedule. + +We try to only use IST entries and the paranoid entry code for vectors +that absolutely need the more expensive check for the GS base - and we +generate all 'normal' entry points with the regular (faster) paranoid=0 +variant. diff --git a/kernel/Documentation/x86/exception-tables.txt b/kernel/Documentation/x86/exception-tables.txt new file mode 100644 index 000000000..32901aa36 --- /dev/null +++ b/kernel/Documentation/x86/exception-tables.txt @@ -0,0 +1,292 @@ + Kernel level exception handling in Linux + Commentary by Joerg Pommnitz <joerg@raleigh.ibm.com> + +When a process runs in kernel mode, it often has to access user +mode memory whose address has been passed by an untrusted program. +To protect itself the kernel has to verify this address. + +In older versions of Linux this was done with the +int verify_area(int type, const void * addr, unsigned long size) +function (which has since been replaced by access_ok()). + +This function verified that the memory area starting at address +'addr' and of size 'size' was accessible for the operation specified +in type (read or write). To do this, verify_read had to look up the +virtual memory area (vma) that contained the address addr. In the +normal case (correctly working program), this test was successful. +It only failed for a few buggy programs. In some kernel profiling +tests, this normally unneeded verification used up a considerable +amount of time. + +To overcome this situation, Linus decided to let the virtual memory +hardware present in every Linux-capable CPU handle this test. + +How does this work? + +Whenever the kernel tries to access an address that is currently not +accessible, the CPU generates a page fault exception and calls the +page fault handler + +void do_page_fault(struct pt_regs *regs, unsigned long error_code) + +in arch/x86/mm/fault.c. The parameters on the stack are set up by +the low level assembly glue in arch/x86/kernel/entry_32.S. The parameter +regs is a pointer to the saved registers on the stack, error_code +contains a reason code for the exception. + +do_page_fault first obtains the unaccessible address from the CPU +control register CR2. If the address is within the virtual address +space of the process, the fault probably occurred, because the page +was not swapped in, write protected or something similar. However, +we are interested in the other case: the address is not valid, there +is no vma that contains this address. In this case, the kernel jumps +to the bad_area label. + +There it uses the address of the instruction that caused the exception +(i.e. regs->eip) to find an address where the execution can continue +(fixup). If this search is successful, the fault handler modifies the +return address (again regs->eip) and returns. The execution will +continue at the address in fixup. + +Where does fixup point to? + +Since we jump to the contents of fixup, fixup obviously points +to executable code. This code is hidden inside the user access macros. +I have picked the get_user macro defined in arch/x86/include/asm/uaccess.h +as an example. The definition is somewhat hard to follow, so let's peek at +the code generated by the preprocessor and the compiler. I selected +the get_user call in drivers/char/sysrq.c for a detailed examination. + +The original code in sysrq.c line 587: + get_user(c, buf); + +The preprocessor output (edited to become somewhat readable): + +( + { + long __gu_err = - 14 , __gu_val = 0; + const __typeof__(*( ( buf ) )) *__gu_addr = ((buf)); + if (((((0 + current_set[0])->tss.segment) == 0x18 ) || + (((sizeof(*(buf))) <= 0xC0000000UL) && + ((unsigned long)(__gu_addr ) <= 0xC0000000UL - (sizeof(*(buf))))))) + do { + __gu_err = 0; + switch ((sizeof(*(buf)))) { + case 1: + __asm__ __volatile__( + "1: mov" "b" " %2,%" "b" "1\n" + "2:\n" + ".section .fixup,\"ax\"\n" + "3: movl %3,%0\n" + " xor" "b" " %" "b" "1,%" "b" "1\n" + " jmp 2b\n" + ".section __ex_table,\"a\"\n" + " .align 4\n" + " .long 1b,3b\n" + ".text" : "=r"(__gu_err), "=q" (__gu_val): "m"((*(struct __large_struct *) + ( __gu_addr )) ), "i"(- 14 ), "0"( __gu_err )) ; + break; + case 2: + __asm__ __volatile__( + "1: mov" "w" " %2,%" "w" "1\n" + "2:\n" + ".section .fixup,\"ax\"\n" + "3: movl %3,%0\n" + " xor" "w" " %" "w" "1,%" "w" "1\n" + " jmp 2b\n" + ".section __ex_table,\"a\"\n" + " .align 4\n" + " .long 1b,3b\n" + ".text" : "=r"(__gu_err), "=r" (__gu_val) : "m"((*(struct __large_struct *) + ( __gu_addr )) ), "i"(- 14 ), "0"( __gu_err )); + break; + case 4: + __asm__ __volatile__( + "1: mov" "l" " %2,%" "" "1\n" + "2:\n" + ".section .fixup,\"ax\"\n" + "3: movl %3,%0\n" + " xor" "l" " %" "" "1,%" "" "1\n" + " jmp 2b\n" + ".section __ex_table,\"a\"\n" + " .align 4\n" " .long 1b,3b\n" + ".text" : "=r"(__gu_err), "=r" (__gu_val) : "m"((*(struct __large_struct *) + ( __gu_addr )) ), "i"(- 14 ), "0"(__gu_err)); + break; + default: + (__gu_val) = __get_user_bad(); + } + } while (0) ; + ((c)) = (__typeof__(*((buf))))__gu_val; + __gu_err; + } +); + +WOW! Black GCC/assembly magic. This is impossible to follow, so let's +see what code gcc generates: + + > xorl %edx,%edx + > movl current_set,%eax + > cmpl $24,788(%eax) + > je .L1424 + > cmpl $-1073741825,64(%esp) + > ja .L1423 + > .L1424: + > movl %edx,%eax + > movl 64(%esp),%ebx + > #APP + > 1: movb (%ebx),%dl /* this is the actual user access */ + > 2: + > .section .fixup,"ax" + > 3: movl $-14,%eax + > xorb %dl,%dl + > jmp 2b + > .section __ex_table,"a" + > .align 4 + > .long 1b,3b + > .text + > #NO_APP + > .L1423: + > movzbl %dl,%esi + +The optimizer does a good job and gives us something we can actually +understand. Can we? The actual user access is quite obvious. Thanks +to the unified address space we can just access the address in user +memory. But what does the .section stuff do????? + +To understand this we have to look at the final kernel: + + > objdump --section-headers vmlinux + > + > vmlinux: file format elf32-i386 + > + > Sections: + > Idx Name Size VMA LMA File off Algn + > 0 .text 00098f40 c0100000 c0100000 00001000 2**4 + > CONTENTS, ALLOC, LOAD, READONLY, CODE + > 1 .fixup 000016bc c0198f40 c0198f40 00099f40 2**0 + > CONTENTS, ALLOC, LOAD, READONLY, CODE + > 2 .rodata 0000f127 c019a5fc c019a5fc 0009b5fc 2**2 + > CONTENTS, ALLOC, LOAD, READONLY, DATA + > 3 __ex_table 000015c0 c01a9724 c01a9724 000aa724 2**2 + > CONTENTS, ALLOC, LOAD, READONLY, DATA + > 4 .data 0000ea58 c01abcf0 c01abcf0 000abcf0 2**4 + > CONTENTS, ALLOC, LOAD, DATA + > 5 .bss 00018e21 c01ba748 c01ba748 000ba748 2**2 + > ALLOC + > 6 .comment 00000ec4 00000000 00000000 000ba748 2**0 + > CONTENTS, READONLY + > 7 .note 00001068 00000ec4 00000ec4 000bb60c 2**0 + > CONTENTS, READONLY + +There are obviously 2 non standard ELF sections in the generated object +file. But first we want to find out what happened to our code in the +final kernel executable: + + > objdump --disassemble --section=.text vmlinux + > + > c017e785 <do_con_write+c1> xorl %edx,%edx + > c017e787 <do_con_write+c3> movl 0xc01c7bec,%eax + > c017e78c <do_con_write+c8> cmpl $0x18,0x314(%eax) + > c017e793 <do_con_write+cf> je c017e79f <do_con_write+db> + > c017e795 <do_con_write+d1> cmpl $0xbfffffff,0x40(%esp,1) + > c017e79d <do_con_write+d9> ja c017e7a7 <do_con_write+e3> + > c017e79f <do_con_write+db> movl %edx,%eax + > c017e7a1 <do_con_write+dd> movl 0x40(%esp,1),%ebx + > c017e7a5 <do_con_write+e1> movb (%ebx),%dl + > c017e7a7 <do_con_write+e3> movzbl %dl,%esi + +The whole user memory access is reduced to 10 x86 machine instructions. +The instructions bracketed in the .section directives are no longer +in the normal execution path. They are located in a different section +of the executable file: + + > objdump --disassemble --section=.fixup vmlinux + > + > c0199ff5 <.fixup+10b5> movl $0xfffffff2,%eax + > c0199ffa <.fixup+10ba> xorb %dl,%dl + > c0199ffc <.fixup+10bc> jmp c017e7a7 <do_con_write+e3> + +And finally: + > objdump --full-contents --section=__ex_table vmlinux + > + > c01aa7c4 93c017c0 e09f19c0 97c017c0 99c017c0 ................ + > c01aa7d4 f6c217c0 e99f19c0 a5e717c0 f59f19c0 ................ + > c01aa7e4 080a18c0 01a019c0 0a0a18c0 04a019c0 ................ + +or in human readable byte order: + + > c01aa7c4 c017c093 c0199fe0 c017c097 c017c099 ................ + > c01aa7d4 c017c2f6 c0199fe9 c017e7a5 c0199ff5 ................ + ^^^^^^^^^^^^^^^^^ + this is the interesting part! + > c01aa7e4 c0180a08 c019a001 c0180a0a c019a004 ................ + +What happened? The assembly directives + +.section .fixup,"ax" +.section __ex_table,"a" + +told the assembler to move the following code to the specified +sections in the ELF object file. So the instructions +3: movl $-14,%eax + xorb %dl,%dl + jmp 2b +ended up in the .fixup section of the object file and the addresses + .long 1b,3b +ended up in the __ex_table section of the object file. 1b and 3b +are local labels. The local label 1b (1b stands for next label 1 +backward) is the address of the instruction that might fault, i.e. +in our case the address of the label 1 is c017e7a5: +the original assembly code: > 1: movb (%ebx),%dl +and linked in vmlinux : > c017e7a5 <do_con_write+e1> movb (%ebx),%dl + +The local label 3 (backwards again) is the address of the code to handle +the fault, in our case the actual value is c0199ff5: +the original assembly code: > 3: movl $-14,%eax +and linked in vmlinux : > c0199ff5 <.fixup+10b5> movl $0xfffffff2,%eax + +The assembly code + > .section __ex_table,"a" + > .align 4 + > .long 1b,3b + +becomes the value pair + > c01aa7d4 c017c2f6 c0199fe9 c017e7a5 c0199ff5 ................ + ^this is ^this is + 1b 3b +c017e7a5,c0199ff5 in the exception table of the kernel. + +So, what actually happens if a fault from kernel mode with no suitable +vma occurs? + +1.) access to invalid address: + > c017e7a5 <do_con_write+e1> movb (%ebx),%dl +2.) MMU generates exception +3.) CPU calls do_page_fault +4.) do page fault calls search_exception_table (regs->eip == c017e7a5); +5.) search_exception_table looks up the address c017e7a5 in the + exception table (i.e. the contents of the ELF section __ex_table) + and returns the address of the associated fault handle code c0199ff5. +6.) do_page_fault modifies its own return address to point to the fault + handle code and returns. +7.) execution continues in the fault handling code. +8.) 