As far as I can see, there is no way to do this without the use of a database. The "algorithm" itself would then be a union of the structure of the database and the queries made to it.
For example, a relational database which had a table of English words, each two columns: word and 1 or more parts of speech, is the most basic language processing database conceivable. A more complex one would also have a verb table with two columns, word, and "temporal characteristics".
As an example, the word "be" always describes a state. Therefore, a program that sees the word be (or its conjugations: is, are, was, etc.) can immediately recognize the clause as describing a state-of-being. Obviously, the word accomplish will immediately denote an accomplishment, and "achieve" will always denote an achievement. But don't forget that out of the four categories you listed, only "state" and "event" are mutually exclusive (with the exception of a present participle such as in the sentence "An event is taking place."). Other than that, a state can also be an accomplishment or achievement ("I am an Olympic gold medalist.") and so can an event ("I graduate tomorrow.").
Accomplishment and achievement are also subjective terms and depend on the sensibilities of the speaker and reader alike. Words like "achieve", "accomplished" and "succeeded" are deliberate expressions of a feeling of achievement, and can therefore always be categorized as such. However, this is a priori information, and would therefore require a relational database to be realized.
Finally, some words' "temporal characteristics" change depending the other words in the sentence. For example, in the sentence "I smell good.", "smell" is a state-of-being verb. In the sentence "I smell bacon.", it is an action verb. These kinds of verbs are action verbs when followed by a noun (transitive), state-of-being verbs when followed by an adjective (predicate nominative), and action verbs when followed by neither (intransitive). A parser would therefore have to inspect the words that follow it in the sentence, one as a noun or adjective, and from that recognize the verb's role in the sentence. This is a joint effort between the database knowing the parts of speech of each word, and the algorithm being able to parse the sentence correctly (and simply knowing that it needs to parse it at all).
This is just a brief overview of lexographical computing, and just my knowledge on the subject. There's a lot more to it and obviously, populating a database with words and their parts of speech, definitions, roles, etc. is tedious. There may exist databases pre-populated with the information that a lexographical computer scientist would need to implement such a system (but I don't claim to know where one would find them).
Hope I've helped, and good luck!