JPH103357A - Video server - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video server having the read scheduling system of bit stream without biasing access load when reading the bit stream in order or at timing different from ordinary reproduction. SOLUTION: When the total sum of access load of I/O commands scheduled in a storage device corresponding to a read request exceeds quantity to be processed within unit time by storage devices 10 (101 -10n ), the I/O commands of which the priority is lower than the read request are taken out of the I/O commands scheduled in the storage devices 10 by a control processor 40 provided for the video server and in place of these commands, the I/O commands corresponding to the read request are scheduled into the desired storage devices 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video server, and more particularly, to a video server that stores a bit stream while striping the bit stream to a plurality of storage devices. The present invention relates to a video server having a function of changing a segment read scheduling among a plurality of storage devices.

More specifically, in a video-on-demand system, when segments are read in a different order and timing from normal reproduction, such as pause, slow, jump, and skip-read reproduction, access to some storage devices is performed. When the load becomes excessive, it can be used to improve the performance of the system by equalizing the access load among a plurality of storage devices.

[0003]

2. Description of the Related Art A conventional video server bit stream read scheduling method will be described. FIG. 5 is a block diagram of a conventional video server. For example, a case will be described where a bit stream is divided into segments of a fixed length, and the segments are stored in three storage devices while being striped.

The video server shown in FIG.
To 32, accumulation control interfaces 33 to 35, overall control processor 36, buffer memory 37, internal bus 38,
It comprises an external interface 39. Storage device 30
Reference numerals 32 are storage media such as magnetic disk devices.

The storage control interfaces 33 to 35 issue I / O commands for instructing the storage devices 30 to 32 to read / write in units of segments. Also, each of the storage devices 30 to 32 performs processing within a unit time.
It manages a queue of / O commands, queues the received segment read requests as I / O commands, and issues I / O commands in order from the head of the queue.

[0006] Upon receiving a segment read request, the general control processor 36 schedules access to the storage devices 30 to 32 to read a desired segment, and based on the schedule, accesses the storage control interface 33.
To 35 is instructed to read the segment.

The buffer memory 37 has storage devices 30 to 3
The segment read from 2 is temporarily stored. The internal bus 38 serves as a connection switching function between the storage devices 30 to 32 and the buffer memory 37 and a data transmission path.

[0008] The external interface 39 is an interface with the outside, and transfers the segments stored in the buffer memory 37 to the outside according to the video bit rate. FIG. 6 is a diagram for explaining a conventional bit stream reading schedule method in FIG.

When the general control processor 36 receives the read request of the bit stream, it checks the access load of the storage device storing the desired segment and schedules the access load so as not to exceed the allowable amount of the storage device. . In FIG. 6, for example, it is assumed that the read segment sizes are all equally fixed in any video file, and the storage devices 30 to 32 perform one read cycle.
In this case, the number of segments that can be read per (Cycle) is 3. Reading of one video bit stream is sequentially sewn to the next disk every cycle. In this case, by properly scheduling the read requests, the three storage devices can receive a total of nine requests. Here, if the first segment of the video bit stream for which the reading request has been made is stored in the storage device indicated by the disk 1, if only the third reading timing is empty, the general control processor 36 An I / O command corresponding to the request is scheduled to the disk 1 at the timing of cycle 1. After that,
By scheduling to disk 2 in sequential cycle 2 and disk 3 in cycle 3, segments can be read without interruption.

[0010]

Conventionally, striping of a bit stream is performed at the start of reading if the segment size of any content, the number of storage devices to be striped, and the order of storage devices to be striped are designed to be the same. By scheduling at a timing that makes the access load even, there is no problem that the access load is biased as it is. However,
Like pause, throw, jump and skip-read playback,
If the bit stream is read in a different order or timing from normal playback, access to the storage device will be different from what was originally planned, and the access load to some storage devices will be excessive. There is a possibility,
In that case, there is a problem that the reading process cannot be performed in time and the bit stream to be sent is interrupted.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and has an advantage that the access load is not biased even when the bit stream is read in a different order and timing from the normal reproduction as in the conventional case. It is an object to provide a video server having a method.

[0012]

FIG. 1 is a block diagram showing the principle of the present invention. The present invention includes a plurality of storage devices 10 for storing bit streams divided into segments while striping them, a storage control interface 20 for controlling data input / output of the storage devices 10, and a request for reading a segment received from outside. A video processor having a control processor that determines the priority and controls the scheduling of I / O commands to be issued to the storage device. the sum of the access load of the I / O command to be scheduled in the storage unit 10 ₁ corresponding to the request, if exceeding the amount of the storage device 10 ₁ can be processed within a unit time, is scheduled to the storage device 10 ₁ I / O with a lower priority than the read request among the I / O commands Remove the command,
Having a first scheduling unit 41 for scheduling an I / O command corresponding to the place the read request to the desired storage device 10 _1.

