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The DHCPv6 protocol does not itself provide a router address or a
prefix length. This information is instead obtained from the router
advertisements.
Our IPv6 minirouting table construction logic will first construct an
entry for each advertised prefix, and later update the entry to
include an address assigned within that prefix via stateful DHCPv6 (if
applicable).
This logic fails if the address assigned via stateful DHCPv6 does not
fall within any of the advertised prefixes (e.g. if the network is
configured to use DHCPv6-assigned /128 addresses with no advertised
on-link prefixes). We will currently treat this situation as
equivalent to having a manually assigned address with no corresponding
router address or prefix length: the routing table entry will use the
default /64 prefix length and will not include the router address.
DHCPv6 is triggered only in response to a router advertisement with
the "Managed Address Configuration (M)" or "Other Configuration (O)"
flags set, and a router address is therefore available at the point
that we initiate DHCPv6.
Record the router address when initiating DHCPv6, and expose this
router address as part of the DHCPv6 settings block. This allows the
routing table entry for any address assigned via stateful DHCPv6 to
correctly include the router address, even if the assigned address
does not fall within an advertised prefix.
Also provide a fixed /128 prefix length as part of the DHCPv6 settings
block. When an address assigned via stateful DHCPv6 does not fall
within an advertised prefix, this will cause the routing table entry
to have a /128 prefix length as expected. (When such an address does
fall within an advertised prefix, it will continue to use the
advertised prefix length.)
Originally-fixed-by: Guvenc Gulce <guevenc.guelce@sap.com>
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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In a small subnet (with a /31 or /32 subnet mask), all addresses
within the subnet are valid host addresses: there is no separate
network address or directed broadcast address.
The logic used in iPXE to determine whether or not to use a link-layer
broadcast address will currently fail in these subnets. In a /31
subnet, the higher of the two host addresses (i.e. the address with
all host bits set) will be treated as a broadcast address. In a /32
subnet, the single valid host address will be treated as a broadcast
address.
Fix by adding the concept of a host mask, defined such that an address
in the local subnet with all of the mask bits set to zero represents
the network address, and an address in the local subnet with all of
the mask bits set to one represents the directed broadcast address.
For most subnets, this is simply the inverse of the subnet mask. For
small subnets (/31 or /32) we can obtain the desired behaviour by
setting the host mask to all ones, so that only the local broadcast
address 255.255.255.255 will be treated as a broadcast address.
Originally-fixed-by: Lukas Stockner <lstockner@genesiscloud.com>
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Remove the now-unused generalised text widget user interface, along
with the associated concept of a widget set and the implementation of
a read-only label widget.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add support for presenting a dynamic user interface as an interactive
form, alongside the existing support for presenting a dynamic user
interface as a menu.
An interactive form may be used to allow a user to input (or edit)
values for multiple settings on a single screen, as a user-friendly
alternative to prompting for setting values via the "read" command.
In the present implementation, all input fields must fit on a single
screen (with no scrolling), and the only supported widget type is an
editable text box.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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For interactive forms, the concept of a secret value becomes
meaningful (e.g. for password fields).
Add a flag to indicate that an item represents a secret value, and
allow this flag to be set via the "--secret" option of the "item"
command.
This flag has no meaning for menu items, but is silently accepted
anyway to keep the code size minimal.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Generalise the ability to look up a dynamic user interface item by
index or by shortcut key, to allow for reuse of this code for
interactive forms.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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We currently have an abstract model of a dynamic menu as a list of
items, each of which has a name, a description, and assorted metadata
such as a shortcut key. The "menu" and "item" commands construct
representations in this abstract model, and the "choose" command then
presents the items as a single-choice menu, with the selected item's
name used as the output value.
This same abstraction may be used to model a dynamic form as a list of
editable items, each of which has a corresponding setting name, an
optional description label, and assorted metadata such as a shortcut
key. By defining a "form" command as an alias for the "menu" command,
we could construct and present forms using commands such as:
#!ipxe
form Login to ${url}
item username Username or email address
item --secret password Password
present
or
#!ipxe
form Configure IPv4 networking for ${netX/ifname}
item netX/ip IPv4 address
item netX/netmask Subnet mask
item netX/gateway Gateway address
item netX/dns DNS server address
present
Reusing the same abstract model for both menus and forms allows us to
minimise the increase in code size, since the implementation of the
"form" and "item" commands is essentially zero-cost.
