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
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
|
/*
* Copyright 2016 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrUserStencilSettings_DEFINED
#define GrUserStencilSettings_DEFINED
#include "GrTypes.h"
/**
* Gr uses the stencil buffer to implement complex clipping inside the
* GrOpList class. The GrOpList makes a subset of the stencil buffer
* bits available for other uses by external code (user bits). Client code can
* modify these bits. GrOpList will ignore ref, mask, and writemask bits
* provided by clients that fall outside the user range.
*
* When code outside the GrOpList class uses the stencil buffer the contract
* is as follows:
*
* > Normal stencil funcs allow the client to pass / fail regardless of the
* reserved clip bits.
* > Additional functions allow a test against the clip along with a limited
* set of tests against the user bits.
* > Client can assume all user bits are zero initially.
* > Client must ensure that after all its passes are finished it has only
* written to the color buffer in the region inside the clip. Furthermore, it
* must zero all user bits that were modifed (both inside and outside the
* clip).
*/
enum GrStencilFlags {
kDisabled_StencilFlag = 0x1,
kNoModifyStencil_StencilFlag = 0x2,
kNoWrapOps_StencilFlag = 0x4,
kSingleSided_StencilFlag = 0x8,
kLast_StencilFlag = kSingleSided_StencilFlag,
kAll_StencilFlags = kLast_StencilFlag | (kLast_StencilFlag - 1)
};
template<typename TTest, typename TOp> struct GrTStencilFaceSettings {
uint16_t fRef; // Reference value for stencil test and ops.
TTest fTest; // Stencil test function, where fRef is on the left side.
uint16_t fTestMask; // Bitwise "and" to perform on fRef and stencil values before testing.
// (e.g. (fRef & fTestMask) < (stencil & fTestMask))
TOp fPassOp; // Op to perform when the test passes.
TOp fFailOp; // Op to perform when the test fails.
uint16_t fWriteMask; // Indicates which bits in the stencil buffer should be updated.
// (e.g. stencil = (newValue & fWriteMask) | (stencil & ~fWriteMask))
};
enum class GrUserStencilTest : uint16_t {
// Tests that respect the clip bit. If a stencil clip is not in effect, the "IfInClip" is
// ignored and these only act on user bits.
kAlwaysIfInClip,
kEqualIfInClip,
kLessIfInClip,
kLEqualIfInClip,
// Tests that ignore the clip bit. The client is responsible to ensure no color write occurs
// outside the clip if it is in use.
kAlways,
kNever,
kGreater,
kGEqual,
kLess,
kLEqual,
kEqual,
kNotEqual
};
constexpr static GrUserStencilTest kLastClippedStencilTest = GrUserStencilTest::kLEqualIfInClip;
constexpr static int kGrUserStencilTestCount = 1 + (int)GrUserStencilTest::kNotEqual;
enum class GrUserStencilOp : uint8_t {
kKeep,
// Ops that only modify user bits. These must not be paired with ops that modify the clip bit.
kZero,
kReplace, // Replace stencil value with fRef (only the bits enabled in fWriteMask).
kInvert,
kIncWrap,
kDecWrap,
// These two should only be used if wrap ops are not supported, or if the math is guaranteed
// to not overflow. The user bits may or may not clamp, depending on the state of non-user bits.
kIncMaybeClamp,
kDecMaybeClamp,
// Ops that only modify the clip bit. These must not be paired with ops that modify user bits.
kZeroClipBit,
kSetClipBit,
kInvertClipBit,
// Ops that modify both clip and user bits. These can only be paired with kKeep or each other.
kSetClipAndReplaceUserBits,
kZeroClipAndUserBits
};
constexpr static GrUserStencilOp kLastUserOnlyStencilOp = GrUserStencilOp::kDecMaybeClamp;
constexpr static GrUserStencilOp kLastClipOnlyStencilOp = GrUserStencilOp::kInvertClipBit;
constexpr static int kGrUserStencilOpCount = 1 + (int)GrUserStencilOp::kZeroClipAndUserBits;
/**
* This struct is a compile-time constant representation of user stencil settings. It describes in
* abstract terms how a draw will use the stencil buffer. It gets ODR-used at runtime to define a
* draw's stencil settings, and is later translated into concrete settings when the pipeline is
* finalized.
