9 年之前 · e0f2f6011e
--- a/docs/Atomics.rst
+++ b/docs/Atomics.rst
@@ -578,7 +578,7 @@ runtime support library.
 
				 LLVM will emit a call to an appropriate ``__sync_*`` routine if the target
			
 
				 ISelLowering code has set the corresponding ``ATOMIC_CMPXCHG``, ``ATOMIC_SWAP``,
			
 
				 or ``ATOMIC_LOAD_*`` operation to "Expand", and if it has opted-into the
			
 
				-availablity of those library functions via a call to ``initSyncLibcalls()``.
			
 
				+availability of those library functions via a call to ``initSyncLibcalls()``.
			
 
				 
			
 
				 The full set of functions that may be called by LLVM is (for ``N`` being 1, 2,
			
 
				 4, 8, or 16)::
			
--- a/docs/LangRef.rst
+++ b/docs/LangRef.rst
@@ -1427,7 +1427,7 @@ example:
 
				     generated for this function needs to follow certain conventions that
			
 
				     make it possible for a runtime function to patch over it later.
			
 
				     The exact effect of this attribute depends on its string value,
			
 
				-    for which there currently is one legal possiblity:
			
 
				+    for which there currently is one legal possibility:
			
 
				 
			
 
				      * ``"prologue-short-redirect"`` - This style of patchable
			
 
				        function is intended to support patching a function prologue to
			
@@ -4338,7 +4338,7 @@ DIMacro
 
				 
			
 
				 ``DIMacro`` nodes represent definition or undefinition of a macro identifiers.
			
 
				 The ``name:`` field is the macro identifier, followed by macro parameters when
			
 
				-definining a function-like macro, and the ``value`` field is the token-string
			
 
				+defining a function-like macro, and the ``value`` field is the token-string
			
 
				 used to expand the macro identifier.
			
 
				 
			
 
				 .. code-block:: llvm
			
--- a/docs/ReportingGuide.rst
+++ b/docs/ReportingGuide.rst
@@ -33,7 +33,7 @@ needed) email conduct@llvm.org.
 
				    intended to discourage this self enforcement of community norms. Instead,
			
 
				    the mechanisms described here are intended to supplement any self
			
 
				    enforcement within the community. They provide avenues for handling severe
			
 
				-   cases or cases where the reporting party does not whish to respond directly
			
 
				+   cases or cases where the reporting party does not wish to respond directly
			
 
				    for any reason.
			
 
				 
			
 
				 Filing a report
			
--- a/docs/TableGen/LangRef.rst
+++ b/docs/TableGen/LangRef.rst
@@ -154,7 +154,7 @@ programmer.
 
				 .. productionlist::
			
 
				    Declaration: `Type` `TokIdentifier` ["=" `Value`]
			
 
				 
			
 
				-It assigns the value to the identifer.
			
 
				+It assigns the value to the identifier.
			
 
				 
			
 
				 Types
			
 
				 -----
			
--- a/docs/tutorial/BuildingAJIT1.rst
+++ b/docs/tutorial/BuildingAJIT1.rst
@@ -47,7 +47,7 @@ code for that chapter and replace it with optimization support in our JIT class
 
				 in Chapter #2.
			
 
				 
			
 
				 Finally, a word on API generations: ORC is the 3rd generation of LLVM JIT API.
			
 
				-It was preceeded by MCJIT, and before that by the (now deleted) legacy JIT.
			
 
				+It was preceded by MCJIT, and before that by the (now deleted) legacy JIT.
			
 
				 These tutorials don't assume any experience with these earlier APIs, but
			
 
				 readers acquainted with them will see many familiar elements. Where appropriate
			
 
				 we will make this connection with the earlier APIs explicit to help people who
			
@@ -140,7 +140,7 @@ to build our LLVM compiler instance; A DataLayout, DL, which will be used for
 
				 symbol mangling (more on that later), and two ORC *layers*: an
			
 
				 ObjectLinkingLayer and a IRCompileLayer. We'll be talking more about layers in
			
 
				 the next chapter, but for now you can think of them as analogous to LLVM
			
 
				-Passes: they wrap up useful JIT utilities behind an easy to compose interace.
			
 
				+Passes: they wrap up useful JIT utilities behind an easy to compose interface.
			
 
				 The first layer, ObjectLinkingLayer, is the foundation of our JIT: it takes
			
 
				 in-memory object files produced by a compiler and links them on the fly to make
			
 
				 them executable. This JIT-on-top-of-a-linker design was introduced in MCJIT,
			
--- a/docs/tutorial/BuildingAJIT2.rst
+++ b/docs/tutorial/BuildingAJIT2.rst
@@ -286,7 +286,7 @@ these choices will have different performance characteristics: Doing work
 
				 eagerly means the JIT takes longer up-front, but proceeds smoothly once this is
			
 
				 done. Deferring work allows the JIT to get up-and-running quickly, but will
			
 
				 force the JIT to pause and wait whenever some code or data is needed that hasn't
			
 
				-already been procesed.
			
 
				+already been processed.
			
 
				 
			
 
				 Our current REPL is eager: Each function definition is optimized and compiled as
			
 
				 soon as it's typed in. If we were to make the transform layer lazy (but not
			
--- a/docs/tutorial/LangImpl08.rst
+++ b/docs/tutorial/LangImpl08.rst
@@ -46,7 +46,7 @@ returns the target triple of the current machine.
 
				 
			
 
				 LLVM doesn't require us to to link in all the target
			
 
				 functionality. For example, if we're just using the JIT, we don't need
			
 
				-the assembly printers. Similarly, if we're only targetting certain
			
 
				+the assembly printers. Similarly, if we're only targeting certain
			
 
				 architectures, we can only link in the functionality for those
			
 
				 architectures.
			
 
				 
			
@@ -80,7 +80,7 @@ Target Machine
 
				 ==============
			
 
				 
			
 
				 We will also need a ``TargetMachine``. This class provides a complete
			
 
				-machine description of the machine we're targetting. If we want to
			
 
				+machine description of the machine we're targeting. If we want to
			
 
				 target a specific feature (such as SSE) or a specific CPU (such as
			
 
				 Intel's Sandylake), we do so now.