8a) EAX becomes -EFAULT (== -14) + 8b) DL becomes zero (the value we "read" from user space) + 8c) execution continues at local label 2 (address of the + instruction immediately after the faulting user access). + +The steps 8a to 8c in a certain way emulate the faulting instruction. + +That's it, mostly. If you look at our example, you might ask why +we set EAX to -EFAULT in the exception handler code. Well, the +get_user macro actually returns a value: 0, if the user access was +successful, -EFAULT on failure. Our original code did not test this +return value, however the inline assembly code in get_user tries to +return -EFAULT. GCC selected EAX to return this value. + +NOTE: +Due to the way that the exception table is built and needs to be ordered, +only use exceptions for code in the .text section. Any other section +will cause the exception table to not be sorted correctly, and the +exceptions will fail. diff --git a/kernel/Documentation/x86/i386/IO-APIC.txt b/kernel/Documentation/x86/i386/IO-APIC.txt new file mode 100644 index 000000000..15f5baf7e --- /dev/null +++ b/kernel/Documentation/x86/i386/IO-APIC.txt @@ -0,0 +1,119 @@ +Most (all) Intel-MP compliant SMP boards have the so-called 'IO-APIC', +which is an enhanced interrupt controller. It enables us to route +hardware interrupts to multiple CPUs, or to CPU groups. Without an +IO-APIC, interrupts from hardware will be delivered only to the +CPU which boots the operating system (usually CPU#0). + +Linux supports all variants of compliant SMP boards, including ones with +multiple IO-APICs. Multiple IO-APICs are used in high-end servers to +distribute IRQ load further. + +There are (a few) known breakages in certain older boards, such bugs are +usually worked around by the kernel. If your MP-compliant SMP board does +not boot Linux, then consult the linux-smp mailing list archives first. + +If your box boots fine with enabled IO-APIC IRQs, then your +/proc/interrupts will look like this one: + + ----------------------------> + hell:~> cat /proc/interrupts + CPU0 + 0: 1360293 IO-APIC-edge timer + 1: 4 IO-APIC-edge keyboard + 2: 0 XT-PIC cascade + 13: 1 XT-PIC fpu + 14: 1448 IO-APIC-edge ide0 + 16: 28232 IO-APIC-level Intel EtherExpress Pro 10/100 Ethernet + 17: 51304 IO-APIC-level eth0 + NMI: 0 + ERR: 0 + hell:~> + <---------------------------- + +Some interrupts are still listed as 'XT PIC', but this is not a problem; +none of those IRQ sources is performance-critical. + + +In the unlikely case that your board does not create a working mp-table, +you can use the pirq= boot parameter to 'hand-construct' IRQ entries. This +is non-trivial though and cannot be automated. One sample /etc/lilo.conf +entry: + + append="pirq=15,11,10" + +The actual numbers depend on your system, on your PCI cards and on their +PCI slot position. Usually PCI slots are 'daisy chained' before they are +connected to the PCI chipset IRQ routing facility (the incoming PIRQ1-4 +lines): + + ,-. ,-. ,-. ,-. ,-. + PIRQ4 ----| |-. ,-| |-. ,-| |-. ,-| |--------| | + |S| \ / |S| \ / |S| \ / |S| |S| + PIRQ3 ----|l|-. `/---|l|-. `/---|l|-. `/---|l|--------|l| + |o| \/ |o| \/ |o| \/ |o| |o| + PIRQ2 ----|t|-./`----|t|-./`----|t|-./`----|t|--------|t| + |1| /\ |2| /\ |3| /\ |4| |5| + PIRQ1 ----| |- `----| |- `----| |- `----| |--------| | + `-' `-' `-' `-' `-' + +Every PCI card emits a PCI IRQ, which can be INTA, INTB, INTC or INTD: + + ,-. + INTD--| | + |S| + INTC--|l| + |o| + INTB--|t| + |x| + INTA--| | + `-' + +These INTA-D PCI IRQs are always 'local to the card', their real meaning +depends on which slot they are in. If you look at the daisy chaining diagram, +a card in slot4, issuing INTA IRQ, it will end up as a signal on PIRQ4 of +the PCI chipset. Most cards issue INTA, this creates optimal distribution +between the PIRQ lines. (distributing IRQ sources properly is not a +necessity, PCI IRQs can be shared at will, but it's a good for performance +to have non shared interrupts). Slot5 should be used for videocards, they +do not use interrupts normally, thus they are not daisy chained either. + +so if you have your SCSI card (IRQ11) in Slot1, Tulip card (IRQ9) in +Slot2, then you'll have to specify this pirq= line: + + append="pirq=11,9" + +the following script tries to figure out such a default pirq= line from +your PCI configuration: + + echo -n pirq=; echo `scanpci | grep T_L | cut -c56-` | sed 's/ /,/g' + +note that this script won't work if you have skipped a few slots or if your +board does not do default daisy-chaining. (or the IO-APIC has the PIRQ pins +connected in some strange way). E.g. if in the above case you have your SCSI +card (IRQ11) in Slot3, and have Slot1 empty: + + append="pirq=0,9,11" + +[value '0' is a generic 'placeholder', reserved for empty (or non-IRQ emitting) +slots.] + +Generally, it's always possible to find out the correct pirq= settings, just +permute all IRQ numbers properly ... it will take some time though. An +'incorrect' pirq line will cause the booting process to hang, or a device +won't function properly (e.g. if it's inserted as a module). + +If you have 2 PCI buses, then you can use up to 8 pirq values, although such +boards tend to have a good configuration. + +Be prepared that it might happen that you need some strange pirq line: + + append="pirq=0,0,0,0,0,0,9,11" + +Use smart trial-and-error techniques to find out the correct pirq line ... + +Good luck and mail to linux-smp@vger.kernel.org or +linux-kernel@vger.kernel.org if you have any problems that are not covered +by this document. + +-- mingo + diff --git a/kernel/Documentation/x86/intel_mpx.txt b/kernel/Documentation/x86/intel_mpx.txt new file mode 100644 index 000000000..818518a3f --- /dev/null +++ b/kernel/Documentation/x86/intel_mpx.txt @@ -0,0 +1,244 @@ +1. Intel(R) MPX Overview +======================== + +Intel(R) Memory Protection Extensions (Intel(R) MPX) is a new capability +introduced into Intel Architecture. Intel MPX provides hardware features +that can be used in conjunction with compiler changes to check memory +references, for those references whose compile-time normal intentions are +usurped at runtime due to buffer overflow or underflow. + +You can tell if your CPU supports MPX by looking in /proc/cpuinfo: + + cat /proc/cpuinfo | grep ' mpx ' + +For more information, please refer to Intel(R) Architecture Instruction +Set Extensions Programming Reference, Chapter 9: Intel(R) Memory Protection +Extensions. + +Note: As of December 2014, no hardware with MPX is available but it is +possible to use SDE (Intel(R) Software Development Emulator) instead, which +can be downloaded from +http://software.intel.com/en-us/articles/intel-software-development-emulator + + +2. How to get the advantage of MPX +================================== + +For MPX to work, changes are required in the kernel, binutils and compiler. +No source changes are required for applications, just a recompile. + +There are a lot of moving parts of this to all work right. The following +is how we expect the compiler, application and kernel to work together. + +1) Application developer compiles with -fmpx. The compiler will add the + instrumentation as well as some setup code called early after the app + starts. New instruction prefixes are noops for old CPUs. +2) That setup code allocates (virtual) space for the "bounds directory", + points the "bndcfgu" register to the directory (must also set the valid + bit) and notifies the kernel (via the new prctl(PR_MPX_ENABLE_MANAGEMENT)) + that the app will be using MPX. The app must be careful not to access + the bounds tables between the time when it populates "bndcfgu" and + when it calls the prctl(). This might be hard to guarantee if the app + is compiled with MPX. You can add "__attribute__((bnd_legacy))" to + the function to disable MPX instrumentation to help guarantee this. + Also be careful not to call out to any other code which might be + MPX-instrumented. +3) The kernel detects that the CPU has MPX, allows the new prctl() to + succeed, and notes the location of the bounds directory. Userspace is + expected to keep the bounds directory at that locationWe note it + instead of reading it each time because the 'xsave' operation needed + to access the bounds directory register is an expensive operation. +4) If the application needs to spill bounds out of the 4 registers, it + issues a bndstx instruction. Since the bounds directory is empty at + this point, a bounds fault (#BR) is raised, the kernel allocates a + bounds table (in the user address space) and makes the relevant entry + in the bounds directory point to the new table. +5) If the application violates the bounds specified in the bounds registers, + a separate kind of #BR is raised which will deliver a signal with + information about the violation in the 'struct siginfo'. +6) Whenever memory is freed, we know that it can no longer contain valid + pointers, and we attempt to free the associated space in the bounds + tables. If an entire table becomes unused, we will attempt to free + the table and remove the entry in the directory. + +To summarize, there are essentially three things interacting here: + +GCC with -fmpx: + * enables annotation of code with MPX instructions and prefixes + * inserts code early in the application to call in to the "gcc runtime" +GCC MPX Runtime: + * Checks for hardware MPX support in cpuid leaf + * allocates virtual space for the bounds directory (malloc() essentially) + * points the hardware BNDCFGU register at the directory + * calls a new prctl(PR_MPX_ENABLE_MANAGEMENT) to notify the kernel to + start managing the bounds directories +Kernel MPX Code: + * Checks for hardware MPX support in cpuid