SPUFS(7) Linux Programmer's Manual SPUFS(7)
NAME
spufs - SPU filesystem
DESCRIPTION
The SPU filesystem is used on PowerPC machines that implement the Cell Broadband Engine Ar‐
chitecture in order to access Synergistic Processor Units (SPUs).
The filesystem provides a name space similar to POSIX shared memory or message queues. Users
that have write permissions on the filesystem can use spu_create(2) to establish SPU contexts
under the spufs root directory.
Every SPU context is represented by a directory containing a predefined set of files. These
files can be used for manipulating the state of the logical SPU. Users can change permis‐
sions on the files, but can't add or remove files.
Mount options
uid=<uid>
Set the user owning the mount point; the default is 0 (root).
gid=<gid>
Set the group owning the mount point; the default is 0 (root).
mode=<mode>
Set the mode of the top-level directory in spufs, as an octal mode string. The de‐
fault is 0775.
Files
The files in spufs mostly follow the standard behavior for regular system calls like read(2)
or write(2), but often support only a subset of the operations supported on regular filesys‐
tems. This list details the supported operations and the deviations from the standard behav‐
ior described in the respective man pages.
All files that support the read(2) operation also support readv(2) and all files that support
the write(2) operation also support writev(2). All files support the access(2) and stat(2)
family of operations, but for the latter call, the only fields of the returned stat structure
that contain reliable information are st_mode, st_nlink, st_uid, and st_gid.
All files support the chmod(2)/fchmod(2) and chown(2)/fchown(2) operations, but will not be
able to grant permissions that contradict the possible operations (e.g., read access on the
wbox file).
The current set of files is:
/capabilities
Contains a comma-delimited string representing the capabilities of this SPU context.
Possible capabilities are:
sched This context may be scheduled.
step This context can be run in single-step mode, for debugging.
New capabilities flags may be added in the future.
/mem the contents of the local storage memory of the SPU. This can be accessed like a reg‐
ular shared memory file and contains both code and data in the address space of the
SPU. The possible operations on an open mem file are:
read(2), pread(2), write(2), pwrite(2), lseek(2)
These operate as usual, with the exception that lseek(2), write(2), and
pwrite(2) are not supported beyond the end of the file. The file size is the
size of the local storage of the SPU, which is normally 256 kilobytes.
mmap(2)
Mapping mem into the process address space provides access to the SPU local
storage within the process address space. Only MAP_SHARED mappings are al‐
lowed.
/regs Contains the saved general-purpose registers of the SPU context. This file contains
the 128-bit values of each register, from register 0 to register 127, in order. This
allows the general-purpose registers to be inspected for debugging.
Reading to or writing from this file requires that the context is scheduled out, so
use of this file is not recommended in normal program operation.
The regs file is not present on contexts that have been created with the SPU_CRE‐�‐
ATE_NOSCHED flag.
/mbox The first SPU-to-CPU communication mailbox. This file is read-only and can be read in
units of 4 bytes. The file can be used only in nonblocking mode - even poll(2) cannot
be used to block on this file. The only possible operation on an open mbox file is:
read(2)
If count is smaller than four, read(2) returns -1 and sets errno to EINVAL. If
there is no data available in the mailbox (i.e., the SPU has not sent a mailbox
message), the return value is set to -1 and errno is set to EAGAIN. When data
has been read successfully, four bytes are placed in the data buffer and the
value four is returned.
/ibox The second SPU-to-CPU communication mailbox. This file is similar to the first mail‐
box file, but can be read in blocking I/O mode, thus calling read(2) on an open ibox
file will block until the SPU has written data to its interrupt mailbox channel (un‐
less the file has been opened with O_NONBLOCK, see below). Also, poll(2) and similar
system calls can be used to monitor for the presence of mailbox data.
The possible operations on an open ibox file are:
read(2)
If count is smaller than four, read(2) returns -1 and sets errno to EINVAL. If
there is no data available in the mailbox and the file descriptor has been
opened with O_NONBLOCK, the return value is set to -1 and errno is set to EA‐�‐
GAIN.
If there is no data available in the mailbox and the file descriptor has been
opened without O_NONBLOCK, the call will block until the SPU writes to its in‐
terrupt mailbox channel. When data has been read successfully, four bytes are
placed in the data buffer and the value four is returned.
poll(2)
Poll on the ibox file returns (POLLIN | POLLRDNORM) whenever data is available
for reading.
/wbox The CPU-to-SPU communication mailbox. It is write-only and can be written in units of
four bytes. If the mailbox is full, write(2) will block, and poll(2) can be used to
block until the mailbox is available for writing again. The possible operations on an
open wbox file are:
write(2)
If count is smaller than four, write(2) returns -1 and sets errno to EINVAL.
If there is no space available in the mailbox and the file descriptor has been
opened with O_NONBLOCK, the return value is set to -1 and errno is set to EA‐�‐
GAIN.
