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1 /*
2  * Copyright 2011 Christoph Bumiller
3  *
4  * Permission is hereby granted, free of charge, to any person obtaining a
5  * copy of this software and associated documentation files (the "Software"),
6  * to deal in the Software without restriction, including without limitation
7  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8  * and/or sell copies of the Software, and to permit persons to whom the
9  * Software is furnished to do so, subject to the following conditions:
10  *
11  * The above copyright notice and this permission notice shall be included in
12  * all copies or substantial portions of the Software.
13  *
14  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
15  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
16  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
17  * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR
18  * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
19  * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
20  * OTHER DEALINGS IN THE SOFTWARE.
21  */
22 
23 #ifndef __NV50_IR_TARGET_H__
24 #define __NV50_IR_TARGET_H__
25 
26 #include "codegen/nv50_ir.h"
27 
28 namespace nv50_ir {
29 
30 struct RelocInfo;
31 
32 struct RelocEntry
33 {
34    enum Type
35    {
36       TYPE_CODE,
37       TYPE_BUILTIN,
38       TYPE_DATA
39    };
40 
41    uint32_t data;
42    uint32_t mask;
43    uint32_t offset;
44    int8_t bitPos;
45    Type type;
46 
47    inline void apply(uint32_t *binary, const RelocInfo *info) const;
48 };
49 
50 struct RelocInfo
51 {
52    uint32_t codePos;
53    uint32_t libPos;
54    uint32_t dataPos;
55 
56    uint32_t count;
57 
58    RelocEntry entry[0];
59 };
60 
61 struct FixupData {
FixupDataFixupData62    FixupData(bool force, bool flat, uint8_t alphatest) :
63       force_persample_interp(force), flatshade(flat), alphatest(alphatest) {}
64    bool force_persample_interp;
65    bool flatshade;
66    uint8_t alphatest;
67 };
68 
69 struct FixupEntry;
70 typedef void (*FixupApply)(const FixupEntry*, uint32_t*, const FixupData&);
71 
72 struct FixupEntry
73 {
FixupEntryFixupEntry74    FixupEntry(FixupApply apply, int ipa, int reg, int loc) :
75       apply(apply), ipa(ipa), reg(reg), loc(loc) {}
76 
77    FixupApply apply;
78    union {
79       struct {
80          uint32_t ipa:4; // SC mode used to identify colors
81          uint32_t reg:8; // The reg used for perspective division
82          uint32_t loc:20; // Let's hope we don't have more than 1M-sized shaders
83       };
84       uint32_t val;
85    };
86 };
87 
88 struct FixupInfo
89 {
90    uint32_t count;
91    FixupEntry entry[0];
92 };
93 
94 class CodeEmitter
95 {
96 public:
97    CodeEmitter(const Target *);
~CodeEmitter()98    virtual ~CodeEmitter() { }
99 
100    // returns whether the instruction was encodable and written
101    virtual bool emitInstruction(Instruction *) = 0;
102 
103    virtual uint32_t getMinEncodingSize(const Instruction *) const = 0;
104 
105    void setCodeLocation(void *, uint32_t size);
getCodeLocation()106    inline void *getCodeLocation() const { return code; }
getCodeSize()107    inline uint32_t getCodeSize() const { return codeSize; }
108 
109    bool addReloc(RelocEntry::Type, int w, uint32_t data, uint32_t m,
110                  int s);
111 
getRelocInfo()112    inline void *getRelocInfo() const { return relocInfo; }
113 
114    bool addInterp(int ipa, int reg, FixupApply apply);
getFixupInfo()115    inline void *getFixupInfo() const { return fixupInfo; }
116 
117    virtual void prepareEmission(Program *);
118    virtual void prepareEmission(Function *);
119    virtual void prepareEmission(BasicBlock *);
120 
121    void printBinary() const;
122 
123 protected:
124    const Target *targ;
125 
126    uint32_t *code;
127    uint32_t codeSize;
128    uint32_t codeSizeLimit;
129 
130    RelocInfo *relocInfo;
131    FixupInfo *fixupInfo;
132 };
133 
134 
135 enum OpClass
136 {
137    OPCLASS_MOVE          = 0,
138    OPCLASS_LOAD          = 1,
139    OPCLASS_STORE         = 2,
140    OPCLASS_ARITH         = 3,
141    OPCLASS_SHIFT         = 4,
142    OPCLASS_SFU           = 5,
143    OPCLASS_LOGIC         = 6,
144    OPCLASS_COMPARE       = 7,
145    OPCLASS_CONVERT       = 8,
146    OPCLASS_ATOMIC        = 9,
147    OPCLASS_TEXTURE       = 10,
148    OPCLASS_SURFACE       = 11,
149    OPCLASS_FLOW          = 12,
150    OPCLASS_PSEUDO        = 14,
151    OPCLASS_VECTOR        = 15,
152    OPCLASS_BITFIELD      = 16,
153    OPCLASS_CONTROL       = 17,
154    OPCLASS_OTHER         = 18
155 };
156 
157 class Target
158 {
159 public:
Target(bool m,bool j,bool s)160    Target(bool m, bool j, bool s) : hasJoin(m), joinAnterior(j), hasSWSched(s) { }
~Target()161    virtual ~Target() { }
162 
163    static Target *create(uint32_t chipset);
164    static void destroy(Target *);
165 
166    // 0x50 and 0x84 to 0xaf for nv50
167    // 0xc0 to 0xdf for nvc0
getChipset()168    inline uint32_t getChipset() const { return chipset; }
169 
170    virtual CodeEmitter *getCodeEmitter(Program::Type) = 0;
171 
172    // Drivers should upload this so we can use it from all programs.