leaf + * Handles #BR exceptions and sends SIGSEGV to the app when it violates + bounds, like during a buffer overflow. + * When bounds are spilled in to an unallocated bounds table, the kernel + notices in the #BR exception, allocates the virtual space, then + updates the bounds directory to point to the new table. It keeps + special track of the memory with a VM_MPX flag. + * Frees unused bounds tables at the time that the memory they described + is unmapped. + + +3. How does MPX kernel code work +================================ + +Handling #BR faults caused by MPX +--------------------------------- + +When MPX is enabled, there are 2 new situations that can generate +#BR faults. + * new bounds tables (BT) need to be allocated to save bounds. + * bounds violation caused by MPX instructions. + +We hook #BR handler to handle these two new situations. + +On-demand kernel allocation of bounds tables +-------------------------------------------- + +MPX only has 4 hardware registers for storing bounds information. If +MPX-enabled code needs more than these 4 registers, it needs to spill +them somewhere. It has two special instructions for this which allow +the bounds to be moved between the bounds registers and some new "bounds +tables". + +#BR exceptions are a new class of exceptions just for MPX. They are +similar conceptually to a page fault and will be raised by the MPX +hardware during both bounds violations or when the tables are not +present. The kernel handles those #BR exceptions for not-present tables +by carving the space out of the normal processes address space and then +pointing the bounds-directory over to it. + +The tables need to be accessed and controlled by userspace because +the instructions for moving bounds in and out of them are extremely +frequent. They potentially happen every time a register points to +memory. Any direct kernel involvement (like a syscall) to access the +tables would obviously destroy performance. + +Why not do this in userspace? MPX does not strictly require anything in +the kernel. It can theoretically be done completely from userspace. Here +are a few ways this could be done. We don't think any of them are practical +in the real-world, but here they are. + +Q: Can virtual space simply be reserved for the bounds tables so that we + never have to allocate them? +A: MPX-enabled application will possibly create a lot of bounds tables in + process address space to save bounds information. These tables can take + up huge swaths of memory (as much as 80% of the memory on the system) + even if we clean them up aggressively. In the worst-case scenario, the + tables can be 4x the size of the data structure being tracked. IOW, a + 1-page structure can require 4 bounds-table pages. An X-GB virtual + area needs 4*X GB of virtual space, plus 2GB for the bounds directory. + If we were to preallocate them for the 128TB of user virtual address + space, we would need to reserve 512TB+2GB, which is larger than the + entire virtual address space today. This means they can not be reserved + ahead of time. Also, a single process's pre-popualated bounds directory + consumes 2GB of virtual *AND* physical memory. IOW, it's completely + infeasible to prepopulate bounds directories. + +Q: Can we preallocate bounds table space at the same time memory is + allocated which might contain pointers that might eventually need + bounds tables? +A: This would work if we could hook the site of each and every memory + allocation syscall. This can be done for small, constrained applications. + But, it isn't practical at a larger scale since a given app has no + way of controlling how all the parts of the app might allocate memory + (think libraries). The kernel is really the only place to intercept + these calls. + +Q: Could a bounds fault be handed to userspace and the tables allocated + there in a signal handler intead of in the kernel? +A: mmap() is not on the list of safe async handler functions and even + if mmap() would work it still requires locking or nasty tricks to + keep track of the allocation state there. + +Having ruled out all of the userspace-only approaches for managing +bounds tables that we could think of, we create them on demand in +the kernel. + +Decoding MPX instructions +------------------------- + +If a #BR is generated due to a bounds violation caused by MPX. +We need to decode MPX instructions to get violation address and +set this address into extended struct siginfo. + +The _sigfault feild of struct siginfo is extended as follow: + +87 /* SIGILL, SIGFPE, SIGSEGV, SIGBUS */ +88 struct { +89 void __user *_addr; /* faulting insn/memory ref. */ +90 #ifdef __ARCH_SI_TRAPNO +91 int _trapno; /* TRAP # which caused the signal */ +92 #endif +93 short _addr_lsb; /* LSB of the reported address */ +94 struct { +95 void __user *_lower; +96 void __user *_upper; +97 } _addr_bnd; +98 } _sigfault; + +The '_addr' field refers to violation address, and new '_addr_and' +field refers to the upper/lower bounds when a #BR is caused. + +Glibc will be also updated to support this new siginfo. So user +can get violation address and bounds when bounds violations occur. + +Cleanup unused bounds tables +---------------------------- + +When a BNDSTX instruction attempts to save bounds to a bounds directory +entry marked as invalid, a #BR is generated. This is an indication that +no bounds table exists for this entry. In this case the fault handler +will allocate a new bounds table on demand. + +Since the kernel allocated those tables on-demand without userspace +knowledge, it is also responsible for freeing them when the associated +mappings go away. + +Here, the solution for this issue is to hook do_munmap() to check +whether one process is MPX enabled. If yes, those bounds tables covered +in the virtual address region which is being unmapped will be freed also. + +Adding new prctl commands +------------------------- + +Two new prctl commands are added to enable and disable MPX bounds tables +management in kernel. + +155 #define PR_MPX_ENABLE_MANAGEMENT 43 +156 #define PR_MPX_DISABLE_MANAGEMENT 44 + +Runtime library in userspace is responsible for allocation of bounds +directory. So kernel have to use XSAVE instruction to get the base +of bounds directory from BNDCFG register. + +But XSAVE is expected to be very expensive. In order to do performance +optimization, we have to get the base of bounds directory and save it +into struct mm_struct to be used in future during PR_MPX_ENABLE_MANAGEMENT +command execution. + + +4. Special rules +================ + +1) If userspace is requesting help from the kernel to do the management +of bounds tables, it may not create or modify entries in the bounds directory. + +Certainly users can allocate bounds tables and forcibly point the bounds +directory at them through XSAVE instruction, and then set valid bit +of bounds entry to have this entry valid. But, the kernel will decline +to assist in managing these tables. + +2) Userspace may not take multiple bounds directory entries and point +them at the same bounds table. + +This is allowed architecturally. See more information "Intel(R) Architecture +Instruction Set Extensions Programming Reference" (9.3.4). + +However, if users did this, the kernel might be fooled in to unmaping an +in-use bounds table since it does not recognize sharing. diff --git a/kernel/Documentation/x86/mtrr.txt b/kernel/Documentation/x86/mtrr.txt new file mode 100644 index 000000000..cc071dc33 --- /dev/null +++ b/kernel/Documentation/x86/mtrr.txt @@ -0,0 +1,305 @@ +MTRR (Memory Type Range Register) control +3 Jun 1999 +Richard Gooch +<rgooch@atnf.csiro.au> + + On Intel P6 family processors (Pentium Pro, Pentium II and later) + the Memory Type Range Registers (MTRRs) may be used to control + processor access to memory ranges. This is most useful when you have + a video (VGA) card on a PCI or AGP bus. Enabling write-combining + allows bus write transfers to be combined into a larger transfer + before bursting over the PCI/AGP bus. This can increase performance + of image write operations 2.5 times or more. + + The Cyrix 6x86, 6x86MX and M II processors have Address Range + Registers (ARRs) which provide a similar functionality to MTRRs. For + these, the ARRs are used to emulate the MTRRs. + + The AMD K6-2 (stepping 8 and above) and K6-3 processors have two + MTRRs. These are supported. The AMD Athlon family provide 8 Intel + style MTRRs. + + The Centaur C6 (WinChip) has 8 MCRs, allowing write-combining. These + are supported. + + The VIA Cyrix III and VIA C3 CPUs offer 8 Intel style MTRRs. + + The CONFIG_MTRR option creates a /proc/mtrr file which may be used + to manipulate your MTRRs. Typically the X server should use + this. This should have a reasonably generic interface so that + similar control registers on other processors can be easily + supported. + + +There are two interfaces to /proc/mtrr: one is an ASCII interface +which allows you to read and write. The other is an ioctl() +interface. The ASCII interface is meant for administration. The +ioctl() interface is meant for C programs (i.e. the X server). The +interfaces are described below, with sample commands and C code. + +=============================================================================== +Reading MTRRs from the shell: + +% cat /proc/mtrr +reg00: base=0x00000000 ( 0MB), size= 128MB: write-back, count=1 +reg01: base=0x08000000 ( 128MB), size= 64MB: write-back, count=1 +=============================================================================== +Creating MTRRs from the C-shell: +# echo "base=0xf8000000 size=0x400000 type=write-combining" >! /proc/mtrr +or if you use bash: +# echo "base=0xf8000000 size=0x400000 type=write-combining" >| /proc/mtrr + +And the result thereof: +% cat /proc/mtrr +reg00: base=0x00000000 ( 0MB), size= 128MB: write-back, count=1 +reg01: base=0x08000000 ( 128MB), size= 64MB: write-back, count=1 +reg02: base=0xf8000000 (3968MB), size= 4MB: write-combining, count=1 + +This