If there is no space available in the mailbox and the file descriptor has been
opened without O_NONBLOCK, the call will block until the SPU reads from its PPE
(PowerPC Processing Element) mailbox channel. When data has been written suc‐
cessfully, the system call returns four as its function result.
poll(2)
A poll on the wbox file returns (POLLOUT | POLLWRNORM) whenever space is avail‐
able for writing.
/mbox_stat, /ibox_stat, /wbox_stat
These are read-only files that contain the length of the current queue of each mail‐
box—that is, how many words can be read from mbox or ibox or how many words can be
written to wbox without blocking. The files can be read only in four-byte units and
return a big-endian binary integer number. The only possible operation on an open
*box_stat file is:
read(2)
If count is smaller than four, read(2) returns -1 and sets errno to EINVAL.
Otherwise, a four-byte value is placed in the data buffer. This value is the
number of elements that can be read from (for mbox_stat and ibox_stat) or writ‐
ten to (for wbox_stat) the respective mailbox without blocking or returning an
EAGAIN error.
/npc, /decr, /decr_status, /spu_tag_mask, /event_mask, /event_status, /srr0, /lslr
Internal registers of the SPU. These files contain an ASCII string representing the
hex value of the specified register. Reads and writes on these files (except for npc,
see below) require that the SPU context be scheduled out, so frequent access to these
files is not recommended for normal program operation.
The contents of these files are:
npc Next Program Counter - valid only when the SPU is in a stopped state.
decr SPU Decrementer
decr_status Decrementer Status
spu_tag_mask MFC tag mask for SPU DMA
event_mask Event mask for SPU interrupts
event_status Number of SPU events pending (read-only)
srr0 Interrupt Return address register
lslr Local Store Limit Register
The possible operations on these files are:
read(2)
Reads the current register value. If the register value is larger than the
buffer passed to the read(2) system call, subsequent reads will continue read‐
ing from the same buffer, until the end of the buffer is reached.
When a complete string has been read, all subsequent read operations will re‐
turn zero bytes and a new file descriptor needs to be opened to read a new
value.
write(2)
A write(2) operation on the file sets the register to the value given in the
string. The string is parsed from the beginning until the first nonnumeric
character or the end of the buffer. Subsequent writes to the same file de‐
scriptor overwrite the previous setting.
Except for the npc file, these files are not present on contexts that have been
created with the SPU_CREATE_NOSCHED flag.
/fpcr This file provides access to the Floating Point Status and Control Register (fcpr) as
a binary, four-byte file. The operations on the fpcr file are:
read(2)
If count is smaller than four, read(2) returns -1 and sets errno to EINVAL.
Otherwise, a four-byte value is placed in the data buffer; this is the current
value of the fpcr register.
write(2)
If count is smaller than four, write(2) returns -1 and sets errno to EINVAL.
Otherwise, a four-byte value is copied from the data buffer, updating the value
of the fpcr register.
/signal1, /signal2
The files provide access to the two signal notification channels of an SPU. These are
read-write files that operate on four-byte words. Writing to one of these files trig‐
gers an interrupt on the SPU. The value written to the signal files can be read from
the SPU through a channel read or from host user space through the file. After the
value has been read by the SPU, it is reset to zero. The possible operations on an
open signal1 or signal2 file are:
read(2)
If count is smaller than four, read(2) returns -1 and sets errno to EINVAL.
Otherwise, a four-byte value is placed in the data buffer; this is the current
value of the specified signal notification register.
write(2)
If count is smaller than four, write(2) returns -1 and sets errno to EINVAL.
Otherwise, a four-byte value is copied from the data buffer, updating the value
of the specified signal notification register. The signal notification regis‐
ter will either be replaced with the input data or will be updated to the bit‐
wise OR operation of the old value and the input data, depending on the con‐
tents of the signal1_type or signal2_type files respectively.
/signal1_type, /signal2_type
These two files change the behavior of the signal1 and signal2 notification files.
They contain a numeric ASCII string which is read as either "1" or "0". In mode 0
(overwrite), the hardware replaces the contents of the signal channel with the data
that is written to it. In mode 1 (logical OR), the hardware accumulates the bits that
are subsequently written to it. The possible operations on an open signal1_type or
signal2_type file are:
read(2)
When the count supplied to the read(2) call is shorter than the required length
for the digit (plus a newline character), subsequent reads from the same file
descriptor will complete the string. When a complete string has been read, all
subsequent read operations will return zero bytes and a new file descriptor
needs to be opened to read the value again.
write(2)
A write(2) operation on the file sets the register to the value given in the
string. The string is parsed from the beginning until the first nonnumeric
character or the end of the buffer. Subsequent writes to the same file de‐
scriptor overwrite the previous setting.
/mbox_info, /ibox_info, /wbox_info, /dma_into, /proxydma_info
Read-only files that contain the saved state of the SPU mailboxes and DMA queues.
