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Linux/Documentation/gpu/komeda-kms.rst

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Differences between /Documentation/gpu/komeda-kms.rst (Version linux-6.12-rc7) and /Documentation/gpu/komeda-kms.rst (Version linux-5.0.21)


  1 .. SPDX-License-Identifier: GPL-2.0               
  2                                                   
  3 ==============================                    
  4  drm/komeda Arm display driver                    
  5 ==============================                    
  6                                                   
  7 The drm/komeda driver supports the Arm display    
  8 this document gives a brief overview of driver    
  9 design it like that.                              
 10                                                   
 11 Overview of D71 like display IPs                  
 12 ================================                  
 13                                                   
 14 From D71, Arm display IP begins to adopt a fle    
 15 architecture. A display pipeline is made up of    
 16 functional pipeline stages called components,     
 17 specific capabilities that can give the flowed    
 18 particular processing.                            
 19                                                   
 20 Typical D71 components:                           
 21                                                   
 22 Layer                                             
 23 -----                                             
 24 Layer is the first pipeline stage, which prepa    
 25 stage. It fetches the pixel from memory, decod    
 26 source image, unpacks or converts YUV pixels t    
 27 then adjusts the color_space of pixels if need    
 28                                                   
 29 Scaler                                            
 30 ------                                            
 31 As its name suggests, scaler takes responsibil    
 32 supports image enhancements by scaler.            
 33 The usage of scaler is very flexible and can b    
 34 for layer scaling, or connected to compositor     
 35 frame and then feed the output data into wb_la    
 36 into memory.                                      
 37                                                   
 38 Compositor (compiz)                               
 39 -------------------                               
 40 Compositor blends multiple layers or pixel dat    
 41 frame. its output frame can be fed into post i    
 42 the monitor or fed into wb_layer and written t    
 43 user can also insert a scaler between composit    
 44 the display frame first and then write to memo    
 45                                                   
 46 Writeback Layer (wb_layer)                        
 47 --------------------------                        
 48 Writeback layer does the opposite things of La    
 49 and writes the composition result to memory.      
 50                                                   
 51 Post image processor (improc)                     
 52 -----------------------------                     
 53 Post image processor adjusts frame data like g    
 54 requirements of the monitor.                      
 55                                                   
 56 Timing controller (timing_ctrlr)                  
 57 --------------------------------                  
 58 Final stage of display pipeline, Timing contro    
 59 handling, but only for controlling the display    
 60                                                   
 61 Merger                                            
 62 ------                                            
 63 D71 scaler mostly only has the half horizontal    
 64 compared with Layer, like if Layer supports 4K    
 65 support 2K input/output in the same time. To a    
 66 introduces Layer Split, which splits the whole    
 67 them to two Layers A and B, and does the scali    
 68 the result need to be fed to merger to merge t    
 69 output merged result to compiz.                   
 70                                                   
 71 Splitter                                          
 72 --------                                          
 73 Similar to Layer Split, but Splitter is used f    
 74 compiz result to two parts and then feed them     
 75                                                   
 76 Possible D71 Pipeline usage                       
 77 ===========================                       
 78                                                   
 79 Benefitting from the modularized architecture,    
 80 adjusted to fit different usages. And D71 has     
 81 types of working mode:                            
 82                                                   
 83 -   Dual display mode                             
 84     Two pipelines work independently and separ    
 85                                                   
 86 -   Single display mode                           
 87     Two pipelines work together to drive only     
 88                                                   
 89     On this mode, pipeline_B doesn't work inde    
 90     composition result into pipeline_A, and it    
 91     pipeline_A.timing_ctrlr. The pipeline_B wo    
 92     pipeline_A(master)                            
 93                                                   
 94 Single pipeline data flow                         
 95 -------------------------                         
 96                                                   
 97 .. kernel-render:: DOT                            
 98    :alt: Single pipeline digraph                  
 99    :caption: Single pipeline data flow            
100                                                   
101    digraph single_ppl {                           
102       rankdir=LR;                                 
103                                                   
104       subgraph {                                  
105          "Memory";                                