Further, in the video server of the present invention, the control processor, upon receiving the read request, sets the total access load of the I / O command scheduled to the storage device corresponding to the read request to the storage device. If the amount exceeds the amount that can be processed in a unit time, and if there is no I / O command with a lower priority than the read request among the I / O commands scheduled to the storage device, the read is performed instead of the read request. There is provided a second scheduling means for scheduling an I / O command in a storage device storing the segment closest to the segment corresponding to the request.

The control processor of the video server according to the present invention, upon receiving the read request, calculates the total access load of the I / O command scheduled to the storage device corresponding to the request by the storage device. If the amount exceeds the amount that can be processed within the time, an I / O command having a lower priority than the read request is taken out of the I / O commands scheduled to the storage device, and the I / O command corresponding to the taken out I / O command is taken out. A third scheduling unit is provided for rescheduling the I / O command in a storage device storing the segment for the segment closest to the segment.

[0015] In the video server of the present invention, the control processor may include, in the read request, a request to read continuous data during normal reproduction, a request to read new program data,
A priority setting means for setting a higher priority in the order of the reproduction mode change request is included. In addition, the above-described request for changing the reproduction mode is any one of the following reproduction modes: jump, skip reading, reverse skip reading, fast forward, reverse fast forward, slow, reverse slow, pause, normal playback, reverse playback, or Includes all.

In the video server according to the present invention, the control processor, upon receiving the read request, stores the sum of the access load of the I / O command scheduled in the storage device corresponding to the request in the storage device. Is less than or equal to n% of the amount that can be processed in a unit time (where 0 ≦ n ≦ 100), the I / O command scheduled to the storage device has a lower priority than the read request. There is provided fourth scheduling means for extracting the I / O command and, instead, scheduling the I / O command corresponding to the read request to a desired storage device. However, the value of n can be set individually for each priority of the read request.

Further, the control processor of the video server according to the present invention, upon receiving the read request, sets the total access load of the I / O command scheduled to the storage device corresponding to the request as a unit of the storage device. N% or more of the amount that can be processed in time (however, 0 ≦ n
≦ 100), and if there is no I / O command with a lower priority than the read request among the I / O commands scheduled to the storage device, The storage device storing the segment closest to the segment corresponding to the read request has a fifth scheduling means for scheduling an I / O command.

Further, the control processor in the video server according to the present invention, upon receiving the read request, calculates the total access load of the I / O command scheduled to the storage device corresponding to the request by the storage device. N% or more of the amount that can be processed in time (however, 0%
≦ n ≦ 100), an I / O command having a lower priority than the read request is taken out of the I / O commands scheduled to the storage device, and the I / O command corresponding to the taken out I / O command is taken out. And a sixth scheduling unit for rescheduling the I / O command in the storage device storing the segment closest to the segment to be executed.

The value of n is set individually according to the priority of the read request. As described above, according to the present invention, by determining the priority of a read request received from the outside and manipulating the scheduling of a read instruction to the storage device, a certain storage device receives a high-priority read request. Sometimes, when a high-priority read process cannot be processed within a unit time due to a bias in access load, the priority of a read request is determined, and the request is transferred from a low-priority request to a storage device having a sufficient access load. As a result, an I / O command corresponding to a high-priority read request can be scheduled to a desired storage device instead.

Therefore, even if the bit stream is read in a different order or timing from the normal reproduction, such as pause, slow, jump, or skip-read reproduction, and the read scheduling of the storage device is disturbed, the reading of the storage device is not affected. The load can be equalized, and the bit stream can be provided without interruption by increasing the priority of the read request for normal reproduction, which is the object of the present invention.

[0021]

FIG. 2 shows the configuration of a video server according to the present invention. The video server shown in FIG.
0, 101, 102, accumulation control interface 203,
204, 205, queuing memories 206, 207,
208, overall control processor 306, buffer memory 3
07, an internal bus 308, and an external interface 309.