*/
struct GrUserStencilSettings {
typedef GrTStencilFaceSettings<GrUserStencilTest, GrUserStencilOp> Face;
template<GrUserStencilTest, GrUserStencilOp PassOp, GrUserStencilOp FailOp> struct Attrs;
// Unfortunately, this is the only way to pass template arguments to a constructor.
template<uint16_t Ref, GrUserStencilTest Test, uint16_t TestMask,
GrUserStencilOp PassOp, GrUserStencilOp FailOp, uint16_t WriteMask> struct Init {};
template<uint16_t FtRef, uint16_t BkRef,
GrUserStencilTest FtTest, GrUserStencilTest BkTest,
uint16_t FtTestMask, uint16_t BkTestMask,
GrUserStencilOp FtPassOp, GrUserStencilOp BkPassOp,
GrUserStencilOp FtFailOp, GrUserStencilOp BkFailOp,
uint16_t FtWriteMask, uint16_t BkWriteMask> struct InitSeparate {};
template<uint16_t Ref, GrUserStencilTest Test, uint16_t TestMask,
GrUserStencilOp PassOp, GrUserStencilOp FailOp, uint16_t WriteMask>
constexpr static Init<Ref, Test, TestMask, PassOp, FailOp, WriteMask> StaticInit() {
return Init<Ref, Test, TestMask, PassOp, FailOp, WriteMask>();
}
template<uint16_t FtRef, uint16_t BkRef,
GrUserStencilTest FtTest, GrUserStencilTest BkTest,
uint16_t FtTestMask, uint16_t BkTestMask,
GrUserStencilOp FtPassOp, GrUserStencilOp BkPassOp,
GrUserStencilOp FtFailOp, GrUserStencilOp BkFailOp,
uint16_t FtWriteMask, uint16_t BkWriteMask>
constexpr static InitSeparate<FtRef, BkRef, FtTest, BkTest, FtTestMask, BkTestMask,
FtPassOp, BkPassOp, FtFailOp, BkFailOp, FtWriteMask,
BkWriteMask> StaticInitSeparate() {
return InitSeparate<FtRef, BkRef, FtTest, BkTest, FtTestMask, BkTestMask,
FtPassOp, BkPassOp, FtFailOp, BkFailOp, FtWriteMask, BkWriteMask>();
}
// We construct with template arguments in order to enforce that the struct be compile-time
// constant and to make use of static asserts.
template<uint16_t Ref, GrUserStencilTest Test, uint16_t TestMask,
GrUserStencilOp PassOp, GrUserStencilOp FailOp, uint16_t WriteMask,
typename Attrs = Attrs<Test, PassOp, FailOp> >
constexpr explicit GrUserStencilSettings(
const Init<Ref, Test, TestMask, PassOp, FailOp, WriteMask>&)
: fFrontFlags{(uint16_t)(Attrs::Flags(false) | kSingleSided_StencilFlag),
(uint16_t)(Attrs::Flags(true) | kSingleSided_StencilFlag)}
, fFront{Ref, Test, Attrs::EffectiveTestMask(TestMask), PassOp, FailOp,
Attrs::EffectiveWriteMask(WriteMask)}
, fBackFlags{(uint16_t)(Attrs::Flags(false) | kSingleSided_StencilFlag),
(uint16_t)(Attrs::Flags(true) | kSingleSided_StencilFlag)}
, fBack{Ref, Test, Attrs::EffectiveTestMask(TestMask), PassOp, FailOp,
Attrs::EffectiveWriteMask(WriteMask)} {
}
template<uint16_t FtRef, uint16_t BkRef,
GrUserStencilTest FtTest, GrUserStencilTest BkTest,
uint16_t FtTestMask, uint16_t BkTestMask,
GrUserStencilOp FtPassOp, GrUserStencilOp BkPassOp,
GrUserStencilOp FtFailOp, GrUserStencilOp BkFailOp,
uint16_t FtWriteMask, uint16_t BkWriteMask,
typename FtAttrs = Attrs<FtTest, FtPassOp, FtFailOp>,
typename BkAttrs = Attrs<BkTest, BkPassOp, BkFailOp> >
constexpr explicit GrUserStencilSettings(
const InitSeparate<FtRef, BkRef, FtTest, BkTest, FtTestMask, BkTestMask,
FtPassOp, BkPassOp, FtFailOp, BkFailOp, FtWriteMask, BkWriteMask>&)
: fFrontFlags{FtAttrs::Flags(false), FtAttrs::Flags(true)}
, fFront{FtRef, FtTest, FtAttrs::EffectiveTestMask(FtTestMask), FtPassOp, FtFailOp,
FtAttrs::EffectiveWriteMask(FtWriteMask)}
, fBackFlags{BkAttrs::Flags(false), BkAttrs::Flags(true)}
, fBack{BkRef, BkTest, BkAttrs::EffectiveTestMask(BkTestMask), BkPassOp, BkFailOp,
BkAttrs::EffectiveWriteMask(BkWriteMask)} {}
// This struct can only be constructed with static initializers.