Rename everything within the abstract data model from "menu" to
"dynamic user interface" to reflect this generalisation.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add support for wraparound scrolling and allow the tab key to be used
to move forward through a list of elements, wrapping back around to
the beginning of the list on overflow.
This is mildly useful for a menu, and likely to be a strong user
expectation for an interactive form.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Switch terminology for the "item" command from "item <label> <text>"
to "item <name> <text>", in preparation for repurposing the "item"
command to cover interactive forms as well as menus.
Since this renaming affects only a positional parameter, it does not
break compatibility with any existing scripts.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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The msg() and alert() functions currently defined in settings_ui.c
provide a general-purpose facility for printing messages centred on
the screen.
Split this out to a separate file to allow for reuse by the form
presentation code.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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The curses concept of a window has been supported but never actively
used in iPXE since the mucurses library was first implemented in 2006.
Simplify the code by removing the ability to place a widget set in a
specified window, and instead use the standard screen for all drawing
operations.
This simplification allows the widget set parameter to be omitted for
the draw_widget() and edit_widget() operations, since the only reason
for its inclusion was to provide access to the specified window.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Create a generic abstraction of a text widget, refactor the existing
editable text box widget to use this abstraction, add an
implementation of a non-editable text label widget, and generalise the
login user interface to use this generic widget abstraction.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Editable strings currently require a fixed-size buffer, which is
inelegant and limits the potential for creating interactive forms with
a variable number of edit box widgets.
Remove this limitation by switching to using a dynamically allocated
buffer for editable strings and edit box widgets.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add a new setting to provide access to the link layer protocol type
from scripts. This can be useful in order to skip configuring
interfaces based on their link layer protocol or, conversely,
configure only selected interface types (Ethernet, IPoIB, etc.)
Example script:
set idx:int32 0
:loop
isset ${net${idx}/mac} || exit 0
iseq ${net${idx}/linktype} IPoIB && goto try_next ||
autoboot net${idx} ||
:try_next
inc idx && goto loop
Signed-off-by: Pavel Krotkiy <porsh@nebius.com>
Modified-by: Michael Brown <mcb30@ipxe.org>
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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We currently attempt to obtain the autoexec.ipxe script via early use
of the EFI_SIMPLE_FILE_SYSTEM_PROTOCOL or EFI_PXE_BASE_CODE_PROTOCOL
interfaces to obtain an opaque block of memory, which is then
registered as an image at an appropriate point during our startup
sequence. The early use of these existent interfaces allows us to
obtain the script even if our subsequent actions (e.g. disconnecting
drivers in order to connect up our own) may cause the script to become
inaccessible.
This mirrors the approach used under BIOS, where the autoexec.ipxe
script is provided by the prefix (e.g. as an initrd image when using
the .lkrn build of iPXE) and so must be copied into a normally
allocated image from wherever it happens to previously exist in
memory.
We do not currently have support for downloading an autoexec.ipxe
script if we were ourselves downloaded via UEFI HTTP boot.
There is an EFI_HTTP_PROTOCOL defined within the UEFI specification,
but it is so poorly designed as to be unusable for the simple purpose
of downloading an additional file from the same directory. It
provides almost nothing more than a very slim wrapper around
EFI_TCP4_PROTOCOL (or EFI_TCP6_PROTOCOL). It will not handle
redirection, content encoding, retries, or even fundamentals such as
the Content-Length header, leaving all of this up to the caller.
The UEFI HTTP Boot driver will install an EFI_LOAD_FILE_PROTOCOL
instance on the loaded image's device handle. This looks promising at
first since it provides the LoadFile() API call which is specified to
accept an arbitrary filename parameter. However, experimentation (and
inspection of the code in EDK2) reveals a multitude of problems that
prevent this from being usable. Calling LoadFile() will idiotically
restart the entire DHCP process (and potentially pop up a UI requiring
input from the user for e.g. a wireless network password). The
filename provided to LoadFile() will be ignored. Any downloaded file
will be rejected unless it happens to match one of the limited set of
types expected by the UEFI HTTP Boot driver. The list of design
failures and conceptual mismatches is fairly impressive.
Choose to bypass every possible aspect of UEFI HTTP support, and
instead use our own HTTP client and network stack to download the
autoexec.ipxe script over a temporary MNP network device. Since this
approach works for TFTP as well as HTTP, drop the direct use of
EFI_PXE_BASE_CODE_PROTOCOL. For consistency and simplicity, also drop
the direct use of EFI_SIMPLE_FILE_SYSTEM_PROTOCOL and rely upon our
existing support to access local files via "file:" URIs.