The storage devices 100, 101, and 102 are composed of, for example, magnetic disks or the like, and store bit streams divided into segments while sequentially striping them. Storage control interfaces 203, 204, 20
5 are stored in the storage devices 100, 101, and 102, respectively.
I / that instructs read / write in segments
O command is queued in memory 206, 207, 20
Issued via 8

Queuing memories 206, 207, 20
8 is a storage control interface 203, 204, 205
Queues the I / O command passed from. Upon receiving the segment read request, the general control processor 306 instructs the corresponding storage control interface to read the segment in order to access the storage device storing the desired segment, and reduces the access load of the storage device. If it is determined that the read request exceeds the allowable amount, a scheduling operation is performed based on the priority of the read request.

The buffer memory 307 stores the storage device 10
The segments read from 0, 101 and 102 are temporarily stored. The internal bus 308 includes storage devices 100, 101,
It serves as a connection switching function between the memory 102 and the buffer memory 307 and a data transmission path.

The external interface 309 transfers the segments stored in the buffer memory 307 to the outside according to the video bit rate. The operation of determining the priority of a segment read request received from the outside and operating the scheduling of an I / O command to be issued to the storage device will be described below.

In the following description, the storage device 100, the storage control interface 203, and the queuing memory 20
6, the storage device 101, the storage control interface 204, and the queuing memory 207 correspond, and the storage device 102, the storage control interface 205, and the queuing memory 208 correspond.

FIG. 3 is a flowchart of the scheduling operation of the present invention. Step 101) The overall control processor 306 receives a read request from the external interface 309. Step 102) For example, when the storage device that has stored the segment corresponding to the read request is the storage device 100, the general control processor 306 sets the I / O scheduled for the storage device 100 corresponding to the read request.
Find the sum of the command access load.

Step 103) The sum of the access load due to the reception of the read request is stored in the storage device 1.
It is determined whether or not 00 exceeds the amount that can be processed in a unit time. If the amount does not exceed the amount that can be processed in a unit time, the process proceeds to step 104. Otherwise, the process proceeds to step 204.

Step 104) The I / O command for reading the segment corresponding to the read request is scheduled at the end of the I / O command queue of the queuing memory 206 corresponding to the predetermined storage device 100. Step 204) The general control processor 306 determines whether or not there is an I / O command of lower priority than the acquired read request among the I / O commands of the queuing memory 206 scheduled to the storage device 100. If not, the process proceeds to step 205. If there is, the process proceeds to step 304.

Step 205) Overall control processor 3
In step 06, an I / O command is scheduled in the storage device storing the segment, targeting the segment closest to the segment corresponding to the read request instead of the read request. Step 304) If the storage device 100 exceeds the amount that can be processed in a unit time, the priority of the I / O command scheduled in the queuing memory 206 corresponding to the storage device 100 is higher than that of the read request. Fetch the low I / O command. Instead, the I / O of reading the segment corresponding to the read request
The O command is scheduled at the end of the I / O command queue of the queuing memory 206 corresponding to the predetermined storage device 100.

Step 305) In order from the segment closest to the segment corresponding to the extracted low-priority I / O command, a storage device storing the segment is searched for a device whose total access load does not exceed the allowable amount. The I / O command for reading the segment is rescheduled to the end of the I / O command queue in the queuing memory of the corresponding storage device.

In step 204, I
The sum of the access load of the / O command is n% or more of the amount that the storage device can process in a unit time (where 0 ≦ n ≦ 10
0) can be used as a criterion. As described above, according to the present invention, the bit stream divided into segments is stored in the storage device while striping, and the priority of the segment read request received from the outside is determined, and the I / O command issued to the storage device is determined. Work with scheduling. In this scheduling, if a read request for a storage device for which an I / O command is newly scheduled cannot be processed within a unit time, an I / O command scheduled in a queuing memory corresponding to the storage device is newly processed. , An I / O command having a lower priority than the read request is taken out and rescheduled in a queuing memory corresponding to another storage device. Instead, an I / O command corresponding to the read request is desired. Can be scheduled to the storage device.

[0033]

Embodiments of the present invention will be described below with reference to the drawings. The general control processor 306 sets the following three priorities to the read request in advance.

(1) Request to read continuous data during normal playback: (2) Request to read new program data: (3) Request to change playback mode: Set.

The playback modes for which the present invention sets the priority include jump, skip reading, reverse skip reading, fast forward, reverse fast forward, slow, reverse flow, pause, normal playback, and reverse playback. Any or all of Further, as a criterion for determining whether or not to perform scheduling to the I / O command queue of the queuing memory corresponding to the storage device, the ratio to the amount that the storage device can process in a unit time is set as follows.

In the case of a request to change the reproduction mode, n = 8
0%, in the case of a request to read new program data, n =
90%, and n = 100% in the case of a continuous data read request during normal reproduction. Here, n = 100% corresponds to the above-described first scheduling operation.

