core/ffi/primitives.rs
1//! Defines primitive types that match C's type definitions for FFI compatibility.
2//!
3//! This module is intentionally standalone to facilitate parsing when retrieving
4//! core C types.
5
6macro_rules! type_alias {
7 {
8 $Docfile:tt, $Alias:ident = $Real:ty;
9 $( $Cfg:tt )*
10 } => {
11 #[doc = include_str!($Docfile)]
12 $( $Cfg )*
13 #[stable(feature = "core_ffi_c", since = "1.64.0")]
14 pub type $Alias = $Real;
15 }
16}
17
18type_alias! { "c_char.md", c_char = c_char_definition::c_char; #[doc(cfg(all()))] }
19
20type_alias! { "c_schar.md", c_schar = i8; }
21type_alias! { "c_uchar.md", c_uchar = u8; }
22type_alias! { "c_short.md", c_short = i16; }
23type_alias! { "c_ushort.md", c_ushort = u16; }
24
25type_alias! { "c_int.md", c_int = c_int_definition::c_int; #[doc(cfg(all()))] }
26type_alias! { "c_uint.md", c_uint = c_int_definition::c_uint; #[doc(cfg(all()))] }
27
28type_alias! { "c_long.md", c_long = c_long_definition::c_long; #[doc(cfg(all()))] }
29type_alias! { "c_ulong.md", c_ulong = c_long_definition::c_ulong; #[doc(cfg(all()))] }
30
31type_alias! { "c_longlong.md", c_longlong = i64; }
32type_alias! { "c_ulonglong.md", c_ulonglong = u64; }
33
34type_alias! { "c_float.md", c_float = f32; }
35type_alias! { "c_double.md", c_double = f64; }
36
37mod c_char_definition {
38 cfg_if! {
39 // These are the targets on which c_char is unsigned. Usually the
40 // signedness is the same for all target_os values on a given architecture
41 // but there are some exceptions (see isSignedCharDefault() in clang).
42 //
43 // aarch64:
44 // Section 10 "Arm C and C++ language mappings" in Procedure Call Standard for the Arm®
45 // 64-bit Architecture (AArch64) says C/C++ char is unsigned byte.
46 // https://github.com/ARM-software/abi-aa/blob/2024Q3/aapcs64/aapcs64.rst#arm-c-and-c-language-mappings
47 // arm:
48 // Section 8 "Arm C and C++ Language Mappings" in Procedure Call Standard for the Arm®
49 // Architecture says C/C++ char is unsigned byte.
50 // https://github.com/ARM-software/abi-aa/blob/2024Q3/aapcs32/aapcs32.rst#arm-c-and-c-language-mappings
51 // csky:
52 // Section 2.1.2 "Primary Data Type" in C-SKY V2 CPU Applications Binary Interface
53 // Standards Manual says ANSI C char is unsigned byte.
54 // https://github.com/c-sky/csky-doc/blob/9f7121f7d40970ba5cc0f15716da033db2bb9d07/C-SKY_V2_CPU_Applications_Binary_Interface_Standards_Manual.pdf
55 // Note: this doesn't seem to match Clang's default (https://github.com/rust-lang/rust/issues/129945).
56 // hexagon:
57 // Section 3.1 "Basic data type" in Qualcomm Hexagon™ Application
58 // Binary Interface User Guide says "By default, the `char` data type is unsigned."
59 // https://docs.qualcomm.com/bundle/publicresource/80-N2040-23_REV_K_Qualcomm_Hexagon_Application_Binary_Interface_User_Guide.pdf
60 // msp430:
61 // Section 2.1 "Basic Types" in MSP430 Embedded Application Binary
62 // Interface says "The char type is unsigned by default".
63 // https://www.ti.com/lit/an/slaa534a/slaa534a.pdf
64 // powerpc/powerpc64:
65 // - PPC32 SysV: "Table 3-1 Scalar Types" in System V Application Binary Interface PowerPC
66 // Processor Supplement says ANSI C char is unsigned byte
67 // https://refspecs.linuxfoundation.org/elf/elfspec_ppc.pdf
68 // - PPC64 ELFv1: Section 3.1.4 "Fundamental Types" in 64-bit PowerPC ELF Application
69 // Binary Interface Supplement 1.9 says ANSI C is unsigned byte
70 // https://refspecs.linuxfoundation.org/ELF/ppc64/PPC-elf64abi.html#FUND-TYPE
71 // - PPC64 ELFv2: Section 2.1.2.2 "Fundamental Types" in 64-Bit ELF V2 ABI Specification
72 // says char is unsigned byte
73 // https://openpowerfoundation.org/specifications/64bitelfabi/
74 // - AIX: XL C for AIX Language Reference says "By default, char behaves like an unsigned char."