173    // The address chosen is supplied to the relocation routine.
174    virtual void getBuiltinCode(const uint32_t **code, uint32_t *size) const = 0;
175 
parseDriverInfo(const struct nv50_ir_prog_info * info,const struct nv50_ir_prog_info_out * info_out)176    virtual void parseDriverInfo(const struct nv50_ir_prog_info *info,
177                                 const struct nv50_ir_prog_info_out *info_out) {
178       if (info_out->type == PIPE_SHADER_COMPUTE) {
179          threads = info->prop.cp.numThreads[0] *
180             info->prop.cp.numThreads[1] *
181             info->prop.cp.numThreads[2];
182          if (threads == 0)
183             threads = info->target >= NVISA_GK104_CHIPSET ? 1024 : 512;
184       } else {
185          threads = 32; // doesn't matter, just not too big.
186       }
187    }
188 
189    virtual bool runLegalizePass(Program *, CGStage stage) const = 0;
190 
191 public:
192    struct OpInfo
193    {
194       OpInfo *variants;
195       operation op;
196       uint16_t srcTypes;
197       uint16_t dstTypes;
198       uint32_t immdBits;
199       uint8_t srcNr;
200       uint8_t srcMods[3];
201       uint8_t dstMods;
202       uint16_t srcFiles[3];
203       uint16_t dstFiles;
204       unsigned int minEncSize  : 5;
205       unsigned int vector      : 1;
206       unsigned int predicate   : 1;
207       unsigned int commutative : 1;
208       unsigned int pseudo      : 1;
209       unsigned int flow        : 1;
210       unsigned int hasDest     : 1;
211       unsigned int terminator  : 1;
212    };
213 
214    inline const OpInfo& getOpInfo(const Instruction *) const;
215    inline const OpInfo& getOpInfo(const operation) const;
216 
217    inline DataFile nativeFile(DataFile f) const;
218 
219    virtual bool insnCanLoad(const Instruction *insn, int s,
220                             const Instruction *ld) const = 0;
221    virtual bool insnCanLoadOffset(const Instruction *insn, int s,
222                                   int offset) const = 0;
223    virtual bool isOpSupported(operation, DataType) const = 0;
224    virtual bool isAccessSupported(DataFile, DataType) const = 0;
225    virtual bool isModSupported(const Instruction *,
226                                int s, Modifier) const = 0;
227    virtual bool isSatSupported(const Instruction *) const = 0;
isPostMultiplySupported(operation op,float f,int & e)228    virtual bool isPostMultiplySupported(operation op, float f,
229                                         int& e) const { return false; }
230    virtual bool mayPredicate(const Instruction *,
231                              const Value *) const = 0;
232 
233    // whether @insn can be issued together with @next (order matters)
canDualIssue(const Instruction * insn,const Instruction * next)234    virtual bool canDualIssue(const Instruction *insn,
235                              const Instruction *next) const { return false; }
getLatency(const Instruction *)236    virtual int getLatency(const Instruction *) const { return 1; }
getThroughput(const Instruction *)237    virtual int getThroughput(const Instruction *) const { return 1; }
238 
239    virtual unsigned int getFileSize(DataFile) const = 0;
240    virtual unsigned int getFileUnit(DataFile) const = 0;
241 
242    virtual uint32_t getSVAddress(DataFile, const Symbol *) const = 0;
243 
244 public:
245    const bool hasJoin;      // true if instructions have a join modifier
246    const bool joinAnterior; // true if join is executed before the op
247    const bool hasSWSched;   // true if code should provide scheduling data
248 
249    static const uint8_t operationSrcNr[];
250    static const OpClass operationClass[];
251 
getOpSrcNr(operation op)252    static inline uint8_t getOpSrcNr(operation op)
253    {
254       return operationSrcNr[op];
255    }
getOpClass(operation op)256    static inline OpClass getOpClass(operation op)
257    {
258       return operationClass[op];
259    }
260 
261 protected:
262    uint32_t chipset;
263    uint32_t threads;
264 
265    DataFile nativeFileMap[DATA_FILE_COUNT];
266 
267    OpInfo opInfo[OP_LAST + 1];
268 };
269 
getOpInfo(const Instruction * insn)270 const Target::OpInfo& Target::getOpInfo(const Instruction *insn) const
271 {
272    return opInfo[MIN2(insn->op, OP_LAST)];
273 }
274 
getOpInfo(const operation op)275 const Target::OpInfo& Target::getOpInfo(const operation op) const
276 {
277    return opInfo[op];
278 }
279 
nativeFile(DataFile f)280 inline DataFile Target::nativeFile(DataFile f) const
281 {
282    return nativeFileMap[f];
283 }
284 
285 } // namespace nv50_ir
286 
287 #endif // __NV50_IR_TARGET_H__
288