FIG. 6 is a flowchart showing the operation of the general control processor according to one embodiment of the present invention. Step 401) The general control processor 306 receives a read request for the segment number i.

Step 402) It is determined whether or not the received request is a change in the reproduction mode. If so, the process proceeds to Step 403; otherwise, the process proceeds to Step 4
Move to 05. Step 403) It is checked whether the total load of access by the I / O command already scheduled to the storage device storing the segment number i is 80% or more of the amount that the storage device can process in a unit time. , 80
If it is not less than%, the process proceeds to step 404; otherwise, the process proceeds to step 414.

Step 404) The segment number is incremented by one, and the routine goes to Step 402. Step 405) Determine whether the received request is a new program data request, and if so, step 406
Otherwise, to step 410.

Step 406) I / O scheduled to the storage device storing the segment number i
It is determined whether or not the sum of the access load by the O command is 90% or more of the amount that the storage device can process in a unit time. If it is 90% or more, the process proceeds to step 407; Moves to step 414.

Step 407) It is determined whether any of the I / O commands already scheduled in the queuing memory corresponding to the storage device storing the segment number i is caused by a request to change the reproduction mode. Goes to step 409, otherwise goes to step 408.

Step 408) Set the segment number i to 1
Increment and proceed to step 402. Step 409) I / O by request to change playback mode
Command, and substitutes the desired I / O command with the I / O of the queuing memory corresponding to the storage device.
The scheduling is performed at the end of the O command sequence, and the process ends.

Step 410) If the received request is not a new program data request in step 405, it is already scheduled to add an I / O command to the queuing memory corresponding to the storage device storing the segment number i. It is determined whether the sum of the access load together with the I / O command exceeds 100% of the amount that the storage device can process in a unit time. If it exceeds, the process proceeds to step 411. If not,
Move to step 414.

Step 411) It is checked whether there is a low priority I / O command among the I / O commands already scheduled in the queuing memory corresponding to the storage device storing the segment number i. The process proceeds to step 413, and if not, proceeds to step 412.

Step 412) Set the segment number i to 1
Increment and proceed to step 402. Step 413) Extract the I / O command according to the low priority request from the queuing memory corresponding to the storage device, and substitute the desired I / O command for the I / O command of the queuing memory corresponding to the storage device. Schedule at end of column. The extracted lower priority request is changed to the request of the nearest segment, and a similar process from step 402
Scheduling is performed to a queuing memory corresponding to one of the storage devices.

Step 414) Step 403 above
80% of the amount that the storage device can process in a unit time
If it is less than or equal to or less than 90% of the amount that the storage device can process in a unit time in step 406, the corresponding I / O command is scheduled to the queuing memory corresponding to the storage device.

When a large load bias occurs due to sudden access concentration due to the above-described operation, even if the first scheduling operation alone cannot completely cope with the situation, as in steps 403 and 406. By distributing low-priority requests to other storage devices as soon as possible, the bias of the access load among a plurality of storage devices can be constantly equalized. Can also reduce the bias of the access load.

In the above embodiment, the control for scheduling the storage devices is performed by the storage control interface queuing the data in the queuing memory corresponding to each storage device. However, it is also possible to provide a queuing memory in the general control processor and perform scheduling by queuing in the queuing memory. It can be easily inferred that the operation of the general control processor in this case is the same as the operation of the storage control interface described above.

The present invention is not limited to the above embodiment, but can be variously modified and applied within the scope of the claims.

[0050]

As described above, according to the video server of the present invention, when a certain storage device receives a high-priority reading request, a high-priority reading process is performed within a unit time due to an uneven access load. If the processing cannot be performed, the priority of the read request is determined, and the priority is shifted from a low priority to a storage device having a sufficient access load, thereby
Instead, I / O corresponding to a high-priority read request
The O command can be scheduled to the storage device, so that the reading of the storage device is instructed to instruct the reading of segments in a different order and timing from normal reproduction, such as pause, slow, jump, and skip-read reproduction. Is disturbed and even if an excessive access load is applied to some storage devices, the read load of the storage devices can be equalized, and the priority of the read request for normal reproduction, which is the object of the present invention, can be reduced. By increasing the value, the bit stream can be provided without interruption.

[Brief description of the drawings]

FIG. 1 is a principle configuration diagram of the present invention.

FIG. 2 is a configuration diagram of a video server of the present invention.

FIG. 3 is a flowchart of a scheduling operation of the present invention.