This approach results in console output during the "iPXE initialising
devices...ok" message that appears while startup is in progress.
Remove the trailing "ok" so that this intermediate output appears at a
sensible location on the screen. The welcome banner that will be
printed immediately afterwards provides an indication that startup has
completed successfully even absent the explicit "ok".
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Retain a reference to the cached DHCPACK until the late startup phase,
and allow it to be recycled for reuse. This allows the cached DHCPACK
to be used for a temporary MNP network device and then subsequently
reused for the corresponding real network device.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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An MNP network device may be temporarily and non-destructively
installed on top of an existing UEFI network stack without having to
disconnect existing drivers.
Add the ability to create such a temporary network device.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Split out the code that allocates our internal struct efi_device
representations, to allow for the creation of temporary MNP devices in
order to download the autoexec.ipxe script.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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For unknown reasons, miscellaneous versions of gcc seem to struggle
with the static assertions used to ensure the correct layout of the
GCM structures.
Adjust the assertions to use offsetof() rather than direct pointer
comparison, on the basis that offsetof() must be a compile-time
constant value.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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The UEFI HTTP boot mechanism is extraordinarily badly designed, even
by the standards of the UEFI specification in general. It has the
symptoms of a feature that has been designed entirely in terms of user
stories, without any consideration at all being given to the
underlying technical architecture. It does work, provided that you
are doing precisely and only what was envisioned by the product owner.
If you want to try anything outside the bounds of the product owner's
extremely limited imagination, then you are almost certainly about to
enter a world of pain.
As one very minor example of this: the cached DHCP packet is not
available when using HTTP boot. The UEFI HTTP boot code does perform
DHCP, but it pointlessly and unhelpfully throws away the DHCP packet
and trashes the network interface configuration before handing over to
the downloaded executable.
Work around this imbecility by parsing and applying the few network
configuration settings that are persisted into the loaded image's
device path. This is limited to very basic information such as the IP
address, gateway address, and DNS server address, but it does at least
provide enough for a functional routing table.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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We want exclusive access to the network device, both for performance
reasons and because we perform operations such as EAPoL that affect
the entire link. We currently drive the network card via either a
native hardware driver or via the SNP or NII/UNDI interfaces, both of
which grant us this exclusive access.
Add an alternative driver that drives the network card non-exclusively
via the EFI_MANAGED_NETWORK_PROTOCOL interface. This can function as
a fallback for situations where neither SNP nor NII/UNDI interfaces
are functional, and also opens up the possibility of non-destructively
installing a temporary network device over which to download the
autoexec.ipxe script.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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When using a service binding protocol, CreateChild() will create a new
protocol instance (and optionally a new handle). The caller will then
typically open this new protocol instance with BY_DRIVER attributes,
since the service binding mechanism has no equivalent of the driver
binding protocol's Stop() method, and there is therefore no other way
for the caller to be informed if the protocol instance is about to
become invalid (e.g. because the service driver wants to remove the
child).
The caller cannot ask CreateChild() to install the new protocol
instance on the original handle (i.e. the service binding handle),
since the whole point of the service binding protocol is to allow for
the existence of multiple children, and UEFI does not permit multiple
instances of the same protocol to be installed on a handle.
Our current drivers all open the original handle (as passed to our
driver binding's Start() method) with BY_DRIVER attributes, and so the
same handle will be passed to our Stop() method. This changes when
our driver must use a separate handle, as described above.
Add an optional "child handle" field to struct efi_device (on the
assumption that we will not have any drivers that need to create
multiple children), and generalise efidev_find() to match on either
the original handle or the child handle.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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The EFI service binding abstraction is used to add and remove child
handles for multiple different protocols. Provide a common interface
for doing so.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Provide an implementation of the iPXE multiprocessor API for EFI,
based on using EFI_MP_SERVICES to start up a wrapper function on all
application processors.
Note that the processor numbers used by EFI_MP_SERVICES are opaque
integers that bear no relation to the underlying CPU identity
(e.g. the APIC ID), and so we must rely on our own (architecture-
specific) implementation to determine the relevant CPU identifiers.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Define an API for executing very limited functions on application
processors in a multiprocessor system, along with an x86-only
implementation.