This allows the SPU status to be inspected, mainly for debugging. The mbox_info and
ibox_info files each contain the four-byte mailbox message that has been written by
the SPU. If no message has been written to these mailboxes, then contents of these
files is undefined. The mbox_stat, ibox_stat, and wbox_stat files contain the avail‐
able message count.
The wbox_info file contains an array of four-byte mailbox messages, which have been
sent to the SPU. With current CBEA machines, the array is four items in length, so up
to 4 * 4 = 16 bytes can be read from this file. If any mailbox queue entry is empty,
then the bytes read at the corresponding location are undefined.
The dma_info file contains the contents of the SPU MFC DMA queue, represented as the
following structure:
struct spu_dma_info {
uint64_t dma_info_type;
uint64_t dma_info_mask;
uint64_t dma_info_status;
uint64_t dma_info_stall_and_notify;
uint64_t dma_info_atomic_command_status;
struct mfc_cq_sr dma_info_command_data[16];
};
The last member of this data structure is the actual DMA queue, containing 16 entries.
The mfc_cq_sr structure is defined as:
struct mfc_cq_sr {
uint64_t mfc_cq_data0_RW;
uint64_t mfc_cq_data1_RW;
uint64_t mfc_cq_data2_RW;
uint64_t mfc_cq_data3_RW;
};
The proxydma_info file contains similar information, but describes the proxy DMA queue
(i.e., DMAs initiated by entities outside the SPU) instead. The file is in the fol‐
lowing format:
struct spu_proxydma_info {
uint64_t proxydma_info_type;
uint64_t proxydma_info_mask;
uint64_t proxydma_info_status;
struct mfc_cq_sr proxydma_info_command_data[8];
};
Accessing these files requires that the SPU context is scheduled out - frequent use
can be inefficient. These files should not be used for normal program operation.
These files are not present on contexts that have been created with the SPU_CRE‐�‐
ATE_NOSCHED flag.
/cntl This file provides access to the SPU Run Control and SPU status registers, as an ASCII
string. The following operations are supported:
read(2)
Reads from the cntl file will return an ASCII string with the hex value of the
SPU Status register.
write(2)
Writes to the cntl file will set the context's SPU Run Control register.
/mfc Provides access to the Memory Flow Controller of the SPU. Reading from the file re‐
turns the contents of the SPU's MFC Tag Status register, and writing to the file ini‐
tiates a DMA from the MFC. The following operations are supported:
write(2)
Writes to this file need to be in the format of a MFC DMA command, defined as
follows:
struct mfc_dma_command {
int32_t pad; /* reserved */
uint32_t lsa; /* local storage address */
uint64_t ea; /* effective address */
uint16_t size; /* transfer size */
uint16_t tag; /* command tag */
uint16_t class; /* class ID */
uint16_t cmd; /* command opcode */
};
Writes are required to be exactly sizeof(struct mfc_dma_command) bytes in size.
The command will be sent to the SPU's MFC proxy queue, and the tag stored in
the kernel (see below).
read(2)
Reads the contents of the tag status register. If the file is opened in block‐
ing mode (i.e., without O_NONBLOCK), then the read will block until a DMA tag
(as performed by a previous write) is complete. In nonblocking mode, the MFC
tag status register will be returned without waiting.
poll(2)
Calling poll(2) on the mfc file will block until a new DMA can be started (by
checking for POLLOUT) or until a previously started DMA (by checking for
POLLIN) has been completed.
/mss Provides access to the MFC MultiSource Synchronization (MSS) facility. By
mmap(2)-ing this file, processes can access the MSS area of the SPU.
The following operations are supported:
mmap(2)
Mapping mss into the process address space gives access to the SPU MSS area
within the process address space. Only MAP_SHARED mappings are allowed.
/psmap Provides access to the whole problem-state mapping of the SPU. Applications can use
this area to interface to the SPU, rather than writing to individual register files in
spufs.
The following operations are supported:
mmap(2)
Mapping psmap gives a process a direct map of the SPU problem state area. Only
MAP_SHARED mappings are supported.
/phys-id
Read-only file containing the physical SPU number that the SPU context is running on.
When the context is not running, this file contains the string "-1".
The physical SPU number is given by an ASCII hex string.
/object-id
Allows applications to store (or retrieve) a single 64-bit ID into the context. This
ID is later used by profiling tools to uniquely identify the context.
write(2)
By writing an ASCII hex value into this file, applications can set the object
ID of the SPU context. Any previous value of the object ID is overwritten.
read(2)
Reading this file gives an ASCII hex string representing the object ID for this
SPU context.
EXAMPLES
/etc/fstab entry
none /spu spufs gid=spu 0 0
SEE ALSO
close(2), spu_create(2), spu_run(2), capabilities(7)
The Cell Broadband Engine Architecture (CBEA) specification
COLOPHON
This page is part of release 5.10 of the Linux man-pages project. A description of the
project, information about reporting bugs, and the latest version of this page, can be found
at https://www.kernel.org/doc/man-pages/.
Linux 2020-12-21 SPUFS(7)