106          "Monitor";                               
107       }                                           
108                                                   
109       subgraph cluster_pipeline {                 
110           style=dashed                            
111           node [shape=box]                        
112           {                                       
113               node [bgcolor=grey style=dashed]    
114               "Scaler-0";                         
115               "Scaler-1";                         
116               "Scaler-0/1"                        
117           }                                       
118                                                   
119          node [bgcolor=grey style=filled]         
120          "Layer-0" -> "Scaler-0"                  
121          "Layer-1" -> "Scaler-0"                  
122          "Layer-2" -> "Scaler-1"                  
123          "Layer-3" -> "Scaler-1"                  
124                                                   
125          "Layer-0" -> "Compiz"                    
126          "Layer-1" -> "Compiz"                    
127          "Layer-2" -> "Compiz"                    
128          "Layer-3" -> "Compiz"                    
129          "Scaler-0" -> "Compiz"                   
130          "Scaler-1" -> "Compiz"                   
131                                                   
132          "Compiz" -> "Scaler-0/1" -> "Wb_layer    
133          "Compiz" -> "Improc" -> "Timing Contr    
134       }                                           
135                                                   
136       "Wb_layer" -> "Memory"                      
137       "Timing Controller" -> "Monitor"            
138    }                                              
139                                                   
140 Dual pipeline with Slave enabled                  
141 --------------------------------                  
142                                                   
143 .. kernel-render:: DOT                            
144    :alt: Slave pipeline digraph                   
145    :caption: Slave pipeline enabled data flow     
146                                                   
147    digraph slave_ppl {                            
148       rankdir=LR;                                 
149                                                   
150       subgraph {                                  
151          "Memory";                                
152          "Monitor";                               
153       }                                           
154       node [shape=box]                            
155       subgraph cluster_pipeline_slave {           
156           style=dashed                            
157           label="Slave Pipeline_B"                
158           node [shape=box]                        
159           {                                       
160               node [bgcolor=grey style=dashed]    
161               "Slave.Scaler-0";                   
162               "Slave.Scaler-1";                   
163           }                                       
164                                                   
165          node [bgcolor=grey style=filled]         
166          "Slave.Layer-0" -> "Slave.Scaler-0"      
167          "Slave.Layer-1" -> "Slave.Scaler-0"      
168          "Slave.Layer-2" -> "Slave.Scaler-1"      
169          "Slave.Layer-3" -> "Slave.Scaler-1"      
170                                                   
171          "Slave.Layer-0" -> "Slave.Compiz"        
172          "Slave.Layer-1" -> "Slave.Compiz"        
173          "Slave.Layer-2" -> "Slave.Compiz"        
174          "Slave.Layer-3" -> "Slave.Compiz"        
175          "Slave.Scaler-0" -> "Slave.Compiz"       
176          "Slave.Scaler-1" -> "Slave.Compiz"       
177       }                                           
178                                                   
179       subgraph cluster_pipeline_master {          
180           style=dashed                            
181           label="Master Pipeline_A"               
182           node [shape=box]                        
183           {                                       
184               node [bgcolor=grey style=dashed]    
185               "Scaler-0";                         
186               "Scaler-1";                         
187               "Scaler-0/1"                        
188           }                                       
189                                                   
190          node [bgcolor=grey style=filled]         
191          "Layer-0" -> "Scaler-0"                  
192          "Layer-1" -> "Scaler-0"                  
193          "Layer-2" -> "Scaler-1"                  
194          "Layer-3" -> "Scaler-1"                  
195                                                   
196          "Slave.Compiz" -> "Compiz"               
197          "Layer-0" -> "Compiz"                    
198          "Layer-1" -> "Compiz"                    
199          "Layer-2" -> "Compiz"                    
200          "Layer-3" -> "Compiz"                    
201          "Scaler-0" -> "Compiz"                   
202          "Scaler-1" -> "Compiz"                   
203                                                   
204          "Compiz" -> "Scaler-0/1" -> "Wb_layer    
205          "Compiz" -> "Improc" -> "Timing Contr    
206       }                                           
207                                                   
208       "Wb_layer" -> "Memory"                      
209       "Timing Controller" -> "Monitor"            
210    }                                              
211                                                   
212 Sub-pipelines for input and output                
213 ----------------------------------                
214                                                   
215 A complete display pipeline can be easily divi    
216 according to the in/out usage.                    