The normal iPXE runtime environment is effectively non-existent on
application processors. There is no ability to make firmware calls
(e.g. to write to a console), and there may be no stack space
available.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add a "--label" option that can be used to specify a filesystem label,
to be matched against the FAT volume label.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add an "--extra" option that can be used to specify an extra
(non-boot) filename that must exist within the booted filesystem.
Note that only files within the FAT-formatted bootable partition will
be visible to this filter. Files within the operating system's root
disk (e.g. "/etc/redhat-release") are not generally accessible to the
firmware and so cannot be used as the existence check filter filename.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add a "--uuid" option which may be used to specify a boot device UUID,
to be matched against the GPT partition GUID.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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EFI provides no API for determining the partition GUID (if any) for a
specified device handle. The partition GUID appears to be exposed
only as part of the device path.
Add efi_path_guid() to extract the partition GUID (if any) from a
device path.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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The drive specification alone does not necessarily contain enough
information to perform a SAN boot (or local disk boot) under UEFI. If
the next-stage bootloader is installed in the EFI system partition
under a non-standard name (e.g. "\EFI\debian\grubx64.efi") then this
explicit boot filename must also be specified.
Generalise this concept to use a "SAN boot configuration parameters"
structure (currently containing only the optional explicit boot
filename), to allow for easy expansion to provide other parameters
such as the partition UUID or volume label.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Extend the EFI SAN boot code to allow for booting from a local disk,
as is already possible with the BIOS SAN boot code.
There is unfortunately no direct UEFI equivalent of the BIOS drive
number. The UEFI shell does provide numbered mappings fs0:, blk0:,
etc, but these numberings exist only while the UEFI shell is running
and are not necessarily stable between shell invocations or across
reboots.
A substantial amount of existing third-party documentation for iPXE
will suggest using "sanboot --drive 0x80" to boot from a local disk
(when no SAN drives are present), since this suggestion has been
present in the official documentation for the "sanboot" command for
almost thirteen years. We therefore aim to ensure that this
instruction will also work for UEFI, i.e. that in a situation where
there are local disks but no SAN disks, then the first local disk will
be treated as being drive 0x80.
We therefore assign local disks the virtual drive numbers 0x80, 0x81,
etc, matching the numbering typically used in a BIOS environment.
Where a SAN disk is already occupying one of these drive numbers, the
local disks' virtual drive numbers will be incremented as necessary.
This provides a rough approximation of the equivalent functionality
under BIOS, where existing local disks' drive numbers are remapped to
make way for SAN disks.
We do not make any attempt to sort the list of local disks: the order
used for allocating virtual drive numbers will be whatever order is
returned by LocateHandle(). This will typically match the creation
order of the EFI handles, which will typically match the hardware
enumeration order of the devices, which will typically match user
expectations as to which local disk is first, second, etc.
We explicitly do not attempt to match the numbering used by the UEFI
shell (which initially sorts in increasing order of device path, but
does not renumber when new devices are added or removed). We can
never guarantee matching this partly transient UEFI shell numbering,
so it is best not to set any expectation that it will be matched.
(Using local drive numbers starting at 0x80 helps to avoid setting up
this impossible expectation, since the UEFI shell uses local drive
numbers starting at zero.)
Since floppy disks are essentially non-existent in any plausible UEFI
system, overload "--drive 0" to mean "boot from any drive containing
the specified (or default) boot filename".
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Maintain the SAN device list in order of drive number, and provide
sandev_next() to locate the first SAN device at or above a given drive
number.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add uuid_aton() to parse a UUID value from a string (analogous to
inet_aton(), inet6_aton(), sock_aton(), etc), treating it as a
32-digit hex string with optional hyphen separators. The placement of
the separators is not checked: each byte within the hex string may be
separated by a hyphen, or not separated at all.
Add dedicated self-tests for UUID parsing and formatting (already
partially covered by the ":uuid" and ":guid" settings self-tests).
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add support for EAP-MSCHAPv2 (note that this is not the same as
PEAP-MSCHAPv2), controllable via the build configuration option
EAP_METHOD_MSCHAPV2 in config/general.h.
Our model for EAP does not encompass mutual authentication: we will
starting sending plaintext packets (e.g. DHCP requests) over the link
even before EAP completes, and our only use for an EAP success is to
mark the link as unblocked.
We therefore ignore the content of the EAP-MSCHAPv2 success request
(containing the MS-CHAPv2 authenticator response) and just send back
an EAP-MSCHAPv2 success response, so that the EAP authenticator will
complete the process and send through the real EAP success packet
(which will, in turn, cause us to unblock the link).
