-
Notifications
You must be signed in to change notification settings - Fork 46
Expand file tree
/
Copy pathmod_hooks.cpp
More file actions
156 lines (128 loc) · 5.36 KB
/
Copy pathmod_hooks.cpp
File metadata and controls
156 lines (128 loc) · 5.36 KB
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
#include <vector>
#include "librecomp/mods.hpp"
#include "librecomp/overlays.hpp"
#include "ultramodern/error_handling.hpp"
template<class... Ts>
struct overloaded : Ts... { using Ts::operator()...; };
template<class... Ts>
overloaded(Ts...) -> overloaded<Ts...>;
struct HookEntry {
size_t mod_index;
recomp::mods::GenericFunction func;
};
struct HookTableEntry {
std::vector<HookEntry> hooks;
bool is_return_hook;
};
// Vector of individual hooks for each hook slot.
std::vector<HookTableEntry> hook_table{};
// Holds the recomp context to restore after running each hook. This is a vector because a hook may end up calling another hooked function,
// so this acts as a stack of contexts to handle that recursion.
thread_local std::vector<recomp_context> hook_contexts = { recomp_context{} };
void recomp::mods::run_hook(uint8_t* rdram, recomp_context* ctx, size_t hook_slot_index) {
// Sanity check the hook slot index.
if (hook_slot_index >= hook_table.size()) {
printf("Hook slot %zu triggered, but only %zu hook slots have been registered!\n", hook_slot_index, hook_table.size());
assert(false);
ultramodern::error_handling::message_box("Encountered an error with loaded mods: hook slot out of bounds");
ULTRAMODERN_QUICK_EXIT();
}
// Copy the initial context state to restore it after running each callback.
hook_contexts.emplace_back(*ctx);
// Call every hook attached to the hook slot.
const std::vector<HookEntry>& hooks = hook_table[hook_slot_index].hooks;
for (HookEntry hook : hooks) {
// Run the hook.
std::visit(overloaded {
[rdram, ctx](recomp_func_t* native_func) {
native_func(rdram, ctx);
},
}, hook.func);
// Restore the original context.
*ctx = hook_contexts.back();
}
// Pop the context after the hook is done.
hook_contexts.pop_back();
}
void recomp::mods::setup_hooks(size_t num_hook_slots) {
hook_table.resize(num_hook_slots);
}
void recomp::mods::set_hook_type(size_t hook_slot_index, bool is_return) {
hook_table[hook_slot_index].is_return_hook = is_return;
}
void recomp::mods::register_hook(size_t hook_slot_index, size_t mod_index, GenericFunction callback) {
hook_table[hook_slot_index].hooks.emplace_back(HookEntry{ mod_index, callback });
}
void recomp::mods::finish_hook_setup(const ModContext& context) {
// Sort hooks by mod order (and return hooks in reverse order).
for (HookTableEntry& cur_entry : hook_table) {
// Reverse sort if this slot is a return hook.
if (cur_entry.is_return_hook) {
std::sort(cur_entry.hooks.begin(), cur_entry.hooks.end(),
[&context](const HookEntry& lhs, const HookEntry& rhs) {
return context.get_mod_order_index(lhs.mod_index) > context.get_mod_order_index(rhs.mod_index);
}
);
}
// Otherwise sort normally.
else {
std::sort(cur_entry.hooks.begin(), cur_entry.hooks.end(),
[&context](const HookEntry& lhs, const HookEntry& rhs) {
return context.get_mod_order_index(lhs.mod_index) < context.get_mod_order_index(rhs.mod_index);
}
);
}
}
}
void recomp::mods::reset_hooks() {
hook_table.clear();
}
void recomphook_get_return_s32(uint8_t* rdram, recomp_context* ctx) {
ctx->r2 = (gpr)(int32_t)hook_contexts.back().r2;
}
void recomphook_get_return_u32(uint8_t* rdram, recomp_context* ctx) {
recomphook_get_return_s32(rdram, ctx);
}
void recomphook_get_return_ptr(uint8_t* rdram, recomp_context* ctx) {
recomphook_get_return_s32(rdram, ctx);
}
void recomphook_get_return_s16(uint8_t* rdram, recomp_context* ctx) {
ctx->r2 = (gpr)(int16_t)hook_contexts.back().r2;
}
void recomphook_get_return_u16(uint8_t* rdram, recomp_context* ctx) {
ctx->r2 = (gpr)(uint16_t)hook_contexts.back().r2;
}
void recomphook_get_return_s8(uint8_t* rdram, recomp_context* ctx) {
ctx->r2 = (gpr)(int8_t)hook_contexts.back().r2;
}
void recomphook_get_return_u8(uint8_t* rdram, recomp_context* ctx) {
ctx->r2 = (gpr)(uint8_t)hook_contexts.back().r2;
}
void recomphook_get_return_s64(uint8_t* rdram, recomp_context* ctx) {
ctx->r2 = (gpr)(int32_t)hook_contexts.back().r2;
ctx->r3 = (gpr)(int32_t)hook_contexts.back().r3;
}
void recomphook_get_return_u64(uint8_t* rdram, recomp_context* ctx) {
recomphook_get_return_s64(rdram, ctx);
}
void recomphook_get_return_float(uint8_t* rdram, recomp_context* ctx) {
ctx->f0.fl = hook_contexts.back().f0.fl;
}
void recomphook_get_return_double(uint8_t* rdram, recomp_context* ctx) {
ctx->f0.fl = (gpr)(uint8_t)hook_contexts.back().f0.fl;
ctx->f1.fl = (gpr)(uint8_t)hook_contexts.back().f1.fl;
}
#define REGISTER_FUNC(name) recomp::overlays::register_base_export(#name, name)
void recomp::mods::register_hook_exports() {
REGISTER_FUNC(recomphook_get_return_s32);
REGISTER_FUNC(recomphook_get_return_u32);
REGISTER_FUNC(recomphook_get_return_ptr);
REGISTER_FUNC(recomphook_get_return_s16);
REGISTER_FUNC(recomphook_get_return_u16);
REGISTER_FUNC(recomphook_get_return_s8);
REGISTER_FUNC(recomphook_get_return_u8);
REGISTER_FUNC(recomphook_get_return_s64);
REGISTER_FUNC(recomphook_get_return_u64);
REGISTER_FUNC(recomphook_get_return_float);
REGISTER_FUNC(recomphook_get_return_double);
}