Wiki source code of Volume Mapping (On-premise)

Last modified by Erik Bakker on 2024/03/05 13:03

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21.1	1	{{container}}{{container layoutStyle="columns"}}(((
58.1	2	When you need to read and write files from an on-premise disk, you need to know the path in which the data is stored and ensure that the docker container in your runtime(s) running has access to this path. There are several ways of dealing with this challenge. This microlearning will discuss the various alternatives and best approaches in these scenarios.
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21.1	4	Should you have any questions, please contact [[academy@emagiz.com>>mailto:academy@emagiz.com]].
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	6	== 1. Prerequisites ==
	7
	8	* Basic knowledge of the eMagiz platform
	9
	10	== 2. Key concepts ==
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58.1	12	This microlearning centers around learning how to correctly set up your volume mapping so you can exchange file-based data on-premise.
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66.1	14	By volume mapping, we mean creating a configuration through which the docker container can read and write data on a specific path on an on-premise machine. Note that the data can also be stored inside the docker container when (1) the other party writing or reading the data can access this path or (2) when the data is only relevant within the context of eMagiz.
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38.1	16	There are several options for volume mapping for your on-premise machine.
70.1	17	* Machine volume
38.1	18	* Bind mount
70.1	19	* Network volume
38.1	20	* Temporary file system
	21	* Named pipe
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38.1	23	== 3. Volume Mapping (On-premise) ==
1.1	24
58.1	25	When you need to read and write files from an on-premise disk, you need to know the path in which the data is stored and ensure that the docker container in your runtime(s) running has access to this path. There are several ways of dealing with this challenge. This microlearning will discuss the various alternatives and best approaches in these scenarios.
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38.1	27	There are several options for volume mapping for your on-premise machine.
54.1	28	* Machine volume
38.1	29	* Bind mount
54.1	30	* Network volume
38.1	31	* Temporary file system
	32	* Named pipe
1.1	33
66.1	34	Below, we will explain the differences between the various options available for your volume mapping. But before we do this, we explain how to set up this configuration within eMagiz. First, you must navigate to Deploy -> Architecture on the model level. This overview lets you access the Volume mapping per runtime deployed on-premise. And then, you can right-click on the runtime to access the context menu.
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	36	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--volume-option-context-menu.png]]
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66.1	38	Right after you click this option, you will see the following pop-up. In this pop-up, you can define the machine-level, runtime-level, and network-level volumes (more on this volume levels later). This pop-up page is the starting point for configuring your volume mapping. We will walk through each available option and explain how they work and should be configured.
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	40	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--volume-mapping-pop-up.png]]
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41.1	42	{{info}}Note that you should be in "Start editing" mode to make any changes to the configuration of your volume mapping.{{/info}}
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	44	=== 3.1 Volume ===
	45
58.1	46	The first Type available to you is volume. With this option, you create one or more folders on Docker relevant to that runtime to read and write persistent data. To configure this Type, you need to link the runtime volume to a machine volume (or network volume) you can create within the same pop-up. This means you can re-use a "Machine volume" or a "Network volume" over multiple runtimes (i.e., containers). We first need to define a machine (or network) volume to do so. Once we have done that, we can learn how to link the volume to the machine or network volume.
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55.1	48	==== 3.1.1 Define Machine Volume ====
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58.1	50	So, we first open the tab called "Machine volume." Then, by pressing the "New" button, we can define a new "Machine volume." In the following pop-up, we can specify the name of a machine volume and tell whether the volume already exists on your docker installation.
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	52	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--machine-volumes-configuration.png]]
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54.1	54	Once you have done so, we press "Save" and switch back to the "Runtime volumes" tab.
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58.1	56	{{info}}When stating that the machine volume already exists, you can re-use the same machine volume across multiple runtimes (i.e., containers). This is especially useful when archiving data. You can create a central volume in which the data is stored, and through the linkage of the volume to the machine volume, you can subsequently structure your archiving folder. The paths will then look as follows, "/archive/runtimename"{{/info}}
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55.1	58	==== 3.1.2 Define Network Volume ====
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58.1	60	So, we first open the tab called "Network volume." Then, by pressing the "New" button, we can define a new "Network volume." In the following pop-up, we can specify the name of a machine volume and configure the relevant information for a network volume. In most cases, a CIFS is used, and the only pertinent options that need to be filled in are the host, path, username, and password.
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	62	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--network-volumes-configuration.png]]
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	64	Once you have done so, we press "Save" and switch back to the "Runtime volumes" tab.
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59.1	66	{{warning}}When configuring a network volume, the following information is relevant to know:
58.1	67	* When you create a network volume to a folder that contains sub-folders, all sub-folders are shared automatically and can be accessed from the flow level
59.1	68	* When dealing with multiple hosts, you must create a specific entry per host, as this follows the guiding security principles of the underlying infrastructure.{{/warning}}
58.1	69
55.1	70	==== 3.1.3 Link Volume ====
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58.1	72	In the "Runtime volumes" tab, we push the "New" button to create a new "Runtime volume." In the following pop-up, we must select the Type we want to use. For this example, we use the Type called "Volume."
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58.1	74	{{info}} The relevant input fields will change based on your selection. {{/info}}
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	76	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--runtime-volumes-configuration-type-volume.png]]
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58.1	78	The first thing we need to select is the "Volume." Once we have chosen our "Volume," we must set the Target specific for this runtime. This target defines the second part of the path to which the runtime will gain access. For example, when you fill in "/target", we can combine this with the "Volume" name to arrive at the correct directory from which eMagiz needs to read data (or write data to). So, in our case, in which we link the volume to the machine volume we created earlier, this would be "/file-directory/target."