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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RFC 3748 states that implementations must support the MD5-Challenge
method. However, some network environments may wish to disable it as
a matter of policy.
Allow support for MD5-Challenge to be controllable via the build
configuration option EAP_METHOD_MD5 in config/general.h.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Inspection of the generated assembly shows that gcc will often emit
standalone implementations of frequently invoked functions such as
digest_update(), which contain no logic and exist only as syntactic
sugar.
Force inlining of these functions to reduce the overall binary size.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Add an implementation of the authentication portions of the MS-CHAPv2
algorithm as defined in RFC 2759, along with the single test vector
provided therein.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Certificates issued by Let's Encrypt have two options for their chain
of trust: the chain can either terminate in the self-signed ISRG Root
X1 root certificate, or in an intermediate ISRG Root X1 certificate
that is signed in turn by the self-signed DST Root CA X3 root
certificate. This is a historical artifact: when Let's Encrypt first
launched as a project, the chain ending in DST Root CA X3 was used
since existing clients would not have recognised the ISRG Root X1
certificate as a trusted root certificate.
The DST Root CA X3 certificate expired in September 2021, and so is no
longer trusted by clients (such as iPXE) that validate the expiry
times of all certificates in the certificate chain.
In order to maintain usability of certificates on older Android
devices, the default certificate chain provided by Let's Encrypt still
terminates in DST Root CA X3, even though that certificate has now
expired. On newer devices which include ISRG Root X1 as a trusted
root certificate, the intermediate version of ISRG Root X1 in the
certificate chain is ignored and validation is performed as though the
chain had terminated in the self-signed ISRG Root X1 root certificate.
On older Android devices which do not include ISRG Root X1 as a
trusted root certificate, the validation succeeds since Android
chooses to ignore expiry times for root certificates and so continues
to trust the DST Root CA X3 root certificate.
This backwards compatibility hack unfortunately breaks the cross-
signing mechanism used by iPXE, which assumes that the certificate
chain will always terminate in a non-expired root certificate.
Generalise the validator's cross-signed certificate download mechanism
to walk up the certificate chain in the event of a failure, attempting
to find a replacement cross-signed certificate chain starting from the
next level up. This allows the validator to step over the expired
(and hence invalidatable) DST Root CA X3 certificate, and instead
download the cross-signed version of the ISRG Root X1 certificate.
This generalisation also gives us the ability to handle servers that
provide a full certificate chain including their root certificate:
iPXE will step over the untrusted public root certificate and attempt
to find a cross-signed version of it instead.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Downloading a cross-signed certificate chain to partially replace
(rather than simply extend) an existing chain will require the ability
to discard all certificates after a specified link in the chain.
Extract the relevant logic from x509_free_chain() and expose it
separately as x509_truncate().
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Signed-off-by: Michael Brown <mcb30@ipxe.org>
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Some versions of gcc (observed with gcc 4.8.5 in CentOS 7) will report
spurious build_assert() failures for some assertions about structure
layouts. There is no clear pattern as to what causes these spurious
failures, and the build assertion does succeed in that no unresolvable
symbol reference is generated in the compiled code.
Adjust the assertions to work around these apparent compiler issues.
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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We build with -Werror by default so that any warning is treated as an
error and aborts the build. The build system allows NO_WERROR=1 to be
used to override this behaviour, in order to allow builds to succeed
when spurious warnings occur (e.g. when using a newer compiler that
includes checks for which the codebase is not yet prepared).
Some versions of gcc (observed with gcc 4.8.5 in CentOS 7) will report
spurious build_assert() failures: the compilation will fail due to an
allegedly unelided call to the build assertion's external function
declared with __attribute__((error)) even though the compiler does
manage to successfully elide the call (as verified by the fact that
there are no unresolvable symbol references in the compiler output).
Change build_assert() to declare __attribute__((warning)) instead of
__attribute__((error)) on its extern function. This will still abort
a normal build if the assertion fails, but may be overridden using
NO_WERROR=1 if necessary to work around a spurious assertion failure.
Note that if the build assertion has genuinely failed (i.e. if the
compiler has genuinely not been able to elide the call) then the
object will still contain an unresolvable symbol reference that will
cause the link to fail (which matches the behaviour of the old
linker_assert() mechanism).
Signed-off-by: Michael Brown <mcb30@ipxe.org>
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