119 lines
6.1 KiB
JSON
119 lines
6.1 KiB
JSON
{
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"predicates": [
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{
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"description": "Unintentional failures wherein the failure is because an ML system produces a formally correct but completely unsafe outcome.",
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"expanded": "Unintended Failures Summary",
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"value": "unintended-failures-summary"
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},
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{
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"expanded": "Intentionally-Motivated Failures Summary",
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"description": "Intentional failures wherein the failure is caused by an active adversary attempting to subvert the system to attain her goals – either to misclassify the result, infer private training data, or to steal the underlying algorithm.",
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"value": "intentionally-motivated-failures-summary"
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}
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],
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"values": [
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{
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"predicate": "intentionally-motivated-failures-summary",
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"entry": [
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{
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"value": "1-perturbation-attack",
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"expanded": "Perturbation attack",
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"description": "Attacker modifies the query to get appropriate response. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "2-poisoning-attack",
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"expanded": "Poisoning attack",
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"description": "Attacker contaminates the training phase of ML systems to get intended result. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "3-model-inversion",
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"expanded": "Model Inversion",
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"description": "Attacker recovers the secret features used in the model by through careful queries. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "4-membership-inference",
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"expanded": "Membership Inference",
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"description": "Attacker can infer if a given data record was part of the model’s training dataset or not. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "5-model-stealing",
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"expanded": "Model Stealing",
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"description": "Attacker is able to recover the model through carefully-crafted queries. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "6-reprogramming-ML-system",
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"expanded": "Reprogramming ML system",
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"description": "Repurpose the ML system to perform an activity it was not programmed for. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "7-adversarial-example-in-physical-domain",
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"expanded": "Adversarial Example in Physical Domain ",
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"description": "Repurpose the ML system to perform an activity it was not programmed for. It doesn't violate traditional technological notion of access/authorization."
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},
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{
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"value": "8-malicious-ML-provider-recovering-training-data",
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"expanded": "Malicious ML provider recovering training data",
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"description": "Malicious ML provider can query the model used by customer and recover customer’s training data. It does violate traditional technological notion of access/authorization."
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},
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{
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"value": "9-attacking-the-ML-supply-chain",
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"expanded": "Attacking the ML supply chain",
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"description": "Attacker compromises the ML models as it is being downloaded for use. It does violate traditional technological notion of access/authorization."
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},
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{
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"value": "10-backdoor-ML",
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"expanded": "Backdoor ML",
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"description": "Malicious ML provider backdoors algorithm to activate with a specific trigger. It does violate traditional technological notion of access/authorization."
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},
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{
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"value": "10-exploit-software-dependencies",
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"expanded": "Exploit Software Dependencies",
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"description": "Attacker uses traditional software exploits like buffer overflow to confuse/control ML systems. It does violate traditional technological notion of access/authorization."
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}
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]
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},
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{
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"predicate": "unintended-failures-summary",
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"entry": [
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{
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"value": "12-reward-hacking",
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"expanded": "Reward Hacking",
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"description": "Reinforcement Learning (RL) systems act in unintended ways because of mismatch between stated reward and true reward"
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},
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{
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"value": "13-side-effects",
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"expanded": "Side Effects",
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"description": "RL system disrupts the environment as it tries to attain its goal"
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},
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{
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"value": "14-distributional-shifts",
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"expanded": "Distributional shifts",
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"description": "The system is tested in one kind of environment, but is unable to adapt to changes in other kinds of environment"
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},
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{
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"value": "15-natural-adversarial-examples",
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"expanded": "Natural Adversarial Examples",
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"description": "Without attacker perturbations, the ML system fails owing to hard negative mining"
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},
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{
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"value": "16-common-corruption",
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"expanded": "Common Corruption",
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"description": "The system is not able to handle common corruptions and perturbations such as tilting, zooming, or noisy images"
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},
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{
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"value": "17-incomplete-testing",
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"expanded": "Incomplete Testing",
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"description": "The ML system is not tested in the realistic conditions that it is meant to operate in"
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}
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]
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}
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],
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"refs": [
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"https://docs.microsoft.com/en-us/security/failure-modes-in-machine-learning"
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],
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"version": 1,
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"description": "The purpose of this taxonomy is to jointly tabulate both the of these failure modes in a single place. Intentional failures wherein the failure is caused by an active adversary attempting to subvert the system to attain her goals – either to misclassify the result, infer private training data, or to steal the underlying algorithm. Unintentional failures wherein the failure is because an ML system produces a formally correct but completely unsafe outcome.",
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"expanded": "Failure mode in machine learning.",
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"namespace": "failure-mode-in-machine-learning"
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}
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