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58.1	80	The last setting we need to configure is to define the rights we will grant our runtime on the volume we create. The default setting is read/write rights for the runtime, which is usually sufficient. The result of following these steps will be the following.
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	82	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--runtime-volumes-configuration-type-volume-filled-in.png]]
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58.1	84	{{warning}}Note the following when considering using the Volume option:
	85	* In the case of using the Volume option in combination with a Machine volume, the external system with which you exchange data on-premise via a file-based method needs to be able to write or read the data from the volume (i.e., directory) you have configured. Should this be a problem, the Bind mount alternative discussed below should be considered.
	86	* The Volume option and Machine volume combination can also be used for eMagiz-only information that needs to be persistable, such as archiving.
	87	* In the case of using the Volume option in combination with a Network volume, the path to read and write from becomes what you define in the target field.
61.1	88	* In case of mapping a volume on a windows host machine to another one on a windows docker runtime, the following small adjustment is required when writing the source/target paths:
	89	** All “\” in the source/target path should be written as “/”. For example: C:\Users\xxxx\tmp should be written as C:/Users/xxxx/tmp.
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58.1	91	{{/warning}}
43.1	92
42.1	93	=== 3.2 Bind mount ===
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58.1	95	An alternative option to read and write persistent data is the "Bind mount" option. We generally advise using the "Volume" option because they perform better, and bind mounts depend on the host machine's directory structure and OS. However, only some external systems can adapt to this that easily. For example, the "Bind mount" option can interest your use case.
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46.1	97	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--runtime-volumes-configuration-type-bind-mount.png]]
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49.1	99	To configure a "Bind mount," you need to define a source and a target directory linked to each other. The source directory represents the directory on your local system (that might already be used currently to exchange files). The target directory defines a directory on your docker installation that the runtime can access.
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46.1	101	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--runtime-volumes-configuration-type-bind-mount-filled-in.png]]
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49.1	103	{{info}}Note that when you use this option, your directory reference in your flow should refer to the "target" directory configured here.{{/info}}
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61.1	105	{{warning}}
	106	When configuring a bind mount on a windows host machine to another one on a windows docker runtime, the following small adjustment is required when writing the source/target paths:
64.1	107	** All “\” in the source/target path should be written as “/”. For example: C:\Users\xxxx\tmp should be written as C:/Users/xxxx/tmp.
61.1	108	{{/warning}}
	109
42.1	110	=== 3.3 Temporary file system ===
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69.1	112	{{info}}This option is only relevant when running on Linux.{{/info}}
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49.1	114	The temporary file system option is for you if you do not want to work with persistent data but require non-persistent data. This way, you can increase the container's performance by avoiding writing into the container's writable layer.
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	116	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--runtime-volumes-configuration-type-temp-file-storage.png]]
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49.1	118	To configure this option, you need a target location. On top of that, you can define the maximum size of the temporary file system.
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	120	[[image:Main.Images.Microlearning.WebHome@novice-file-based-connectivity-volume-mapping-on-premise--runtime-volumes-configuration-type-temp-file-storage-filled-in.png]]
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61.1	122	{{warning}}
	123	We strongly advise you to define this number so that you can limit the potential impact this solution can have on the stability of your machine. {{/warning}}
47.1	124
42.1	125	=== 3.4 Named pipe ===
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69.1	127	{{info}}This option is only relevant when running on Windows.{{/info}}
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	129	A named pipe is a named, one-way or duplex pipe for communication between the pipe server and one or more pipe clients. All instances of a named pipe share the same pipe name, but each instance has its own buffers and handles, and provides a separate conduit for client/server communication. Any process can access named pipes, subject to security checks, making named pipes an easy form of communication between related or unrelated processes.
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61.1	131	*The named pipe option can be selected, but we yet have to see a valid use case within the context of eMagiz for using this option. Therefore, we won't discuss this option further in this microlearning.
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61.1	133	{{warning}}
	134	* When configuring a pipe path on a windows host machine to another one on a windows docker runtime, the following small adjustment is required when writing the source/target paths:
63.1	135	** All “\” in the source/target path should be written as “/”. For example: C:\Users\xxxx\tmp should be written as C:/Users/xxxx/tmp.{{/warning}}
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58.1	137	=== 3.5 Deployment consequences ===
	138
	139	{{warning}}
	140	* Note that the runtimes cannot be deployed correctly when the source directory does not exist. Consequently, no runtime on that machine will start up. One of the following two configurations displayed below are needed to find the source directory:
	141	** /mnt/host/{local-directory}
	142	** /run/desktop/mnt/host/{local-directory}
	143	* When the source directory can be found but the user has no access, the deployment will fail for the specific runtime in question with the volume mapping configured. All other runtimes (i.e., containers) will start up (pending other configuration issues).{{/warning}}
	144
57.1	145	== 4. Key takeaways ==
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49.1	147	* File-based communication on-premise changes in the new runtime architecture
48.1	148	* There are two ways to store persistent data
	149	** Volume
	150	** Bind mount
49.1	151	* The Volume option is considered the best alternative because they have better performance, and bind mounts are dependent on the directory structure and OS of the host machine
58.1	152	* Before deploying, ensure that the various sources in your configuration exist and that access is granted to avoid problems while deploying.
	153	* The Temporary file storage option is the way to go when dealing with non-persistent data.
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57.1	155	== 5. Suggested Additional Readings ==
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49.1	157	If you are interested in this topic and want more information, please read the help text provided by eMagiz.
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21.1	159	)))((({{toc/}}))){{/container}}{{/container}}

Wiki source code of Volume Mapping (On-premise)

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