is for video RAM at base address 0xf8000000 and size 4 megabytes. To +find out your base address, you need to look at the output of your X +server, which tells you where the linear framebuffer address is. A +typical line that you may get is: + +(--) S3: PCI: 968 rev 0, Linear FB @ 0xf8000000 + +Note that you should only use the value from the X server, as it may +move the framebuffer base address, so the only value you can trust is +that reported by the X server. + +To find out the size of your framebuffer (what, you don't actually +know?), the following line will tell you: + +(--) S3: videoram: 4096k + +That's 4 megabytes, which is 0x400000 bytes (in hexadecimal). +A patch is being written for XFree86 which will make this automatic: +in other words the X server will manipulate /proc/mtrr using the +ioctl() interface, so users won't have to do anything. If you use a +commercial X server, lobby your vendor to add support for MTRRs. +=============================================================================== +Creating overlapping MTRRs: + +%echo "base=0xfb000000 size=0x1000000 type=write-combining" >/proc/mtrr +%echo "base=0xfb000000 size=0x1000 type=uncachable" >/proc/mtrr + +And the results: cat /proc/mtrr +reg00: base=0x00000000 ( 0MB), size= 64MB: write-back, count=1 +reg01: base=0xfb000000 (4016MB), size= 16MB: write-combining, count=1 +reg02: base=0xfb000000 (4016MB), size= 4kB: uncachable, count=1 + +Some cards (especially Voodoo Graphics boards) need this 4 kB area +excluded from the beginning of the region because it is used for +registers. + +NOTE: You can only create type=uncachable region, if the first +region that you created is type=write-combining. +=============================================================================== +Removing MTRRs from the C-shell: +% echo "disable=2" >! /proc/mtrr +or using bash: +% echo "disable=2" >| /proc/mtrr +=============================================================================== +Reading MTRRs from a C program using ioctl()'s: + +/* mtrr-show.c + + Source file for mtrr-show (example program to show MTRRs using ioctl()'s) + + Copyright (C) 1997-1998 Richard Gooch + + This program is free software; you can redistribute it and/or modify + it under the terms of the GNU General Public License as published by + the Free Software Foundation; either version 2 of the License, or + (at your option) any later version. + + This program is distributed in the hope that it will be useful, + but WITHOUT ANY WARRANTY; without even the implied warranty of + MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + GNU General Public License for more details. + + You should have received a copy of the GNU General Public License + along with this program; if not, write to the Free Software + Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. + + Richard Gooch may be reached by email at rgooch@atnf.csiro.au + The postal address is: + Richard Gooch, c/o ATNF, P. O. Box 76, Epping, N.S.W., 2121, Australia. +*/ + +/* + This program will use an ioctl() on /proc/mtrr to show the current MTRR + settings. This is an alternative to reading /proc/mtrr. + + + Written by Richard Gooch 17-DEC-1997 + + Last updated by Richard Gooch 2-MAY-1998 + + +*/ +#include <stdio.h> +#include <stdlib.h> +#include <string.h> +#include <sys/types.h> +#include <sys/stat.h> +#include <fcntl.h> +#include <sys/ioctl.h> +#include <errno.h> +#include <asm/mtrr.h> + +#define TRUE 1 +#define FALSE 0 +#define ERRSTRING strerror (errno) + +static char *mtrr_strings[MTRR_NUM_TYPES] = +{ + "uncachable", /* 0 */ + "write-combining", /* 1 */ + "?", /* 2 */ + "?", /* 3 */ + "write-through", /* 4 */ + "write-protect", /* 5 */ + "write-back", /* 6 */ +}; + +int main () +{ + int fd; + struct mtrr_gentry gentry; + + if ( ( fd = open ("/proc/mtrr", O_RDONLY, 0) ) == -1 ) + { + if (errno == ENOENT) + { + fputs ("/proc/mtrr not found: not supported or you don't have a PPro?\n", + stderr); + exit (1); + } + fprintf (stderr, "Error opening /proc/mtrr\t%s\n", ERRSTRING); + exit (2); + } + for (gentry.regnum = 0; ioctl (fd, MTRRIOC_GET_ENTRY, &gentry) == 0; + ++gentry.regnum) + { + if (gentry.size < 1) + { + fprintf (stderr, "Register: %u disabled\n", gentry.regnum); + continue; + } + fprintf (stderr, "Register: %u base: 0x%lx size: 0x%lx type: %s\n", + gentry.regnum, gentry.base, gentry.size, + mtrr_strings[gentry.type]); + } + if (errno == EINVAL) exit (0); + fprintf (stderr, "Error doing ioctl(2) on /dev/mtrr\t%s\n", ERRSTRING); + exit (3); +} /* End Function main */ +=============================================================================== +Creating MTRRs from a C programme using ioctl()'s: + +/* mtrr-add.c + + Source file for mtrr-add (example programme to add an MTRRs using ioctl()) + + Copyright (C) 1997-1998 Richard Gooch + + This program is free software; you can redistribute it and/or modify + it under the terms of the GNU General Public License as published by + the Free Software Foundation; either version 2 of the License, or + (at your option) any later version. + + This program is distributed in the hope that it will be useful, + but WITHOUT ANY WARRANTY; without even the implied warranty of + MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + GNU General Public License for more details. + + You should have received a copy of the GNU General Public License + along with this program; if not, write to the Free Software + Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. + + Richard Gooch may be reached by email at rgooch@atnf.csiro.au + The postal address is: + Richard Gooch, c/o ATNF, P. O. Box 76, Epping, N.S.W., 2121, Australia. +*/ + +/* + This programme will use an ioctl() on /proc/mtrr to add an entry. The first + available mtrr is used. This is an alternative to writing /proc/mtrr. + + + Written by Richard Gooch 17-DEC-1997 + + Last updated by Richard Gooch 2-MAY-1998 + + +*/ +#include <stdio.h> +#include <string.h> +#include <stdlib.h> +#include <unistd.h> +#include <sys/types.h> +#include <sys/stat.h> +#include <fcntl.h> +#include <sys/ioctl.h> +#include <errno.h> +#include <asm/mtrr.h> + +#define TRUE 1 +#define FALSE 0 +#define ERRSTRING strerror (errno) + +static char *mtrr_strings[MTRR_NUM_TYPES] = +{ + "uncachable", /* 0 */ + "write-combining", /* 1 */ + "?", /* 2 */ + "?", /* 3 */ + "write-through", /* 4 */ + "write-protect", /* 5 */ + "write-back", /* 6 */ +}; + +int main (int argc, char **argv) +{ + int fd; + struct mtrr_sentry sentry; + + if (argc != 4) + { + fprintf (stderr, "Usage:\tmtrr-add base size type\n"); + exit (1); + } + sentry.base = strtoul (argv[1], NULL, 0); + sentry.size = strtoul (argv[2], NULL, 0); + for (sentry.type = 0; sentry.type < MTRR_NUM_TYPES; ++sentry.type) + { + if (strcmp (argv[3], mtrr_strings[sentry.type]) == 0) break; + } + if (sentry.type >= MTRR_NUM_TYPES) + { + fprintf (stderr, "Illegal type: \"%s\"\n", argv[3]); + exit (2); + } + if ( ( fd = open ("/proc/mtrr", O_WRONLY, 0) ) == -1 ) + { + if (errno == ENOENT) + { + fputs ("/proc/mtrr not found: not supported or you don't have a PPro?\n", + stderr); + exit (3); + } + fprintf (stderr, "Error opening /proc/mtrr\t%s\n", ERRSTRING); + exit (4); + } + if (ioctl (fd, MTRRIOC_ADD_ENTRY, &sentry) == -1) + { + fprintf (stderr, "Error doing ioctl(2) on /dev/mtrr\t%s\n", ERRSTRING); + exit (5); + } + fprintf (stderr, "Sleeping for 5 seconds so you can see the new entry\n"); + sleep (5); + close (fd); + fputs ("I've just closed /proc/mtrr so now the new entry should be gone\n", + stderr); +} /* End Function main */ +=============================================================================== diff --git a/kernel/Documentation/x86/pat.txt b/kernel/Documentation/x86/pat.txt new file mode 100644 index 000000000..cf08c9fff --- /dev/null +++ b/kernel/Documentation/x86/pat.txt @@ -0,0 +1,160 @@ + +PAT (Page Attribute Table) + +x86 Page Attribute Table (PAT) allows for setting the memory attribute at the +page level granularity. PAT is complementary to the MTRR settings which allows +for setting of memory types over physical address ranges. However, PAT is +more flexible than MTRR due to its capability to set attributes at page level +and also due to the fact that there are no hardware limitations on number of +such attribute settings allowed. Added flexibility comes with guidelines for +not having memory type aliasing for the same physical memory with multiple +virtual addresses. + +PAT allows for different types of memory attributes. The most commonly used +ones that will be supported at this time are Write-back, Uncached, +Write-combined and Uncached Minus. + + +PAT APIs +-------- + +There are many different APIs in the kernel that allows setting of memory +attributes at the page level. In order to avoid aliasing, these interfaces +should be used thoughtfully. Below is a table of interfaces available, +their intended usage and their memory attribute relationships. Internally, +these APIs use a reserve_memtype()/free_memtype() interface on the physical +address range to avoid any aliasing. + + +------------------------------------------------------------------- +API | RAM | ACPI,... | Reserved/Holes | +-----------------------|----------|------------|------------------| + | | | | +ioremap | -- | UC- | UC- | + | | | | +ioremap_cache | -- | WB | WB | + | | | | +ioremap_nocache | -- | UC- | UC- | + | | | | +ioremap_wc | -- | -- | WC | + | | | | +set_memory_uc | UC- | -- | -- | + set_memory_wb | | | | + | | | | +set_memory_wc | WC | -- | -- | + set_memory_wb | | | | + | | | | +pci sysfs resource | -- | -- | UC- | + | | | | +pci sysfs resource_wc | -- | -- | WC | + is IORESOURCE_PREFETCH| | | | + | | | | +pci proc | -- | -- | UC- | + !PCIIOC_WRITE_COMBINE | | | | + | | | | +pci proc | -- | -- | WC | + PCIIOC_WRITE_COMBINE | | | | + | | | | +/dev/mem | -- | WB/WC/UC- | WB/WC/UC- | + read-write | | | | + | | | | +/dev/mem | -- | UC- | UC- | + mmap SYNC flag | | | | + | | | | +/dev/mem | -- | WB/WC/UC- | WB/WC/UC- | + mmap !SYNC flag | |(from