Struct podman_rest_client::models::TopologyRequirement

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pub struct TopologyRequirement {
    pub preferred: Option<Vec<Topology>>,
    pub requisite: Option<Vec<Topology>>,
}
Expand description

TopologyRequirement : TopologyRequirement expresses the user’s requirements for a volume’s accessible topology.

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§preferred: Option<Vec<Topology>>

Preferred is a list of Topologies that the volume should attempt to be provisioned in. Taken from the CSI spec: Specifies the list of topologies the CO would prefer the volume to be provisioned in. This field is OPTIONAL. If TopologyRequirement is specified either requisite or preferred or both MUST be specified. An SP MUST attempt to make the provisioned volume available using the preferred topologies in order from first to last. If requisite is specified, all topologies in preferred list MUST also be present in the list of requisite topologies. If the SP is unable to make the provisioned volume available from any of the preferred topologies, the SP MAY choose a topology from the list of requisite topologies. If the list of requisite topologies is not specified, then the SP MAY choose from the list of all possible topologies. If the list of requisite topologies is specified and the SP is unable to make the provisioned volume available from any of the requisite topologies it MUST fail the CreateVolume call. Example 1: Given a volume should be accessible from a single zone, and requisite = {"region": "R1", "zone": "Z2"}, {"region": "R1", "zone": "Z3"} preferred = {"region": "R1", "zone": "Z3"} then the SP SHOULD first attempt to make the provisioned volume available from "zone" "Z3" in the "region" "R1" and fall back to "zone" "Z2" in the "region" "R1" if that is not possible. Example 2: Given a volume should be accessible from a single zone, and requisite = {"region": "R1", "zone": "Z2"}, {"region": "R1", "zone": "Z3"}, {"region": "R1", "zone": "Z4"}, {"region": "R1", "zone": "Z5"} preferred = {"region": "R1", "zone": "Z4"}, {"region": "R1", "zone": "Z2"} then the SP SHOULD first attempt to make the provisioned volume accessible from "zone" "Z4" in the "region" "R1" and fall back to "zone" "Z2" in the "region" "R1" if that is not possible. If that is not possible, the SP may choose between either the "zone" "Z3" or "Z5" in the "region" "R1". Example 3: Given a volume should be accessible from TWO zones (because an opaque parameter in CreateVolumeRequest, for example, specifies the volume is accessible from two zones, aka synchronously replicated), and requisite = {"region": "R1", "zone": "Z2"}, {"region": "R1", "zone": "Z3"}, {"region": "R1", "zone": "Z4"}, {"region": "R1", "zone": "Z5"} preferred = {"region": "R1", "zone": "Z5"}, {"region": "R1", "zone": "Z3"} then the SP SHOULD first attempt to make the provisioned volume accessible from the combination of the two "zones" "Z5" and "Z3" in the "region" "R1". If that’s not possible, it should fall back to a combination of "Z5" and other possibilities from the list of requisite. If that’s not possible, it should fall back to a combination of "Z3" and other possibilities from the list of requisite. If that’s not possible, it should fall back to a combination of other possibilities from the list of requisite.

§requisite: Option<Vec<Topology>>

Requisite specifies a list of Topologies, at least one of which the volume must be accessible from. Taken verbatim from the CSI Spec: Specifies the list of topologies the provisioned volume MUST be accessible from. This field is OPTIONAL. If TopologyRequirement is specified either requisite or preferred or both MUST be specified. If requisite is specified, the provisioned volume MUST be accessible from at least one of the requisite topologies. Given x = number of topologies provisioned volume is accessible from n = number of requisite topologies The CO MUST ensure n >= 1. The SP MUST ensure x >= 1 If x==n, then the SP MUST make the provisioned volume available to all topologies from the list of requisite topologies. If it is unable to do so, the SP MUST fail the CreateVolume call. For example, if a volume should be accessible from a single zone, and requisite = {"region": "R1", "zone": "Z2"} then the provisioned volume MUST be accessible from the "region" "R1" and the "zone" "Z2". Similarly, if a volume should be accessible from two zones, and requisite = {"region": "R1", "zone": "Z2"}, {"region": "R1", "zone": "Z3"} then the provisioned volume MUST be accessible from the "region" "R1" and both "zone" "Z2" and "zone" "Z3". If x<n, then the SP SHALL choose x unique topologies from the list of requisite topologies. If it is unable to do so, the SP MUST fail the CreateVolume call. For example, if a volume should be accessible from a single zone, and requisite = {"region": "R1", "zone": "Z2"}, {"region": "R1", "zone": "Z3"} then the SP may choose to make the provisioned volume available in either the "zone" "Z2" or the "zone" "Z3" in the "region" "R1". Similarly, if a volume should be accessible from two zones, and requisite = {"region": "R1", "zone": "Z2"}, {"region": "R1", "zone": "Z3"}, {"region": "R1", "zone": "Z4"} then the provisioned volume MUST be accessible from any combination of two unique topologies: e.g. "R1/Z2" and "R1/Z3", or "R1/Z2" and "R1/Z4", or "R1/Z3" and "R1/Z4". If x>n, then the SP MUST make the provisioned volume available from all topologies from the list of requisite topologies and MAY choose the remaining x-n unique topologies from the list of all possible topologies. If it is unable to do so, the SP MUST fail the CreateVolume call. For example, if a volume should be accessible from two zones, and requisite = {"region": "R1", "zone": "Z2"} then the provisioned volume MUST be accessible from the "region" "R1" and the "zone" "Z2" and the SP may select the second zone independently, e.g. "R1/Z4".

Implementations§

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impl TopologyRequirement

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pub fn new() -> TopologyRequirement

TopologyRequirement expresses the user’s requirements for a volume’s accessible topology.

Trait Implementations§

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impl Clone for TopologyRequirement

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fn clone(&self) -> TopologyRequirement

Returns a copy of the value. Read more
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fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source. Read more
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impl Debug for TopologyRequirement

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fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter. Read more
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impl Default for TopologyRequirement

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fn default() -> TopologyRequirement

Returns the “default value” for a type. Read more
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impl<'de> Deserialize<'de> for TopologyRequirement

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fn deserialize<__D>( __deserializer: __D, ) -> Result<TopologyRequirement, <__D as Deserializer<'de>>::Error>
where __D: Deserializer<'de>,

Deserialize this value from the given Serde deserializer. Read more
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impl PartialEq for TopologyRequirement

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fn eq(&self, other: &TopologyRequirement) -> bool

This method tests for self and other values to be equal, and is used by ==.
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fn ne(&self, other: &Rhs) -> bool

This method tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.
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impl Serialize for TopologyRequirement

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fn serialize<__S>( &self, __serializer: __S, ) -> Result<<__S as Serializer>::Ok, <__S as Serializer>::Error>
where __S: Serializer,

Serialize this value into the given Serde serializer. Read more
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impl StructuralPartialEq for TopologyRequirement

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