FIG. 4 is a flowchart showing the operation of the general control processor according to one embodiment of the present invention.

FIG. 5 is a configuration diagram of a conventional video server.

FIG. 6 is a diagram for explaining a conventional bit stream read scheduling method.

[Explanation of symbols]

10, 100, 101, 102 Storage device 20, 203, 204, 205 Storage control interface 40 Control processor 41 First scheduling means 206, 207, 208 Queuing memory 306 Overall control processor 307 Buffer memory 308 Internal bus 309 External interface

──────────────────────────────────────────────────続 き Continuation of the front page (51) Int.Cl. ⁶ Identification number Agency reference number FI Technical display location H04N 7/16 H04N 5/93 E (72) Inventor Hideki Sakamoto 3-19 Nishishinjuku, Shinjuku-ku, Tokyo No. 2 Nippon Telegraph and Telephone Corporation

Claims (9)

[Claims] 1. A plurality of storage devices for storing bit streams divided into segments while striping them, a storage control interface for controlling data input / output of the storage devices, and a priority of a segment read request received from outside. And I / O issued to the storage device
A video server having a control processor that operates command scheduling, wherein the control processor receives an read request, and is configured to schedule an I / O scheduled in a storage device corresponding to the read request.
If the sum of the access loads of the commands exceeds the amount that the storage device can process in a unit time, the I / O command having a lower priority than the read request among the I / O commands scheduled to the storage device. Take out the command,
Instead, a video server having first scheduling means for scheduling an I / O command corresponding to the read request to a desired storage device. 2. The control processor according to claim 1, wherein, upon receiving the read request, an I / O scheduled to a storage device corresponding to the read request.
If the sum of the access loads of the commands exceeds the amount that the storage device can process in a unit time, and among the I / O commands scheduled to the storage device, I / O commands with lower priority than the read request are included. In the absence of the / O command, instead of the read request, for the segment closest to the segment corresponding to the read request,
2. The video server according to claim 1, further comprising a second scheduling means for scheduling an I / O command in a storage device storing the segment. 3. The control processor according to claim 1, wherein the control processor receives the read request and processes the sum of the access loads of the I / O commands scheduled to the storage device corresponding to the request within the unit time. If the number exceeds the limit, an I / O command having a lower priority than the read request is extracted from the I / O commands scheduled to the storage device, and the segment closest to the segment corresponding to the extracted I / O command is extracted. 2. The video server according to claim 1, further comprising third scheduling means for rescheduling said I / O command in a storage device storing said segments. 4. The control processor according to claim 1, wherein said read request has priority setting means for setting a higher priority in the order of a continuous data read request during normal reproduction, a new program data read request, and a reproduction mode change request. 4. The video server according to claim 1, comprising: 5. The reproduction apparatus according to claim 1, wherein the priority setting unit sets a reproduction mode in the reproduction mode change request.
5. A method comprising one or all of jump, skip reading, reverse skip reading, fast forward, reverse fast forward, slow, reverse slow, pause, normal playback, and reverse playback.
Video server as described. 6. The control processor, upon receiving the read request, stores the sum of access loads of I / O commands scheduled in the storage device corresponding to the request within a unit time. N% or more of the processable amount (however, 0 ≦ n ≦ 100)
In this case, an I / O command whose priority is lower than that of the read request is extracted from the I / O commands scheduled to the storage device, and the I / O command corresponding to the read request is extracted instead. 2. The video server according to claim 1, further comprising a fourth scheduling unit for scheduling a desired storage device. 7. The control processor, upon receiving the read request, processes the sum of access loads of I / O commands scheduled in the storage device corresponding to the request within a unit time. When the amount becomes n% or more (where 0 ≦ n ≦ 100), and among the I / O commands scheduled to the storage device, the I / O command having a lower priority than the read request is included. In the case where there is no, the fifth scheduling means for scheduling the I / O command in the storage device storing the segment for the segment closest to the segment corresponding to the read request instead of the read request. The video server according to claim 1, comprising: 8. The control processor, upon receiving the read request, processes the sum of access loads of I / O commands scheduled to the storage device corresponding to the request in a unit time. When n% or more of the possible amount (where 0 ≦ n ≦ 100), an I / O command having a lower priority than the read request is extracted from I / O commands scheduled to the storage device. , For the segment closest to the segment corresponding to the extracted I / O command, the I / O
2. The video server according to claim 1, further comprising sixth scheduling means for rescheduling the command. 9. The video server according to claim 6, wherein the value of n is individually set according to the priority of the read request.