75 // https://www.ibm.com/docs/en/xl-c-aix/13.1.3?topic=specifiers-character-types
76 // riscv32/riscv64:
77 // C/C++ type representations section in RISC-V Calling Conventions
78 // page in RISC-V ELF psABI Document says "char is unsigned."
79 // https://github.com/riscv-non-isa/riscv-elf-psabi-doc/blob/draft-20240829-13bfa9f54634cb60d86b9b333e109f077805b4b3/riscv-cc.adoc#cc-type-representations
80 // s390x:
81 // - ELF: "Table 1.1.: Scalar types" in ELF Application Binary Interface s390x Supplement
82 // Version 1.6.1 categorize ISO C char in unsigned integer
83 // https://github.com/IBM/s390x-abi/releases/tag/v1.6.1
84 // - z/OS: XL C/C++ Language Reference says: "By default, char behaves like an unsigned char."
85 // https://www.ibm.com/docs/en/zos/3.1.0?topic=specifiers-character-types
86 // xtensa:
87 // Section 2.17.1 "Data Types and Alignment" of Xtensa LX Microprocessor Overview handbook
88 // says "`char` type is unsigned by default".
89 // https://loboris.eu/ESP32/Xtensa_lx%20Overview%20handbook.pdf
90 //
91 // On the following operating systems, c_char is signed by default, regardless of architecture.
92 // Darwin (macOS, iOS, etc.):
93 // Apple targets' c_char is signed by default even on arm
94 // https://developer.apple.com/documentation/xcode/writing-arm64-code-for-apple-platforms#Handle-data-types-and-data-alignment-properly
95 // Windows:
96 // Windows MSVC C++ Language Reference says "Microsoft-specific: Variables of type char
97 // are promoted to int as if from type signed char by default, unless the /J compilation
98 // option is used."
99 // https://learn.microsoft.com/en-us/cpp/cpp/fundamental-types-cpp?view=msvc-170#character-types
100 // L4Re:
101 // The kernel builds with -funsigned-char on all targets (but useserspace follows the
102 // architecture defaults). As we only have a target for userspace apps so there are no
103 // special cases for L4Re below.
104 // https://github.com/rust-lang/rust/pull/132975#issuecomment-2484645240
105 if #[cfg(all(
106 not(windows),
107 not(target_vendor = "apple"),
108 any(
109 target_arch = "aarch64",
110 target_arch = "arm",
111 target_arch = "csky",
112 target_arch = "hexagon",
113 target_arch = "msp430",
114 target_arch = "powerpc",
115 target_arch = "powerpc64",
116 target_arch = "riscv32",
117 target_arch = "riscv64",
118 target_arch = "s390x",
119 target_arch = "xtensa",
120 )
121 ))] {
122 pub(super) type c_char = u8;
123 } else {
124 // On every other target, c_char is signed.
125 pub(super) type c_char = i8;
126 }
127 }
128}
129
130mod c_long_definition {
131 cfg_if! {
132 if #[cfg(all(target_pointer_width = "64", not(windows)))] {
133 pub(super) type c_long = i64;
134 pub(super) type c_ulong = u64;
135 } else {
136 // The minimal size of `long` in the C standard is 32 bits
137 pub(super) type c_long = i32;
138 pub(super) type c_ulong = u32;
139 }
140 }
141}
142
143/// Equivalent to C's `size_t` type, from `stddef.h` (or `cstddef` for C++).
144///
145/// This type is currently always [`usize`], however in the future there may be
146/// platforms where this is not the case.
147#[unstable(feature = "c_size_t", issue = "88345")]
148pub type c_size_t = usize;
149
150/// Equivalent to C's `ptrdiff_t` type, from `stddef.h` (or `cstddef` for C++).
151///
152/// This type is currently always [`isize`], however in the future there may be
153/// platforms where this is not the case.
154#[unstable(feature = "c_size_t", issue = "88345")]
155pub type c_ptrdiff_t = isize;
156
157/// Equivalent to C's `ssize_t` (on POSIX) or `SSIZE_T` (on Windows) type.
158///
159/// This type is currently always [`isize`], however in the future there may be
160/// platforms where this is not the case.
161#[unstable(feature = "c_size_t", issue = "88345")]
162pub type c_ssize_t = isize;
163
164mod c_int_definition {
165 cfg_if! {
166 if #[cfg(any(target_arch = "avr", target_arch = "msp430"))] {
167 pub(super) type c_int = i16;
168 pub(super) type c_uint = u16;
169 } else {
170 pub(super) type c_int = i32;
171 pub(super) type c_uint = u32;
172 }
173 }
174}