217                                                   
218 Layer(input) pipeline                             
219 ~~~~~~~~~~~~~~~~~~~~~                             
220                                                   
221 .. kernel-render:: DOT                            
222    :alt: Layer data digraph                       
223    :caption: Layer (input) data flow              
224                                                   
225    digraph layer_data_flow {                      
226       rankdir=LR;                                 
227       node [shape=box]                            
228                                                   
229       {                                           
230          node [bgcolor=grey style=dashed]         
231            "Scaler-n";                            
232       }                                           
233                                                   
234       "Layer-n" -> "Scaler-n" -> "Compiz"         
235    }                                              
236                                                   
237 .. kernel-render:: DOT                            
238    :alt: Layer Split digraph                      
239    :caption: Layer Split pipeline                 
240                                                   
241    digraph layer_data_flow {                      
242       rankdir=LR;                                 
243       node [shape=box]                            
244                                                   
245       "Layer-0/1" -> "Scaler-0" -> "Merger"       
246       "Layer-2/3" -> "Scaler-1" -> "Merger"       
247       "Merger" -> "Compiz"                        
248    }                                              
249                                                   
250 Writeback(output) pipeline                        
251 ~~~~~~~~~~~~~~~~~~~~~~~~~~                        
252 .. kernel-render:: DOT                            
253    :alt: writeback digraph                        
254    :caption: Writeback(output) data flow          
255                                                   
256    digraph writeback_data_flow {                  
257       rankdir=LR;                                 
258       node [shape=box]                            
259                                                   
260       {                                           
261          node [bgcolor=grey style=dashed]         
262            "Scaler-n";                            
263       }                                           
264                                                   
265       "Compiz" -> "Scaler-n" -> "Wb_layer"        
266    }                                              
267                                                   
268 .. kernel-render:: DOT                            
269    :alt: split writeback digraph                  
270    :caption: Writeback(output) Split data flow    
271                                                   
272    digraph writeback_data_flow {                  
273       rankdir=LR;                                 
274       node [shape=box]                            
275                                                   
276       "Compiz" -> "Splitter"                      
277       "Splitter" -> "Scaler-0" -> "Merger"        
278       "Splitter" -> "Scaler-1" -> "Merger"        
279       "Merger" -> "Wb_layer"                      
280    }                                              
281                                                   
282 Display output pipeline                           
283 ~~~~~~~~~~~~~~~~~~~~~~~                           
284 .. kernel-render:: DOT                            
285    :alt: display digraph                          
286    :caption: display output data flow             
287                                                   
288    digraph single_ppl {                           
289       rankdir=LR;                                 
290       node [shape=box]                            
291                                                   
292       "Compiz" -> "Improc" -> "Timing Controll    
293    }                                              
294                                                   
295 In the following section we'll see these three    
296 by KMS-plane/wb_conn/crtc respectively.           
297                                                   
298 Komeda Resource abstraction                       
299 ===========================                       
300                                                   
301 struct komeda_pipeline/component                  
302 --------------------------------                  
303                                                   
304 To fully utilize and easily access/configure t    
305 a similar architecture: Pipeline/Component to     
306 capabilities, and a specific component include    
307                                                   
308 -  Data flow controlling.                         
309 -  Specific component capabilities and feature    
310                                                   
311 So the driver defines a common header struct k    
312 data flow control and all specific components     
313 structure.                                        
314                                                   
315 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
316    :internal:                                     
317                                                   
318 Resource discovery and initialization             
319 =====================================             
320                                                   
321 Pipeline and component are used to describe ho    
322 still need a @struct komeda_dev to describe th    
323 the control-abilites of device.                   
324                                                   
325 We have &komeda_dev, &komeda_pipeline, &komeda    
326 pipelines. Since komeda is not for D71 only bu    
327 of course we’d better share as much as possi    
328 achieve this, split the komeda device into two    
329                                                   
330 -   CORE: for common features and capabilities    
331 -   CHIP: for register programming and HW spec    
332                                                   
333 CORE can access CHIP by three chip function st    
334                                                   
335 -   struct komeda_dev_funcs                       
336 -   struct komeda_pipeline_funcs                  
337 -   struct komeda_component_funcs                 
338                                                   
339 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
340    :internal:                                     
341                                                   
342 Format handling                                   
343 ===============                                   
344                                                   
345 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
346    :internal:                                     
347 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
348    :internal:                                     
349                                                   
350 Attach komeda_dev to DRM-KMS                      
351 ============================                      
352                                                   
353 Komeda abstracts resources by pipeline/compone    
354 crtc/plane/connector. One KMS-obj cannot repre    
355 since the requirements of a single KMS object     
356 single component, usually that needs multiple     
357 Like set mode, gamma, ctm for KMS all target o    
358 compiz, improc and timing_ctrlr to work togeth    
359 And a KMS-Plane may require multiple komeda re    
360                                                   
361 So, one KMS-Obj represents a sub-pipeline of k    
362                                                   
363 -   Plane: `Layer(input) pipeline`_               
364 -   Wb_connector: `Writeback(output) pipeline`    
365 -   Crtc: `Display output pipeline`_              
366                                                   
367 So, for komeda, we treat KMS crtc/plane/connec    
368 component, and at any one time a pipeline/comp    
369 user. And pipeline/component will be treated a    
370 state will be managed by drm_atomic_state as w    
371                                                   
372 How to map plane to Layer(input) pipeline         
373 -----------------------------------------         
374                                                   
375 Komeda has multiple Layer input pipelines, see    
376 -   `Single pipeline data flow`_                  
377 -   `Dual pipeline with Slave enabled`_           
378                                                   
379 The easiest way is binding a plane to a fixed     
380 komeda capabilities:                              
381                                                   
382 -   Layer Split, See `Layer(input) pipeline`_     
383                                                   
384     Layer_Split is quite complicated feature,     
385     parts and handles it by two layers and two    
386     imports an edge problem or effect in the m    
387     To avoid such a problem, it needs a compli    
388     special configurations to the layer and sc    
389     related complexity to user mode.              