exist-| (from exist- | + and | | ing alias)| ing alias) | + any alias to this area| | | | + | | | | +/dev/mem | -- | WB | WB | + mmap !SYNC flag | | | | + no alias to this area | | | | + and | | | | + MTRR says WB | | | | + | | | | +/dev/mem | -- | -- | UC- | + mmap !SYNC flag | | | | + no alias to this area | | | | + and | | | | + MTRR says !WB | | | | + | | | | +------------------------------------------------------------------- + +Advanced APIs for drivers +------------------------- +A. Exporting pages to users with remap_pfn_range, io_remap_pfn_range, +vm_insert_pfn + +Drivers wanting to export some pages to userspace do it by using mmap +interface and a combination of +1) pgprot_noncached() +2) io_remap_pfn_range() or remap_pfn_range() or vm_insert_pfn() + +With PAT support, a new API pgprot_writecombine is being added. So, drivers can +continue to use the above sequence, with either pgprot_noncached() or +pgprot_writecombine() in step 1, followed by step 2. + +In addition, step 2 internally tracks the region as UC or WC in memtype +list in order to ensure no conflicting mapping. + +Note that this set of APIs only works with IO (non RAM) regions. If driver +wants to export a RAM region, it has to do set_memory_uc() or set_memory_wc() +as step 0 above and also track the usage of those pages and use set_memory_wb() +before the page is freed to free pool. + + + +Notes: + +-- in the above table mean "Not suggested usage for the API". Some of the --'s +are strictly enforced by the kernel. Some others are not really enforced +today, but may be enforced in future. + +For ioremap and pci access through /sys or /proc - The actual type returned +can be more restrictive, in case of any existing aliasing for that address. +For example: If there is an existing uncached mapping, a new ioremap_wc can +return uncached mapping in place of write-combine requested. + +set_memory_[uc|wc] and set_memory_wb should be used in pairs, where driver will +first make a region uc or wc and switch it back to wb after use. + +Over time writes to /proc/mtrr will be deprecated in favor of using PAT based +interfaces. Users writing to /proc/mtrr are suggested to use above interfaces. + +Drivers should use ioremap_[uc|wc] to access PCI BARs with [uc|wc] access +types. + +Drivers should use set_memory_[uc|wc] to set access type for RAM ranges. + + +PAT debugging +------------- + +With CONFIG_DEBUG_FS enabled, PAT memtype list can be examined by + +# mount -t debugfs debugfs /sys/kernel/debug +# cat /sys/kernel/debug/x86/pat_memtype_list +PAT memtype list: +uncached-minus @ 0x7fadf000-0x7fae0000 +uncached-minus @ 0x7fb19000-0x7fb1a000 +uncached-minus @ 0x7fb1a000-0x7fb1b000 +uncached-minus @ 0x7fb1b000-0x7fb1c000 +uncached-minus @ 0x7fb1c000-0x7fb1d000 +uncached-minus @ 0x7fb1d000-0x7fb1e000 +uncached-minus @ 0x7fb1e000-0x7fb25000 +uncached-minus @ 0x7fb25000-0x7fb26000 +uncached-minus @ 0x7fb26000-0x7fb27000 +uncached-minus @ 0x7fb27000-0x7fb28000 +uncached-minus @ 0x7fb28000-0x7fb2e000 +uncached-minus @ 0x7fb2e000-0x7fb2f000 +uncached-minus @ 0x7fb2f000-0x7fb30000 +uncached-minus @ 0x7fb31000-0x7fb32000 +uncached-minus @ 0x80000000-0x90000000 + +This list shows physical address ranges and various PAT settings used to +access those physical address ranges. + +Another, more verbose way of getting PAT related debug messages is with +"debugpat" boot parameter. With this parameter, various debug messages are +printed to dmesg log. + diff --git a/kernel/Documentation/x86/tlb.txt b/kernel/Documentation/x86/tlb.txt new file mode 100644 index 000000000..39d172326 --- /dev/null +++ b/kernel/Documentation/x86/tlb.txt @@ -0,0 +1,75 @@ +When the kernel unmaps or modified the attributes of a range of +memory, it has two choices: + 1. Flush the entire TLB with a two-instruction sequence. This is + a quick operation, but it causes collateral damage: TLB entries + from areas other than the one we are trying to flush will be + destroyed and must be refilled later, at some cost. + 2. Use the invlpg instruction to invalidate a single page at a + time. This could potentialy cost many more instructions, but + it is a much more precise operation, causing no collateral + damage to other TLB entries. + +Which method to do depends on a few things: + 1. The size of the flush being performed. A flush of the entire + address space is obviously better performed by flushing the + entire TLB than doing 2^48/PAGE_SIZE individual flushes. + 2. The contents of the TLB. If the TLB is empty, then there will + be no collateral damage caused by doing the global flush, and + all of the individual flush will have ended up being wasted + work. + 3. The size of the TLB. The larger the TLB, the more collateral + damage we do with a full flush. So, the larger the TLB, the + more attrative an individual flush looks. Data and + instructions have separate TLBs, as do different page sizes. + 4. The microarchitecture. The TLB has become a multi-level + cache on modern CPUs, and the global flushes have become more + expensive relative to single-page flushes. + +There is obviously no way the kernel can know all these things, +especially the contents of the TLB during a given flush. The +sizes of the flush will vary greatly depending on the workload as +well. There is essentially no "right" point to choose. + +You may be doing too many individual invalidations if you see the +invlpg instruction (or instructions _near_ it) show up high in +profiles. If you believe that individual invalidations being +called too often, you can lower the tunable: + + /sys/kernel/debug/x86/tlb_single_page_flush_ceiling + +This will cause us to do the global flush for more cases. +Lowering it to 0 will disable the use of the individual flushes. +Setting it to 1 is a very conservative setting and it should +never need to be 0 under normal circumstances. + +Despite the fact that a single individual flush on x86 is +guaranteed to flush a full 2MB [1], hugetlbfs always uses the full +flushes. THP is treated exactly the same as normal memory. + +You might see invlpg inside of flush_tlb_mm_range() show up in +profiles, or you can use the trace_tlb_flush() tracepoints. to +determine how long the flush operations are taking. + +Essentially, you are balancing the cycles you spend doing invlpg +with the cycles that you spend refilling the TLB later. + +You can measure how expensive TLB refills are by using +performance counters and 'perf stat', like this: + +perf stat -e + cpu/event=0x8,umask=0x84,name=dtlb_load_misses_walk_duration/, + cpu/event=0x8,umask=0x82,name=dtlb_load_misses_walk_completed/, + cpu/event=0x49,umask=0x4,name=dtlb_store_misses_walk_duration/, + cpu/event=0x49,umask=0x2,name=dtlb_store_misses_walk_completed/, + cpu/event=0x85,umask=0x4,name=itlb_misses_walk_duration/, + cpu/event=0x85,umask=0x2,name=itlb_misses_walk_completed/ + +That works on an IvyBridge-era CPU (i5-3320M). Different CPUs +may have differently-named counters, but they should at least +be there in some form. You can use pmu-tools 'ocperf list' +(https://github.com/andikleen/pmu-tools) to find the right +counters for a given CPU. + +1. A footnote in Intel's SDM "4.10.4.2 Recommended Invalidation" + says: "One execution of INVLPG is sufficient even for a page + with size greater than 4 KBytes." diff --git a/kernel/Documentation/x86/usb-legacy-support.txt b/kernel/Documentation/x86/usb-legacy-support.txt new file mode 100644 index 000000000..1894cdfc6 --- /dev/null +++ b/kernel/Documentation/x86/usb-legacy-support.txt @@ -0,0 +1,44 @@ +USB Legacy support +~~~~~~~~~~~~~~~~~~ + +Vojtech Pavlik <vojtech@suse.cz>, January 2004 + + +Also known as "USB Keyboard" or "USB Mouse support" in the BIOS Setup is a +feature that allows one to use the USB mouse and keyboard as if they were +their classic PS/2 counterparts. This means one can use an USB keyboard to +type in LILO for example. + +It has several drawbacks, though: + +1) On some machines, the emulated PS/2 mouse takes over even when no USB + mouse is present and a real PS/2 mouse is present. In that case the extra + features (wheel, extra buttons, touchpad mode) of the real PS/2 mouse may + not be available. + +2) If CONFIG_HIGHMEM64G is enabled, the PS/2 mouse emulation can cause + system crashes, because the SMM BIOS is not expecting to be in PAE mode. + The Intel E7505 is a typical machine where this happens. + +3) If AMD64 64-bit mode is enabled, again system crashes often happen, + because the SMM BIOS isn't expecting the CPU to be in 64-bit mode. The + BIOS manufacturers only test with Windows, and Windows doesn't do 64-bit + yet. + +Solutions: + +Problem 1) can be solved by loading the USB drivers prior to loading the +PS/2 mouse driver. Since the PS/2 mouse driver is in 2.6 compiled into +the kernel unconditionally, this means the USB drivers need to be +compiled-in, too. + +Problem 2) can currently only be solved by either disabling HIGHMEM64G +in the kernel config or USB Legacy support in the BIOS. A BIOS update +could help, but so far no such update exists. + +Problem 3) is usually fixed by a BIOS update. Check the board +manufacturers web site. If an update is not available, disable USB +Legacy support in the BIOS. If this alone doesn't help, try also adding +idle=poll on the kernel command line. The BIOS may be entering the SMM +on the HLT instruction as well. + diff --git a/kernel/Documentation/x86/x86_64/00-INDEX b/kernel/Documentation/x86/x86_64/00-INDEX new file mode 100644 index 000000000..92fc20ab5 --- /dev/null +++ b/kernel/Documentation/x86/x86_64/00-INDEX @@ -0,0 +1,16 @@ +00-INDEX + - This file +boot-options.txt + - AMD64-specific boot options. +cpu-hotplug-spec + - Firmware support for CPU hotplug under Linux/x86-64 +fake-numa-for-cpusets + - Using numa=fake and CPUSets for Resource Management +kernel-stacks + - Context-specific per-processor interrupt stacks. +machinecheck + - Configurable sysfs parameters for the x86-64 machine check code. +mm.txt + - Memory layout of x86-64 (4 level page