GrUserStencilSettings() = delete;
GrUserStencilSettings(const GrUserStencilSettings&) = delete;
uint16_t flags(bool hasStencilClip) const {
return fFrontFlags[hasStencilClip] & fBackFlags[hasStencilClip];
}
bool isDisabled(bool hasStencilClip) const {
return this->flags(hasStencilClip) & kDisabled_StencilFlag;
}
bool doesWrite(bool hasStencilClip) const {
return !(this->flags(hasStencilClip) & kNoModifyStencil_StencilFlag);
}
bool isTwoSided(bool hasStencilClip) const {
return !(this->flags(hasStencilClip) & kSingleSided_StencilFlag);
}
bool usesWrapOp(bool hasStencilClip) const {
return !(this->flags(hasStencilClip) & kNoWrapOps_StencilFlag);
}
const uint16_t fFrontFlags[2]; // frontFlagsForDraw = fFrontFlags[hasStencilClip].
const Face fFront;
const uint16_t fBackFlags[2]; // backFlagsForDraw = fBackFlags[hasStencilClip].
const Face fBack;
static const GrUserStencilSettings& kUnused;
bool isUnused() const { return this == &kUnused; }
};
template<GrUserStencilTest Test, GrUserStencilOp PassOp, GrUserStencilOp FailOp>
struct GrUserStencilSettings::Attrs {
// Ensure an op that only modifies user bits isn't paired with one that modifies clip bits.
GR_STATIC_ASSERT(GrUserStencilOp::kKeep == PassOp || GrUserStencilOp::kKeep == FailOp ||
(PassOp <= kLastUserOnlyStencilOp) == (FailOp <= kLastUserOnlyStencilOp));
// Ensure an op that only modifies clip bits isn't paired with one that modifies clip and user.
GR_STATIC_ASSERT(GrUserStencilOp::kKeep == PassOp || GrUserStencilOp::kKeep == FailOp ||
(PassOp <= kLastClipOnlyStencilOp) == (FailOp <= kLastClipOnlyStencilOp));
constexpr static bool TestAlwaysPasses(bool hasStencilClip) {
return (!hasStencilClip && GrUserStencilTest::kAlwaysIfInClip == Test) ||
GrUserStencilTest::kAlways == Test;
}
constexpr static bool DoesNotModifyStencil(bool hasStencilClip) {
return (GrUserStencilTest::kNever == Test || GrUserStencilOp::kKeep == PassOp) &&
(TestAlwaysPasses(hasStencilClip) || GrUserStencilOp::kKeep == FailOp);
}
constexpr static bool IsDisabled(bool hasStencilClip) {
return TestAlwaysPasses(hasStencilClip) && DoesNotModifyStencil(hasStencilClip);
}
constexpr static bool UsesWrapOps() {
return GrUserStencilOp::kIncWrap == PassOp || GrUserStencilOp::kDecWrap == PassOp ||
GrUserStencilOp::kIncWrap == FailOp || GrUserStencilOp::kDecWrap == FailOp;
}
constexpr static bool TestIgnoresRef() {
return (GrUserStencilTest::kAlwaysIfInClip == Test || GrUserStencilTest::kAlways == Test ||
GrUserStencilTest::kNever == Test);
}
constexpr static uint16_t Flags(bool hasStencilClip) {
return (IsDisabled(hasStencilClip) ? kDisabled_StencilFlag : 0) |
(DoesNotModifyStencil(hasStencilClip) ? kNoModifyStencil_StencilFlag : 0) |
(UsesWrapOps() ? 0 : kNoWrapOps_StencilFlag);
}
constexpr static uint16_t EffectiveTestMask(uint16_t testMask) {
return TestIgnoresRef() ? 0 : testMask;
}
constexpr static uint16_t EffectiveWriteMask(uint16_t writeMask) {
// We don't modify the mask differently when hasStencilClip=false because either the entire
// face gets disabled in that case (e.g. Test=kAlwaysIfInClip, PassOp=kKeep), or else the
// effective mask stays the same either way.
return DoesNotModifyStencil(true) ? 0 : writeMask;
}
};
#endif
|