390                                                   
391 -   Slave pipeline, See `Dual pipeline with Sl    
392                                                   
393     Since the compiz component doesn't output     
394     only can be used for bottom layers composi    
395     hide this limitation to the user. The way     
396     Layer according to plane_state->zpos.         
397                                                   
398 So for komeda, the KMS-plane doesn't represent    
399 but multiple Layers with same capabilities. Ko    
400 Layers to fit the requirement of one KMS-plane    
401                                                   
402 Make component/pipeline to be drm_private_obj     
403 ---------------------------------------------     
404                                                   
405 Add :c:type:`drm_private_obj` to :c:type:`kome    
406                                                   
407 .. code-block:: c                                 
408                                                   
409     struct komeda_component {                     
410         struct drm_private_obj obj;               
411         ...                                       
412     }                                             
413                                                   
414     struct komeda_pipeline {                      
415         struct drm_private_obj obj;               
416         ...                                       
417     }                                             
418                                                   
419 Tracking component_state/pipeline_state by drm    
420 ----------------------------------------------    
421                                                   
422 Add :c:type:`drm_private_state` and user to :c    
423 :c:type:`komeda_pipeline_state`                   
424                                                   
425 .. code-block:: c                                 
426                                                   
427     struct komeda_component_state {               
428         struct drm_private_state obj;             
429         void *binding_user;                       
430         ...                                       
431     }                                             
432                                                   
433     struct komeda_pipeline_state {                
434         struct drm_private_state obj;             
435         struct drm_crtc *crtc;                    
436         ...                                       
437     }                                             
438                                                   
439 komeda component validation                       
440 ---------------------------                       
441                                                   
442 Komeda has multiple types of components, but t    
443 similar, usually including the following steps    
444                                                   
445 .. code-block:: c                                 
446                                                   
447     int komeda_xxxx_validate(struct komeda_com    
448                 struct komeda_component_output    
449                 struct drm_plane/crtc/connecto    
450                 struct drm_plane/crtc/connecto    
451     {                                             
452          setup 1: check if component is needed    
453                   on the user_state; if unneed    
454                   put the data flow into next     
455          Setup 2: check user_state with compon    
456                   if requirements can be met;     
457          Setup 3: get component_state from drm    
458                   user to component; fail if c    
459                   user already.                   
460          Setup 3: configure the component_stat    
461                   convert user_state to compon    
462          Setup 4: adjust the input_dflow and p    
463     }                                             
464                                                   
465 komeda_kms Abstraction                            
466 ----------------------                            
467                                                   
468 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
469    :internal:                                     
470                                                   
471 komde_kms Functions                               
472 -------------------                               
473 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
474    :internal:                                     
475 .. kernel-doc:: drivers/gpu/drm/arm/display/ko    
476    :internal:                                     
477                                                   
478 Build komeda to be a Linux module driver          
479 ========================================          
480                                                   
481 Now we have two level devices:                    
482                                                   
483 -   komeda_dev: describes the real display har    
484 -   komeda_kms_dev: attaches or connects komed    
485                                                   
486 All komeda operations are supplied or operated    
487 the module driver is only a simple wrapper to     
488 (probe/remove/pm) into komeda_dev or komeda_km    
                                                      

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