tables, 46 bits physical). +uefi.txt + - Booting Linux via Unified Extensible Firmware Interface. diff --git a/kernel/Documentation/x86/x86_64/boot-options.txt b/kernel/Documentation/x86/x86_64/boot-options.txt new file mode 100644 index 000000000..522347929 --- /dev/null +++ b/kernel/Documentation/x86/x86_64/boot-options.txt @@ -0,0 +1,284 @@ +AMD64 specific boot options + +There are many others (usually documented in driver documentation), but +only the AMD64 specific ones are listed here. + +Machine check + + Please see Documentation/x86/x86_64/machinecheck for sysfs runtime tunables. + + mce=off + Disable machine check + mce=no_cmci + Disable CMCI(Corrected Machine Check Interrupt) that + Intel processor supports. Usually this disablement is + not recommended, but it might be handy if your hardware + is misbehaving. + Note that you'll get more problems without CMCI than with + due to the shared banks, i.e. you might get duplicated + error logs. + mce=dont_log_ce + Don't make logs for corrected errors. All events reported + as corrected are silently cleared by OS. + This option will be useful if you have no interest in any + of corrected errors. + mce=ignore_ce + Disable features for corrected errors, e.g. polling timer + and CMCI. All events reported as corrected are not cleared + by OS and remained in its error banks. + Usually this disablement is not recommended, however if + there is an agent checking/clearing corrected errors + (e.g. BIOS or hardware monitoring applications), conflicting + with OS's error handling, and you cannot deactivate the agent, + then this option will be a help. + mce=bootlog + Enable logging of machine checks left over from booting. + Disabled by default on AMD because some BIOS leave bogus ones. + If your BIOS doesn't do that it's a good idea to enable though + to make sure you log even machine check events that result + in a reboot. On Intel systems it is enabled by default. + mce=nobootlog + Disable boot machine check logging. + mce=tolerancelevel[,monarchtimeout] (number,number) + tolerance levels: + 0: always panic on uncorrected errors, log corrected errors + 1: panic or SIGBUS on uncorrected errors, log corrected errors + 2: SIGBUS or log uncorrected errors, log corrected errors + 3: never panic or SIGBUS, log all errors (for testing only) + Default is 1 + Can be also set using sysfs which is preferable. + monarchtimeout: + Sets the time in us to wait for other CPUs on machine checks. 0 + to disable. + mce=bios_cmci_threshold + Don't overwrite the bios-set CMCI threshold. This boot option + prevents Linux from overwriting the CMCI threshold set by the + bios. Without this option, Linux always sets the CMCI + threshold to 1. Enabling this may make memory predictive failure + analysis less effective if the bios sets thresholds for memory + errors since we will not see details for all errors. + + nomce (for compatibility with i386): same as mce=off + + Everything else is in sysfs now. + +APICs + + apic Use IO-APIC. Default + + noapic Don't use the IO-APIC. + + disableapic Don't use the local APIC + + nolapic Don't use the local APIC (alias for i386 compatibility) + + pirq=... See Documentation/x86/i386/IO-APIC.txt + + noapictimer Don't set up the APIC timer + + no_timer_check Don't check the IO-APIC timer. This can work around + problems with incorrect timer initialization on some boards. + apicpmtimer + Do APIC timer calibration using the pmtimer. Implies + apicmaintimer. Useful when your PIT timer is totally + broken. + +Timing + + notsc + Don't use the CPU time stamp counter to read the wall time. + This can be used to work around timing problems on multiprocessor systems + with not properly synchronized CPUs. + + nohpet + Don't use the HPET timer. + +Idle loop + + idle=poll + Don't do power saving in the idle loop using HLT, but poll for rescheduling + event. This will make the CPUs eat a lot more power, but may be useful + to get slightly better performance in multiprocessor benchmarks. It also + makes some profiling using performance counters more accurate. + Please note that on systems with MONITOR/MWAIT support (like Intel EM64T + CPUs) this option has no performance advantage over the normal idle loop. + It may also interact badly with hyperthreading. + +Rebooting + + reboot=b[ios] | t[riple] | k[bd] | a[cpi] | e[fi] [, [w]arm | [c]old] + bios Use the CPU reboot vector for warm reset + warm Don't set the cold reboot flag + cold Set the cold reboot flag + triple Force a triple fault (init) + kbd Use the keyboard controller. cold reset (default) + acpi Use the ACPI RESET_REG in the FADT. If ACPI is not configured or the + ACPI reset does not work, the reboot path attempts the reset using + the keyboard controller. + efi Use efi reset_system runtime service. If EFI is not configured or the + EFI reset does not work, the reboot path attempts the reset using + the keyboard controller. + + Using warm reset will be much faster especially on big memory + systems because the BIOS will not go through the memory check. + Disadvantage is that not all hardware will be completely reinitialized + on reboot so there may be boot problems on some systems. + + reboot=force + + Don't stop other CPUs on reboot. This can make reboot more reliable + in some cases. + +Non Executable Mappings + + noexec=on|off + + on Enable(default) + off Disable + +NUMA + + numa=off Only set up a single NUMA node spanning all memory. + + numa=noacpi Don't parse the SRAT table for NUMA setup + + numa=fake=<size>[MG] + If given as a memory unit, fills all system RAM with nodes of + size interleaved over physical nodes. + + numa=fake=<N> + If given as an integer, fills all system RAM with N fake nodes + interleaved over physical nodes. + +ACPI + + acpi=off Don't enable ACPI + acpi=ht Use ACPI boot table parsing, but don't enable ACPI + interpreter + acpi=force Force ACPI on (currently not needed) + + acpi=strict Disable out of spec ACPI workarounds. + + acpi_sci={edge,level,high,low} Set up ACPI SCI interrupt. + + acpi=noirq Don't route interrupts + + acpi=nocmcff Disable firmware first mode for corrected errors. This + disables parsing the HEST CMC error source to check if + firmware has set the FF flag. This may result in + duplicate corrected error reports. + +PCI + + pci=off Don't use PCI + pci=conf1 Use conf1 access. + pci=conf2 Use conf2 access. + pci=rom Assign ROMs. + pci=assign-busses Assign busses + pci=irqmask=MASK Set PCI interrupt mask to MASK + pci=lastbus=NUMBER Scan up to NUMBER busses, no matter what the mptable says. + pci=noacpi Don't use ACPI to set up PCI interrupt routing. + +IOMMU (input/output memory management unit) + + Currently four x86-64 PCI-DMA mapping implementations exist: + + 1. <arch/x86_64/kernel/pci-nommu.c>: use no hardware/software IOMMU at all + (e.g. because you have < 3 GB memory). + Kernel boot message: "PCI-DMA: Disabling IOMMU" + + 2. <arch/x86/kernel/amd_gart_64.c>: AMD GART based hardware IOMMU. + Kernel boot message: "PCI-DMA: using GART IOMMU" + + 3. <arch/x86_64/kernel/pci-swiotlb.c> : Software IOMMU implementation. Used + e.g. if there is no hardware IOMMU in the system and it is need because + you have >3GB memory or told the kernel to us it (iommu=soft)) + Kernel boot message: "PCI-DMA: Using software bounce buffering + for IO (SWIOTLB)" + + 4. <arch/x86_64/pci-calgary.c> : IBM Calgary hardware IOMMU. Used in IBM + pSeries and xSeries servers. This hardware IOMMU supports DMA address + mapping with memory protection, etc. + Kernel boot message: "PCI-DMA: Using Calgary IOMMU" + + iommu=[<size>][,noagp][,off][,force][,noforce][,leak[=<nr_of_leak_pages>] + [,memaper[=<order>]][,merge][,forcesac][,fullflush][,nomerge] + [,noaperture][,calgary] + + General iommu options: + off Don't initialize and use any kind of IOMMU. + noforce Don't force hardware IOMMU usage when it is not needed. + (default). + force Force the use of the hardware IOMMU even when it is + not actually needed (e.g. because < 3 GB memory). + soft Use software bounce buffering (SWIOTLB) (default for + Intel machines). This can be used to prevent the usage + of an available hardware IOMMU. + + iommu options only relevant to the AMD GART hardware IOMMU: + <size> Set the size of the remapping area in bytes. + allowed Overwrite iommu off workarounds for specific chipsets. + fullflush Flush IOMMU on each allocation (default). + nofullflush Don't use IOMMU fullflush. + leak Turn on simple iommu leak tracing (only when + CONFIG_IOMMU_LEAK is on). Default number of leak pages + is 20. + memaper[=<order>] Allocate an own aperture over RAM with size 32MB<<order. + (default: order=1, i.e. 64MB) + merge Do scatter-gather (SG) merging. Implies "force" + (experimental). + nomerge Don't do scatter-gather (SG) merging. + noaperture Ask the IOMMU not to touch the aperture for AGP. + forcesac Force single-address cycle (SAC) mode for masks <40bits + (experimental). + noagp Don't initialize the AGP driver and use full aperture. + allowdac Allow double-address cycle (DAC) mode, i.e. DMA >4GB. + DAC is used with 32-bit PCI to push a 64-bit address in + two cycles. When off all DMA over >4GB is forced through + an IOMMU or software bounce buffering. + nodac Forbid DAC mode, i.e. DMA >4GB. + panic Always panic when IOMMU overflows. + calgary Use the Calgary IOMMU if it is available + + iommu options only relevant to the software bounce buffering (SWIOTLB) IOMMU + implementation: + swiotlb=<pages>[,force] + <pages> Prereserve that many 128K pages for the software IO + bounce buffering. + force Force all IO through the software TLB. + + Settings for the IBM Calgary hardware IOMMU currently found in IBM + pSeries and xSeries machines: + + calgary=[64k,128k,256k,512k,1M,2M,4M,8M] + calgary=[translate_empty_slots] + calgary=[disable=<PCI bus number>] + panic Always panic when IOMMU overflows + + 64k,...,8M - Set the size of each PCI slot's translation table + when using the Calgary IOMMU. This is the size of the translation + table itself in main memory. The smallest table, 64k, covers an IO + space of 32MB; the largest, 8MB table, can cover an IO space of + 4GB. Normally the kernel will make the right choice by itself. + + translate_empty_slots - Enable translation even on slots that have + no devices attached to them, in case a device will be hotplugged + in the future. + + disable=<PCI bus number> - Disable translation on a given PHB. For + example, the built-in graphics adapter resides on the first bridge + (PCI bus number 0); if translation (isolation) is enabled on this + bridge, X servers that access the hardware directly from user + space might stop working. Use this option if you have devices that + are accessed from userspace directly on some PCI host bridge. + +Debugging + + kstack=N Print N words from the kernel stack in oops dumps. + +Miscellaneous + + nogbpages + Do not use GB pages for kernel direct mappings. + gbpages + Use GB pages for kernel direct mappings. diff --git a/kernel/Documentation/x86/x86_64/cpu-hotplug-spec b/kernel/Documentation/x86/x86_64/cpu-hotplug-spec new file mode 100644 index 000000000..3c23e0587 --- /dev/null +++ b/kernel/Documentation/x86/x86_64/cpu-hotplug-spec @@ -0,0 +1,21 @@ +Firmware support for CPU hotplug under Linux/x86-64 +--------------------------------------------------- + +Linux/x86-64 supports CPU hotplug now. For various reasons Linux wants to +know in advance of boot time the maximum number of CPUs that could be plugged +into the system. ACPI 3.0 currently has no official way to supply +this information from the firmware to the operating system. + +In ACPI each CPU needs an LAPIC object in the MADT table (5.2.11.5 in the +ACPI 3.0 specification). ACPI already has the concept of disabled LAPIC +objects by setting the Enabled bit in the LAPIC object to zero. + +For CPU hotplug Linux/x86-64 expects now that any possible future hotpluggable +CPU is already available in the MADT. If the CPU is not available yet +it should have its LAPIC Enabled bit set to 0. Linux will use the number +of disabled LAPICs to compute the maximum number of future CPUs. + +In the worst case the user can overwrite this choice using a command line +option (additional_cpus=...), but it is recommended to supply the correct +number (or a reasonable approximation of it, with erring towards more not less) +in the MADT to avoid manual configuration. diff --git a/kernel/Documentation/x86/x86_64/fake-numa-for-cpusets b/kernel/Documentation/x86/x86_64/fake-numa-for-cpusets new file mode 100644 index 000000000..0f11d9bec --- /dev/null +++ b/kernel/Documentation/x86/x86_64/fake-numa-for-cpusets @@ -0,0 +1,67 @@ +Using numa=fake and CPUSets for Resource Management +Written by David Rientjes <rientjes@cs.washington.edu> + +This document describes how the numa=fake x86_64 command-line option can be used +in conjunction with cpusets for coarse memory management. Using this feature, +you can create fake NUMA nodes that represent contiguous chunks of memory and +assign them to cpusets and their attached tasks. This is a way of limiting the +amount of system memory that are available to a certain class of tasks. + +For more information on the features of cpusets, see +Documentation/cgroups/cpusets.txt. +There are a number of different configurations you can use for your needs. For +more information on the numa=fake command line option and its various ways of +configuring fake nodes, see Documentation/x86/x86_64/boot-options.txt. + +For the purposes of this introduction, we'll assume a very primitive NUMA +emulation setup of "numa=fake=4*512,". This will split our system memory into +four equal chunks of 512M each that we can now use to assign to cpusets. As +you become more familiar with using this combination for resource control, +you'll determine a better setup to minimize the number of nodes you have to deal +with. + +A machine may be split as follows with "numa=fake=4*512," as reported by dmesg: + + Faking node 0 at 0000000000000000-0000000020000000 (512MB) + Faking node 1 at 0000000020000000-0000000040000000 (512MB) + Faking node 2 at 0000000040000000-0000000060000000 (512MB) + Faking node 3 at 0000000060000000-0000000080000000 (512MB) + ... + On node 0 totalpages: 130975 + On node 1 totalpages: 131072 + On node 2 totalpages: 131072 + On node 3 totalpages: 131072 + +Now following the instructions for mounting the cpusets filesystem from +Documentation/cgroups/cpusets.txt, you can assign fake nodes (i.e. contiguous memory +address spaces) to individual cpusets: + + [root@xroads /]# mkdir exampleset + [root@xroads /]# mount -t cpuset none exampleset + [root@xroads /]# mkdir exampleset/ddset + [root@xroads /]# cd exampleset/ddset + [root@xroads /exampleset/ddset]# echo 0-1 > cpus + [root@xroads /exampleset/ddset]# echo 0-1 > mems + +Now this cpuset, 'ddset', will only allowed access to fake nodes 0 and 1 for +memory allocations (1G). + +You can now assign tasks to these cpusets to limit the memory resources +available to them according to the fake nodes assigned as mems: + + [root@xroads /exampleset/ddset]# echo $$ > tasks + [root@xroads /exampleset/ddset]# dd if=/dev/zero of=tmp bs=1024 count=1G + [1] 13425 + +Notice the difference between the system memory usage as reported by +/proc/meminfo between the restricted cpuset case above and the unrestricted +case (i.e. running the same 'dd' command without assigning it to a fake NUMA +cpuset): + Unrestricted Restricted + MemTotal: 3091900 kB 3091900 kB + MemFree: 42113 kB 1513236 kB + +This allows for coarse memory management for the tasks you assign to particular +cpusets. Since cpusets can form a hierarchy, you can create some pretty +interesting combinations of use-cases for various classes of tasks for your +memory management needs. diff --git a/kernel/Documentation/x86/x86_64/kernel-stacks b/kernel/Documentation/x86/x86_64/kernel-stacks new file mode 100644 index 000000000..e3c8a49d1 --- /dev/null +++ b/kernel/Documentation/x86/x86_64/kernel-stacks @@ -0,0 +1,101 @@ +Most of the text from Keith Owens, hacked by AK + +x86_64 page size (PAGE_SIZE) is 4K. + +Like all other architectures, x86_64 has a kernel stack for every +active thread. These thread stacks are THREAD_SIZE (2*PAGE_SIZE) big. +These stacks contain useful data as long as a thread is alive or a +zombie. While the thread is in user space the kernel stack is empty +except for the thread_info structure at the bottom. + +In addition to the per thread stacks, there are specialized stacks +associated with each CPU. These stacks are only used while the kernel +is in control on that CPU; when a CPU returns to user space the +specialized stacks contain no useful data. The main CPU stacks are: + +* Interrupt stack. IRQSTACKSIZE + + Used for external hardware interrupts. If this is the first external + hardware interrupt (i.e. not a nested hardware interrupt) then the + kernel switches from the current task to the interrupt stack. Like + the split thread and interrupt stacks on i386, this gives more room + for kernel interrupt processing without having to increase the size + of every per thread stack. + + The interrupt stack is also used when processing a softirq. + +Switching to the kernel interrupt stack is done by software based on a +per CPU interrupt nest counter. This is needed because x86-64 "IST" +hardware stacks cannot nest without races. + +x86_64 also has a feature which is not available on i386, the ability +to automatically switch to a new stack for designated events such as +double fault or NMI, which makes it easier to handle these unusual +events on x86_64. This feature is called the Interrupt Stack Table +(IST). There can be up to 7 IST entries per CPU. The IST code is an +index into the Task State Segment (TSS). The IST entries in the TSS +point to dedicated stacks; each stack can be a different size. + +An IST is selected by a non-zero value in the IST field of an +interrupt-gate descriptor. When an interrupt occurs and the hardware +loads such a descriptor, the hardware automatically sets the new stack +pointer based on the IST value, then invokes the interrupt handler. If +the interrupt came from user mode, then the interrupt handler prologue +will switch back to the per-thread stack. If software wants to allow +nested IST interrupts then the handler must adjust the IST values on +entry to and exit from the interrupt handler. (This is occasionally +done, e.g. for debug exceptions.) + +Events with different IST codes (i.e. with different stacks) can be +nested. For example, a debug interrupt can safely be interrupted by an +NMI. arch/x86_64/kernel/entry.S::paranoidentry adjusts the stack +pointers on entry to and exit from all IST events, in theory allowing +IST events with the same code to be nested. However in most cases, the +stack size allocated to an IST assumes no nesting for the same code. +If that assumption is ever broken then the stacks will become corrupt. + +The currently assigned IST stacks are :- + +* STACKFAULT_STACK. EXCEPTION_STKSZ (PAGE_SIZE). + + Used for interrupt 12 - Stack Fault Exception (#SS). + + This allows the CPU to recover from invalid stack segments. Rarely + happens. + +* DOUBLEFAULT_STACK. EXCEPTION_STKSZ (PAGE_SIZE). + + Used for interrupt 8 - Double Fault Exception (#DF). + + Invoked when handling one exception causes another exception. Happens + when the kernel is very confused (e.g. kernel stack pointer corrupt). + Using a separate stack allows the kernel to recover from it well enough + in many cases to still output an oops. + +* NMI_STACK. EXCEPTION_STKSZ (PAGE_SIZE). + + Used for non-maskable interrupts (NMI). + + NMI can be delivered at any time, including when the kernel is in the + middle of switching stacks. Using IST for NMI events avoids making + assumptions about the previous state of the kernel stack. + +* DEBUG_STACK. DEBUG_STKSZ + + Used for hardware debug interrupts (interrupt 1) and for software + debug interrupts (INT3). + + When debugging a kernel, debug interrupts (both hardware and + software) can occur at any time. Using IST for these interrupts + avoids making assumptions about the previous state of the kernel + stack. + +* MCE_STACK. EXCEPTION_STKSZ (PAGE_SIZE). + + Used for interrupt 18 - Machine Check Exception (#MC). + + MCE can be delivered at any time, including when the kernel is in the + middle of switching stacks. Using IST for MCE events avoids making + assumptions about the previous state of the kernel stack. + +For more details see the Intel IA32 or AMD AMD64 architecture manuals. diff --git a/kernel/Documentation/x86/x86_64/machinecheck b/kernel/Documentation/x86/x86_64/machinecheck new file mode 100644 index 000000000..b1fb30273 --- /dev/null +++ b/kernel/Documentation/x86/x86_64/machinecheck @@ -0,0 +1,83 @@ + +Configurable sysfs parameters for the x86-64 machine check code. + +Machine checks report internal hardware error conditions detected +by the CPU. Uncorrected errors typically cause a machine check +(often with panic), corrected ones cause a machine check log entry. + +Machine checks are organized in banks (normally associated with +a hardware subsystem) and subevents in a bank. The exact meaning +of the banks and subevent is CPU specific. + +mcelog knows how to decode them. + +When you see the "Machine check errors logged" message in the system +log then mcelog should run to collect and decode machine check entries +from /dev/mcelog. Normally mcelog should be run regularly from a cronjob. + +Each CPU has a directory in /sys/devices/system/machinecheck/machinecheckN +(N = CPU number) + +The directory contains some configurable entries: + +Entries: + +bankNctl +(N bank number) + 64bit Hex bitmask enabling/disabling specific subevents for bank N + When a bit in the bitmask is zero then the respective + subevent will not be reported. + By default all events are enabled. + Note that BIOS maintain another mask to disable specific events + per bank. This is not visible here + +The following entries appear for each CPU, but they are truly shared +between all CPUs. + +check_interval + How often to poll for corrected machine check errors, in seconds + (Note output is hexademical). Default 5 minutes. When the poller + finds MCEs it triggers an exponential speedup (poll more often) on + the polling interval. When the poller stops finding MCEs, it + triggers an exponential backoff (poll less often) on the polling + interval. The check_interval variable is both the initial and + maximum polling interval. 0 means no polling for corrected machine + check errors (but some corrected errors might be still reported + in other ways) + +tolerant + Tolerance level. When a machine check exception occurs for a non + corrected machine check the kernel can take different actions. + Since machine check exceptions can happen any time it is sometimes + risky for the kernel to kill a process because it defies + normal kernel locking rules. The tolerance level configures + how hard the kernel tries to recover even at some risk of + deadlock. Higher tolerant values trade potentially better uptime + with the risk of a crash or even corruption (for tolerant >= 3). + + 0: always panic on uncorrected errors, log corrected errors + 1: panic or SIGBUS on uncorrected errors, log corrected errors + 2: SIGBUS or log uncorrected errors, log corrected errors + 3: never panic or SIGBUS, log all errors (for testing only) + + Default: 1 + + Note this only makes a difference if the CPU allows recovery + from a machine check exception. Current x86 CPUs generally do not. + +trigger + Program to run when a machine check event is detected. + This is an alternative to running mcelog regularly from cron + and allows to detect events faster. +monarch_timeout + How long to wait for the other CPUs to machine check too on a + exception. 0 to disable waiting for other CPUs. + Unit: us + +TBD document entries for AMD threshold interrupt configuration + +For more details about the x86 machine check architecture +see the Intel and AMD architecture manuals from their developer websites. + +For more details about the architecture see +see http://one.firstfloor.org/~andi/mce.pdf diff --git a/kernel/Documentation/x86/x86_64/mm.txt b/kernel/Documentation/x86/x86_64/mm.txt new file mode 100644 index 000000000..05712ac83 --- /dev/null +++ b/kernel/Documentation/x86/x86_64/mm.txt @@ -0,0 +1,42 @@ + +<previous description obsolete, deleted> + +Virtual memory map with 4 level page tables: + +0000000000000000 - 00007fffffffffff (=47 bits) user space, different per mm +hole caused by [48:63] sign extension +ffff800000000000 - ffff87ffffffffff (=43 bits) guard hole, reserved for hypervisor +ffff880000000000 - ffffc7ffffffffff (=64 TB) direct mapping of all phys. memory +ffffc80000000000 - ffffc8ffffffffff (=40 bits) hole +ffffc90000000000 - ffffe8ffffffffff (=45 bits) vmalloc/ioremap space +ffffe90000000000 - ffffe9ffffffffff (=40 bits) hole +ffffea0000000000 - ffffeaffffffffff (=40 bits) virtual memory map (1TB) +... unused hole ... +ffffec0000000000 - fffffc0000000000 (=44 bits) kasan shadow memory (16TB) +... unused hole ... +ffffff0000000000 - ffffff7fffffffff (=39 bits) %esp fixup stacks +... unused hole ... +ffffffff80000000 - ffffffffa0000000 (=512 MB) kernel text mapping, from phys 0 +ffffffffa0000000 - ffffffffff5fffff (=1525 MB) module mapping space +ffffffffff600000 - ffffffffffdfffff (=8 MB) vsyscalls +ffffffffffe00000 - ffffffffffffffff (=2 MB) unused hole + +The direct mapping covers all memory in the system up to the highest +memory address (this means in some cases it can also include PCI memory +holes). + +vmalloc space is lazily synchronized into the different PML4 pages of +the processes using the page fault handler, with init_level4_pgt as +reference. + +Current X86-64 implementations only support 40 bits of address space, +but we support up to 46 bits. This expands into MBZ space in the page tables. + +->trampoline_pgd: + +We map EFI runtime services in the aforementioned PGD in the virtual +range of 64Gb (arbitrarily set, can be raised if needed) + +0xffffffef00000000 - 0xffffffff00000000 + +-Andi Kleen, Jul 2004 diff --git a/kernel/Documentation/x86/x86_64/uefi.txt b/kernel/Documentation/x86/x86_64/uefi.txt new file mode 100644 index 000000000..a5e2b4fdb --- /dev/null +++ b/kernel/Documentation/x86/x86_64/uefi.txt @@ -0,0 +1,42 @@ +General note on [U]EFI x86_64 support +------------------------------------- + +The nomenclature EFI and UEFI are used interchangeably in this document. + +Although the tools below are _not_ needed for building the kernel, +the needed bootloader support and associated tools for x86_64 platforms +with EFI firmware and specifications are listed below. + +1. UEFI specification: http://www.uefi.org + +2. Booting Linux kernel on UEFI x86_64 platform requires bootloader + support. Elilo with x86_64 support can be used. + +3. x86_64 platform with EFI/UEFI firmware. + +Mechanics: +--------- +- Build the kernel with the following configuration. + CONFIG_FB_EFI=y + CONFIG_FRAMEBUFFER_CONSOLE=y + If EFI runtime services are expected, the following configuration should + be selected. + CONFIG_EFI=y + CONFIG_EFI_VARS=y or m # optional +- Create a VFAT partition on the disk +- Copy the following to the VFAT partition: + elilo bootloader with x86_64 support, elilo configuration file, + kernel image built in first step and corresponding + initrd. Instructions on building elilo and its dependencies + can be found in the elilo sourceforge project. +- Boot to EFI shell and invoke elilo choosing the kernel image built + in first step. +- If some or all EFI runtime services don't work, you can try following + kernel command line parameters to turn off some or all EFI runtime + services. + noefi turn off all EFI runtime services + reboot_type=k turn off EFI reboot runtime service +- If the EFI memory map has additional entries not in the E820 map, + you can include those entries in the kernels memory map of available + physical RAM by using the following kernel command line parameter. + add_efi_memmap include EFI memory map of available physical RAM diff --git a/kernel/Documentation/x86/zero-page.txt b/kernel/Documentation/x86/zero-page.txt new file mode 100644 index 000000000..82fbdbc1e --- /dev/null +++ b/kernel/Documentation/x86/zero-page.txt @@ -0,0 +1,37 @@ +The additional fields in struct boot_params as a part of 32-bit boot +protocol of kernel. These should be filled by bootloader or 16-bit +real-mode setup code of the kernel. References/settings to it mainly +are in: + + arch/x86/include/uapi/asm/bootparam.h + + +Offset Proto Name Meaning +/Size + +000/040 ALL screen_info Text mode or frame buffer information + (struct screen_info) +040/014 ALL apm_bios_info APM BIOS information (struct apm_bios_info) +058/008 ALL tboot_addr Physical address of tboot shared page +060/010 ALL ist_info Intel SpeedStep (IST) BIOS support information + (struct ist_info) +080/010 ALL hd0_info hd0 disk parameter, OBSOLETE!! +090/010 ALL hd1_info hd1 disk parameter, OBSOLETE!! +0A0/010 ALL sys_desc_table System description table (struct sys_desc_table) +0B0/010 ALL olpc_ofw_header OLPC's OpenFirmware CIF and friends +0C0/004 ALL ext_ramdisk_image ramdisk_image high 32bits +0C4/004 ALL ext_ramdisk_size ramdisk_size high 32bits +0C8/004 ALL ext_cmd_line_ptr cmd_line_ptr high 32bits +140/080 ALL edid_info Video mode setup (struct edid_info) +1C0/020 ALL efi_info EFI 32 information (struct efi_info) +1E0/004 ALL alk_mem_k Alternative mem check, in KB +1E4/004 ALL scratch Scratch field for the kernel setup code +1E8/001 ALL e820_entries Number of entries in e820_map (below) +1E9/001 ALL eddbuf_entries Number of entries in eddbuf (below) +1EA/001 ALL edd_mbr_sig_buf_entries Number of entries in edd_mbr_sig_buffer + (below) +1EF/001 ALL sentinel Used to detect broken bootloaders +290/040 ALL edd_mbr_sig_buffer EDD MBR signatures +2D0/A00 ALL e820_map E820 memory map table + (array of struct e820entry) +D00/1EC ALL eddbuf EDD data (array of struct edd_info) |